GE 369 User Manual

WARRANTY ......................................................................................................................................... A-275

WARRANTY INFORMATION ................................................................................................. A-275

INDEX

TOC–6

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 1: Introduction

Introduction

1.1 Ordering

1.1.1 General Overview

The 369 Motor Management Relay is a digital relay that provides protection and

monitoring for three phase motors and their associated mechanical systems. A unique

feature of the 369 Relay is its ability to ‘learn’ individual motor parameters and to adapt

itself to each application. Values such as motor inrush current, cooling rates and

acceleration time may be used to improve the 369 Relay’s protective capabilities.

The 369 Relay offers optimum motor protection where other relays cannot, by using the

FlexCurve™ custom overload curve, or one of the fifteen standard curves.

The 369 Relay has one RS232 front panel port and three RS485 rear ports. The Modbus RTU

protocol is standard to all ports. Setpoints can be entered via the front keypad or by using

the EnerVista 369 Setup software and a computer. Status, actual values and

troubleshooting information are also available via the front panel display or via

communications.

As an option, the 369 Relay can individually monitor up to 12 RTDs. These can be from the

stator, bearings, ambient or driven equipment. The type of RTD used is software selectable.

Optionally available as an accessory is the remote RTD module which can be linked to the

369 Relay via a fibre optic or RS485 connection.

The optional metering package provides VT inputs for voltage and power elements. It also

provides metering of V, kW, kvar, kVA, PF, Hz, and MWhrs. Three additional user

configurable analog outputs are included with this option along with one analog output

included as part of the base unit.

The Back-Spin Detection (B) option enables the 369 Relay to detect the flow reversal of a

pump motor and enable timely and safe motor restarting. All 369 Relay options are

available when ordering the relay from the factory. Field upgrades are only available for

the relay when the required hardware is installed in the relay from the factory. Field

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CHAPTER 1: INTRODUCTION

upgrades are via an option enabling passcode available from GE Multilin, which is unique

to each relay and option. Any hardware modifications made to the relay in the field will

void the product warranty and will not be supported by GE Multilin.

1.1.2 Ordering

Select the basic model and the desired features from the selection guide below:

Table 1–1:

369

Base unit (no RTD)

50-300 VDC / 60-265 VAC control power

20-60 VDC / 20-48 VAC control power

Optional 12 RTD inputs (built-in)

No optional RTD inputs

Optional metering package

Optional backspin detection (incl. metering)

No optional metering or backspin detection

Optional Fiber Optic Port

No optional Fiber Optic Port

Optional Modbus/TCP protocol interface

Optional Profibus-DP protocol interface

Optional Profibus-DPV1 protocol interface

Optional DeviceNet protocol interface

No optional protocol interfaces

Harsh environment option

No Harsh environment option

Enhanced diagnostics with Enhanced faceplate

No Enhanced diagnostics with Basic faceplate

NoteNotes:

1. One Analog Output is available with the 369 base model. The other three Analog

Outputs can be obtained by purchasing the metering or backspin options.

The control power (HI or LO) must be specified with all orders. If a feature is not

required, a 0 must be placed in the order code. All order codes have 10 digits. The 369

is available in a non-drawout version only.

Examples: 369-HI-R-0-0-0-0-E: 369 with HI voltage control power and 12 RTD

inputs, and enhanced diagnostics

369-LO-0-M-0-0-0-E: 369 relay with LO voltage control power and metering

option, and enhanced diagnotics

2. Features available only in Enhanced option (E)

•

Enhanced faceplate with motor status indicators

Motor Health Report

Enhanced learned data

Motor Start Data Logger

Enhanced event recorder

Security audit trail events

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ORDERING

1.1.3 Accessories

EnerVista 369 Setup software: Setup and monitoring software provided free with each

relay.

RRTD:

Remote RTD Module. Connects to the 369 Relay via a fibre optic or

RS485 connection. Allows remote metering and programming for up

to 12 RTDs.

F485:

CT:

Communications converter between RS232 and RS485 / fibre optic.

Interfaces a PC to the relay.

50, 75, 100, 150, 200, 300, 350, 400, 500, 600, 750, 1000 (1 A or 5 A

secondaries)

HGF:

515:

Ground CTs (50:0.025) used for sensitive earth fault detection on high

resistance grounded systems.

Blocking and test module. Provides effective trip blocking and relay

isolation.

DEMO:

FPC15:

Metal carry case in which 369 is mounted.

Remote faceplate cable, 15'.

1.1.4 Firmware History

Table 1–2: FIRMWARE HISTORY (Sheet 1 of 2)

FIRMWARE

BRIEF DESCRIPTION OF CHANGE

RELEASE DATE

REVISION

53CMB110.000

53CMB111.000

53CMB112.000

Production Release

June 14, 1999

June 24, 1999

July 2, 1999

Changes to Backspin Detection algorithm

Capability to work with the Remote RTD

module

53CMB120.000

53CMB130.000

October 15, 1999

January 3, 2000

Improvements to the Remote RTD

communications

Changes to Backspin Detection algorithm

and improved RS232 communications

53CMB140.000

53CMB145.000

March 27, 2000

June 9, 2000

Minor firmware changes

Profibus protocol, waveform capture,

phasor display, single analog output,

demand power and current, power

consumption

53CMB160.000

October 12, 2000

October 19, 2000

53CMB161.000

53CMB162.000

Minor firmware changes

November 30,

2000

53CMB170.000

53CMB180.000

Autorestart feature added

Modbus/TCP feature added

February 9, 2001

June 15, 2001

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CHAPTER 1: INTRODUCTION

Table 1–2: FIRMWARE HISTORY (Sheet 2 of 2)

FIRMWARE

REVISION

BRIEF DESCRIPTION OF CHANGE

RELEASE DATE

Number of Event Recorders increased to

250; Hottest Overall RTD value added

November 23,

2001

53CMB190.000

53CMB201.000

Added Starter Failure, MWhrs as analog

output parameter, and Motor Load

Averaging feature.

April 16, 2004

Added support for variable frequency

drives; minor changes to Modbus TCP.

53CMB210.000

53CMB220.000

53CMB230.000

53CMB240.000

November 5, 2004

April 11, 2005

Implementation of DeviceNet protocol and

starter operation monitor.

Implemented Profibus DPV1, Force

Outputs and Protection Blocking.

September 19,

2005

Custom Curve enhancement, increase

range from 0 to 32767 to 0 to 65534.

November 21,

2005

Implementation of start control relay timer

setting for reduced voltage starting,

additional Modbus address added for

starts/hour lockout time remaining,

correction to date and time Broadcast

command Modbus addresses, fix for

latched resets with multiple local/remote

assigned relays, fix for repeated “Motor

Stopped” and “Motor Running” events.

53CMB250.000

April 28, 2006

Profibus loss of trip, trip contact seal in

undervoltage auto restart, Motor Health

Report, Enhanced learned data, motor

start data logger, enhanced event recorder,

security audit trail events, DeviceNet

enhanced polling.

53CMC310.000

53CMC320.000

June 7, 2007

2-speed motor feature, Datalogger

feature, speed of last trip display, latched

trip and alarm note.

March 20, 2008

53CMC330.000

53CMC340.000

Added Ethernet Loss of Comms Trip.

Added DeviceNet Loss of Comms Trip.

May 7, 2009

July 7, 2010

1.1.5 PC Program (Software) History

Table 1–3: SOFTWARE HISTORY

BRIEF DESCRIPTION OF CHANGES

RELEASE DATE

PROGRAM

REVISION

1.10

1.20

Production Release

June 14, 1999

Capability to work with the Remote RTD module

October 15, 1999

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CHAPTER 1: INTRODUCTION

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Table 1–3: SOFTWARE HISTORY

BRIEF DESCRIPTION OF CHANGES

RELEASE DATE

PROGRAM

REVISION

Capability to communicate effectively with version

1.30 firmware

1.30

January 3, 2000

1.40

1.45

Changes made for new firmware release

March 27, 2000

June 9, 2000

Profibus protocol, waveform capture, phasor

display, single analog output, demand power and

current, power consumption

1.60

October 23, 2000

1.70

1.80

1.90

2.00

3.01

3.11

3.20

Changes made for new firmware release

New features and enhancements

February 9, 2001

June 7, 2001

November 23, 2001

September 9, 2003

August 16, 2004

November 16, 2004

April 13, 2005

Added support for firmware revision 2.1x

Changes made for firmware revision 2.2x

September 19,

2005

3.30

Changes made for firmware revision 2.3x

3.40

3.50

3.70

3.80

3.90

4.00

Changes made for firmware revision 2.4x

Changes made for firmware revision 2.5x

Changes made for firmware revision 3.1x

Changes made for firmware revision 3.2x

Changes made for firmware revision 3.3x

Changes made for firmware revision 3.4x

November 25, 2005

May 15, 2006

June 7, 2007

March 20, 2008

May 7, 2009

July 7, 2010

1.1.6 369 Relay Functional Summary

The front view for all 369 Relay models is shown below, along with the rear view showing

the Profibus port, the Modbus/TCP port, and the DeviceNet port.

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CHAPTER 1: INTRODUCTION

DISPLAY

40 Character alpha-numeric

LCD display for viewing

actual values, causes

of alarms and trips, and

programming setpoints

STATUS INDICATORS

4 LEDs indicate when an

output is activated. When

an LED is lit, the cause of

the output relay operation

will be shown on the display.

SERVICE LED indicates that a

self-diagnostic test failed, or

that the 369 is in Test Mode .

STATUS INDICATORS

LEDs indicate if motor is

stopped, starting, running,

overloaded or locked out

HELP KEY

Help key can be pressed at

any time to provide additional

information

Rugged, corrosion and

flame retardent case.

KEYPAD

Used to select the display

of actual values, causes of

alarms, causes of trips, fault

diagnosis, and to program

setpoints

CONTROL POWER

HI: 50-300 VDC/60-265 VAC

LO: 20-60 VDC / 20-48 VAC

4 OUTPUT RELAYS

Programmable alarm and trip

conditions activated by

programmable setpoints,

switch input, remote

communication control

Customer Accessible

Fuse

320

DIGITAL INPUTS

12 RTD INPUTS ( R )

Field selectable type

PROFIBUS-DP ( P )

PROFIBUS-DPV1 ( P1 )

3 x RS485 Ports

3 Independent modbus

channels

1 ANALOG OUTPUT ( BASE UNIT )

3 ANALOG OUTPUTS (M,B)

FIBER OPTIC DATA LINK ( F )

For harsh enviroments and or

hook up to RRTD

BACKSPIN DETECTION ( B )

20mV to 480V RMS

CURRENT INPUTS

3 Phase CT inputs

5A, 1A, taps

VOLTAGE INPUTS ( M )

0-240V wye or delta VT

connections.

GROUND CT INPUTS

5A, 1A and 50:0.25 taps

840702BM.CDR

FIGURE 1–1: Front and Rear View

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 1: INTRODUCTION

ORDERING

FIGURE 1–2: DeviceNet Model

FIGURE 1–3: Rear View (Modbus/TCP Model)

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CHAPTER 1: INTRODUCTION

1.1.7 Relay Label Definition

4 5

MAXIMUM CONTACT RATING

RESISTIVE

250 VAC

1/4 HP 125 VAC 1/2 HP 250 VAC

MODEL: 369-HI-R-B-F-P-0

SERIAL No: M53C07000001

FIRMWARE: 53CMC320.000

INPUT POWER:

OPTIONS

12 RTDs:

BACKSPIN

FIBER OPTIC PORT

PROFIBUS

50-300 VDC

60-265 VAC

485mA MAX.

50/60Hz or DC

MOD:

POLLUTION DEGREE: 2 IP CODE: 50X

OVERVOLTAGE CATAGORY: II

INSULATIVE VOLTAGE: 2

NONE

9 10 11 12

840350AA.CDR

1. The 369 Relay order code at the time of leaving the factory.

2. The serial number of the 369 Relay.

3. The firmware installed at the factory. Note that this may no longer be the currently

installed firmware as it may have been upgraded in the field. The current firmware revi-

sion can be checked in the actual values section of the 369 Relay.

4. Specifications for the output relay contacts.

5. Certifications the 369 Relay conforms with or has been approved to.

6. Factory installed options. These are based on the order code. Note that the 369 Relay

may have had options upgraded in the field. The actual values section of the 369 can

be checked to verify this.

7. Control power ratings for the 369 Relay as ordered. Based on the HI/LO rating from

the order code.

8. Pollution degree.

9. Overvoltage category.

10. IP code.

11. Modification number for any factory-ordered mods.

12. Insulative voltage rating.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 2: Product Description

Product Description

2.1 Overview

2.1.1 Guideform Specifications

Motor protection and management shall be provided by a digital relay. Protective func-

tions include:

•

phase overload standard curves (51)

overload by custom programmable curve (51)

I²t modeling (49)

current unbalance / single phase detection (46)

starts per hour and time between starts

short circuit (50)

ground fault (50G/50N 51G/51N)

mechanical jam / stall

two-speed motor protection

Optional functions include:

•

under / overvoltage (27/59)

phase reversal (47)

underpower (37)

power factor (55)

stator / bearing overtemperature with twelve (12) independent RTD inputs (49/38)

backspin detection

Management functions include:

statistical data

•

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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OVERVIEWCHAPTER 2: PRODUCT DESCRIPTION

•

pre-trip data (last 40 events)

ability to learn, display and integrate critical parameters to maximize motor

protection

•

a keypad with 40 character display

flash memory

The relay is capable of displaying important metering functions, including phase volt-

ages, kilowatts, kvars, power factor, frequency and MWhr. In addition, undervoltage

and low power factor alarm and trip levels are field programmable. The communica-

tions interface include one front RS232 port and three independent rear RS485 ports

with supporting PC software, thus allowing easy setpoint programming, local retrieval

of information and flexibility in communication with SCADA and engineering worksta-

tions.

2.1.2 Metered Quantities

METERED QUANTITY

UNITS

OPTION

Phase Currents and Current Demand

Motor Load

Amps

× FLA

Unbalance Current

Ground Current

Amps

Input Switch Status

Open / Closed

(De) Energized

°C or °F

Relay Output Status

RTD Temperature

Backspin Frequency

Phase/Line Voltages

Volts

Frequency

Power Factor

lead / lag

Watts

Real Power and Real Power Demand

Reactive Power and Reactive Power Demand

Apparent Power and Apparent Power Demand

Real Power Consumption

Reactive Power Consumption/Generation

Vars

MWh

±Mvarh

2.1.3 Protection Features

ANSI/

PROTECTION FEATURES

OPTION

TRIP ALARM BLOCK

START

IEEE

DEVICE

Speed Switch

•

Undervoltage

•

Undercurrent / Underpower

Bearing RTD

R or RRTD

Current Unbalance

Voltage Phase Reversal

Stator RTD

R or RRTD

•

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONOVERVIEW

ANSI/

IEEE

DEVICE

PROTECTION FEATURES

OPTION

TRIP ALARM BLOCK

START

Short Circuit & Backup

•

Ground Fault & Ground Fault

Backup

50G/51G

•

Overload

•

Power Factor

Overvoltage

Starts per Hour/Time

Between Starts

Alarm

•

Over/Under Frequency

Lockout

•

Differential Switch

General Switch

Reactive Power

Thermal Capacity

•

Start Inhibit (thermal capacity

available)

•

Restart Block (Backspin

Timer)

Mechanical Jam

Acceleration Timer

Ambient RTD

•

R or RRTD

•

Short/Low temp RTD

Broken/Open RTD

Loss of RRTD

Communications

RRTD

•

Trip Counter

•

Self Test/Service

Backspin Detection

Current Demand

kW Demand

•

kvar Demand

kVA Demand

Starter Failure

Reverse Power

Undervoltage Autorestart

M or B

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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OVERVIEWCHAPTER 2: PRODUCT DESCRIPTION

2.1.4 Additional Features

FEATURE

OPTION

Modbus/TCP protocol Ethernet

interface

Profibus-DP rear communication port

Profibus-DPV1 rear communication

port

DeviceNet protocol interface

User Definable Baud Rate (1200-

19200)

Flash Memory for easy firmware

updates

Front RS232 communication port

Rear RS485 communication port

Rear fiber optic port

RTD type is user definable

R or RRTD

4 User Definable Analog Outputs

(0 to 1 mA, 0 to 20 mA, 4 to 20 mA)

Windows based PC program for

setting up and monitoring

FIGURE 2–1: Single Line Diagram

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

2.2 Specifications

2.2.1 Inputs

CONTROL POWER

LO range:............................................................DC: 20 to 60 V DC

AC: 20 to 48 V AC at 50/60 Hz

HI range:.............................................................DC: 50 to 300 V DC

AC: 60 to 265 V AC at 50/60 Hz

Power:..................................................................nominal: 20 VA; maximum: 65 VA

Holdup:................................................................non-failsafe trip: 200 ms; failsafe trip: 100 ms

FUSE

T 3.15 A H 250 V (5 × 20 mm)

Timelag high breaking capacity

PHASE CURRENT INPUTS (CT)

CT input (rated):...............................................1 A and 5 A secondary

CT primary:........................................................1 to 5000 A

Range:

for 50/60 Hz nominal frequency: ......0.05 to 20 × CT primary amps

for variable frequency: ...........................0.1 to 20 × CT primary amps

Full Scale: ...........................................................20 × CT primary amps or 65535 A maximum

Frequency:.........................................................20 to 100 Hz

Conversion: .......................................................True RMS, 1.04 ms/sample

Accuracy:

at ≤ 2 × CT:....................................................±0.5% of 2 × CT for 50/60 Hz nominal freq.

±1.0% of 2 × CT for variable frequency (for sinusoidal

waveforms)

at > 2 × CT:....................................................±1.0% of 20 × CT for 50/60 Hz nominal freq.

±3.0% of 12 × CT or less for variable frequency (for

sinusoidal waveforms)

PHASE CT BURDEN

PHASE CT

INPUT (A)

BURDEN

(Ω)

0.03

0.64

11.7

0.07

1.71

1 A

0.03

0.003

5 A

100

PHASE CT CURRENT WITHSTAND

PHASE CT

1 s

WITHSTAND TIME

2 s

40 × CT

continuous

3 × CT

1 A

5 A

100 × CT

DIGITAL / SWITCH INPUTS

Inputs:..................................................................6 optically isolated

Input type:..........................................................Dry Contact (< 800 Ω)

Function:.............................................................Programmable

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

GROUND CURRENT INPUT (GF CT)

CT Input (rated):...............................................1 A/5 A secondary and 50:0.025

CT Primary: ........................................................1 to 5000 A (1 A/5 A)

Range: .................................................................0.1 to 1.0 × CT primary (1 A/5 A)

0.05 to 25.0 A (50:0.025)

Full Scale: ...........................................................1.0 × CT primary (1 A/5 A)

25 A (50:0.025)

Frequency:.........................................................20 to 100 Hz

Conversion:........................................................True RMS 1.04ms/sample

Accuracy at 50/60 Hz:

for 1 A/5 A: ......................................... 1.0% of full scale (1 A/5 A)

for 50:0.025........................................ 0.07 A at <1 A

0.20 A at <25 A

Accuracy at variable frequency:

for 1 A tap:.....................................................±1.5% for 40 to 100 Hz

±2.5% for 20 to 39 Hz

for 5 A tap:.....................................................±2% for 40 to 100 Hz

±3% for 20 to 39 Hz

for 50:0.025: .................................................±0.2 A at <1 A

±0.6 A at <25 A

GROUND CT BURDEN

GROUND CT

INPUT (A)

BURDEN

VA (Ω)

0.04

0.78

6.79

0.07

1.72

0.036

0.031

0.017

0.003

384

1 A

5 A

100

0.025

0.1

0.5

0.24

2.61

37.5

50:0.025

261

150

GROUND CT CURRENT WITHSTAND

GROUND CT

WITHSTAND TIME

2 s continuous

1 s

1 A

100 × CT

10 A

40 × CT 3 × CT

5 A

50:0.025

5 A

150 mA

PHASE/LINE VOLTAGE INPUT (VT) (OPTION M)

VT ratio:...............................................................1.00 to 240.00:1 in steps of 0.01

VT secondary:...................................................240 V AC (full scale)

Range:..................................................................0.05 to 1.00 × full scale

Frequency:.........................................................20 to 100 Hz

Conversion:........................................................True RMS 1.04 ms/sample

Accuracy:............................................... 2.5% of full scale for ≤ 200 V at 20 to 39 Hz

±1% of full scale for 12 to 240 V at > 40 Hz

Burden:................................................................>200 kΩ

Max. continuous: ............................................280 V AC

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

BSD INPUTS (OPTION B)

Frequency: ........................................................1 to 120 Hz

Dynamic BSD range: ....................................20 mV to 480 V RMS

Accuracy:............................................... 0.02 Hz

Burden:................................................................>200 kΩ

RTD INPUTS (OPTION R)

Wire Type: ..........................................................3 wire

Sensor Type: .....................................................100 Ω platinum (DIN 43760), 100 Ω nickel, 120 Ω nickel,

10 Ω copper

RTD sensing current: ....................................3 mA

Range:..................................................................–40 to 200°C or –40 to 392°F

Accuracy:............................................... 2°C or 4°F

Lead resistance:..............................................25 Ω max. per lead for Pt and Ni type;

3 Ω max. per lead for Cu type

Isolation:.............................................................36 Vpk

2.2.2 Outputs

ANALOG OUTPUTS (OPTION M)

PROGRAMMABLE

OUTPUT

0 to 1 mA 0 to 20 mA 4 to 20 mA

MAX LOAD

2400 Ω

600 Ω

MAX OUTPUT 1.01 mA

20.2 mA

Accuracy:............................................... 1% of full scale

Isolation:.............................................................fully isolated active source

OUTPUT RELAYS

RESISTIVE

INDUCTIVE

LOAD (pf = 1) LOAD (pf = 0.4)(L/

R – 7ms)

RATED LOAD

8 A at 250 V AC 3.5 A at 250 V AC

8 A at 30 V DC 3.5 A at 30 V DC

CARRY CURRENT

MAX SWITCHING

CAPACITY

2000 VA

240 W

875 VA

170 W

MAX SWITCHING V

MAX SWITCHING I

OPERATE TIME

380 V AC; 125 V DC

8 A

3.5 A

<10 ms (5 ms typical)

CONTACT

MATERIAL

silver alloy

This equipment is suitable for use in Class 1, Div 2, Groups A, B, C, D or Non-Hazardous

Locations only if MOD502 is ordered.

Hazardous Location – Class 1, Div 2 output rating if MOD502 is ordered: 240 V, 3 A max,

as per UL1604. The contact rating is only for Make and carry operations, and shall not

be used for breaking DC current.

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

Explosion Hazard – Substitution of components may impair suitability for Class 1, Div 2.

Explosion Hazard – Do not disconnect equipment unless power has been switched off

or the area is known to be Non-Hazardous.

2.2.3 Metering

POWER METERING (OPTION M)

PARAMETE ACCURAC RESOLUTIO

RANGE

(FULL SCALE)

1 kW

±32000

kvar

kVA

1 kvar

1 kVA

32000

0 to 65000

0 to 999

kWh

MWh

1 kWh

1 MWh

1 kvarh

1 Mvarh

0.01

±2%

0 to 65535

0 to 999

0 to 65535

–0.99 to 1.00

kvarh

±Mvarh

±2%

Power Factor 1%

20.00 to

100.00

Frequency

0.02 Hz

0.01 Hz

kW Demand

1 kW

1 kvar

1 kVA

1 A

0 to 32000

0 to 65000

0 to 65535

kvar Demand 2%

kVA Demand 2%

Amp Demand 2%

EVENT RECORD

Capacity:.............................................................last 512 events

Triggers:..............................................................trip, inhibit, power fail, alarms, self test,

waveform capture

WAVEFORM CAPTURE

Length:.................................................................3 buffers containing 16 cycles of all current and voltage

channels

Trigger position: ..............................................1 to 100% pre-trip to post-trip

Trigger: ...............................................................trip, manually via communications or digital input

MOTOR START DATA LOGGER

Length: ...............................................................6 Buffers containing 30 seconds of motor start data.

Trigger: ...............................................................Motor Start Status.

Trigger position: .............................................1-second pre-trigger duration.

Logging rate: ...................................................1 sample/200ms.

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CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

2.2.4 Communications

FRONT PORT

Type:.....................................................................RS232, non-isolated

Baud rate: ..........................................................4800 to 19200

Protocol:..............................................................Modbus RTU

BACK PORTS (3)

Type:.....................................................................RS485

Baud rate: ..........................................................1200 to 19200

Protocol:..............................................................Modbus RTU

36V isolation (together)

PROFIBUS (OPTIONS P AND P1)

Type:.....................................................................RS485

Baud rate: ..........................................................1200 baud to 12 Mbaud

Protocol:..............................................................Profibus-DP

Profibus-DPV1

Connector Type:..............................................DB9 Female

MODBUS/TCP ETHERNET (OPTION E)

Connector type:...............................................RJ45

Protocol:..............................................................Modbus/TCP

DEVICENET (OPTION D)

DeviceNet CONFORMANCE TESTED™

Connector type:...............................................5-pin linear DeviceNet plug (phoenix type)

Baud rate: ..........................................................125, 250, and 500 kbps

Protocol:..............................................................DeviceNet

Bus-Side Current Draw:...............................85mA (Typical), 100mA (Max)

FIBER OPTIC PORT (OPTION F)

Optional use:.....................................................RTD remote module hookup

Baud rate: ..........................................................1200 to 19200

Protocol:..............................................................Modbus RTU

Fiber sizes: .........................................................50/125, 62.5/125, 100/140, and 200 μm

Emitter fiber type: ..........................................820 nm LED, multimode

Link power budget:

Transmit power: ...........................................–20 dBm

Received sensitivity: ...................................–30 dBm

Power budget:...............................................10 dB

Maximum optical input power: ..............–7.6 dBm

Typical link distance: ...................................1.65 km

Note

Typical link distance is based upon the following assumptions for system loss. As actual

losses vary between installations, the distance covered will vary.

Connector loss: ..............................................2 dB

Fiber loss: ..........................................................3 dB/km

Splice loss: ........................................................One splice every 2 km at 0.05 dB loss/splice

System margin: ..............................................3 dB additional loss added to calculations to compensate

for all other losses

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

FIELDBUS LOSS OF COMMUNICATION

Pickup: .................................................................No communication

Time delay:........................................................0.25 to 10 sec in steps of 0.25 sec

Timing accuracy:................................... 250 ms for Profibus

300 ms for Ethernet

250 ms for DeviceNet

2.2.5 Protection Elements

51 OVERLOAD/STALL/THERMAL MODEL

Curve Shape: ....................................................1 to 15 standard, custom

Curve Biasing: ..................................................unbalance, temperature, hot/cold ratio,

cool time constants

Pickup Level: .....................................................1.01 to 1.25 × FLA

Pickup Accuracy: ............................................as per phase current inputs

Dropout Level:..................................................96 to 98% of pickup

Timing Accuracy:............................................±100 ms or ±2% of total trip time

THERMAL CAPACITY ALARM

Pickup Level: .....................................................1 to 100% TC in steps of 1

Pickup Accuracy: ............................................±2%

Dropout Level:..................................................96 to 98% of pickup

Timing Accuracy:............................................±100 ms

OVERLOAD ALARM

Pickup Level: .....................................................1.01 to 1.50 × FLA in steps of 0.01

Pickup Accuracy: ............................................as per phase current inputs

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0.1 to 60.0 s in steps of 0.1

Timing Accuracy:............................................±100 ms or ±2% of total trip time

50 SHORT CIRCUIT

Pickup Level: .....................................................2.0 to 20.0 × CT in steps of 0.1

Pickup Accuracy: ............................................as per phase current inputs

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0 to 255.00 s in steps of 0.01 s

Backup Delay: ..................................................0.10 to 255.00 s in steps of 0.01 s

Timing Accuracy:............................................+50 ms for delays <50 ms

±100 ms or ±0.5% of total trip time

MECHANICAL JAM

Pickup Level: .....................................................1.01 to 6.00 × FLA in steps of 0.01

Pickup Accuracy: ............................................as per phase current inputs

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0.5 to 125.0 s in steps of 0.5

Timing Accuracy:............................................±250 ms or ±0.5% of total trip time

37 UNDERCURRENT

Pickup Level: .....................................................0.10 to 0.99 × FLA in steps of 0.01

Pickup Accuracy: ............................................as per phase current inputs

Dropout Level:..................................................102 to 104% of pickup

Time Delay:........................................................1 to 255 s in steps of 1

Start Delay:........................................................0 to 15000 s in steps of 1

Timing Accuracy:............................................±500 ms or ±0.5% of total time

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

46 UNBALANCE

Pickup Level:.....................................................4 to 30% in steps of 1

Pickup Accuracy: ............................................±2%

Dropout Level:..................................................1 to 2% below pickup

Time Delay: .......................................................1 to 255 s in steps of 1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±500 ms or ±0.5% of total time

50G/51G 50N/51N GROUND FAULT

Pickup Level:.....................................................0.10 to 1.00 × CT for 1 A/5 A CT

0.25 to 25.00 A for 50:0.025 CT

Pickup Accuracy: ............................................as per ground current inputs

Dropout Level:..................................................96 to 98% of pickup

Time Delay: .......................................................0 to 255.00 s in steps of 0.01 s

Backup Delay:..................................................0.01 to 255.00 s in steps of 0.01 s

Timing Accuracy:............................................+50 ms for delays <50 ms

±100 ms or ±0.5% of total trip time

ACCELERATION TRIP

Pickup Level:.....................................................motor start condition

Dropout Level:..................................................motor run, trip or stop condition

Time Delay: .......................................................1.0 to 250.0 s in steps of 0.1

Timing Accuracy:............................................±100 ms or ±0.5% of total time

38/49 RTD AND RRTD PROTECTION

Pickup Level:.....................................................1 to 200°C or 34 to 392°F

Pickup Accuracy:................................... 2°C or 4°F

Dropout Level:..................................................96 to 98% of pickup above 80°C

Time Delay: .......................................................<5 s

OPEN RTD ALARM

Pickup Level:.....................................................detection of an open RTD

Pickup Accuracy: ............................................>1000 Ω

Dropout Level:..................................................96 to 98% of pickup

Time Delay: .......................................................<5 s

SHORT/LOW TEMP RTD ALARM

Pickup Level:.....................................................<–40°C or –40°F

Pickup Accuracy:................................... 2°C or 4°F

Dropout Level:..................................................96 to 98% of pickup

Time Delay: .......................................................<5 s

LOSS OF RRTD COMMS ALARM

Pickup Level:.....................................................no communication

Time Delay: .......................................................2 to 5 s

27 UNDERVOLTAGE

Pickup Level:.....................................................0.50 to 0.99 × rated in steps of 0.01

Pickup Accuracy: ............................................as per phase voltage inputs

Dropout Level:..................................................102 to 104% of pickup

Time Delay: .......................................................0.0 to 255.0 s in steps of 0.1

Start Delay:........................................................separate level for start conditions

Timing Accuracy:............................................+75 ms for delays <50 ms

±100 ms or ±0.5% of total trip time

59 OVERVOLTAGE

Pickup Level:.....................................................1.01 to 1.25 × rated in steps of 0.01

Pickup Accuracy: ............................................as per phase voltage inputs

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0.0 to 255.0 s in steps of 0.1

Timing Accuracy:............................................±100 ms or ±0.5% of total trip time

47 PHASE REVERSAL

Pickup Level: .....................................................phase reversal detected

Time Delay:........................................................500 to 700 ms

81 UNDERFREQUENCY

Pickup Level: .....................................................20.00 to 70.00 Hz in steps of 0.01

Pickup Accuracy: ............................................±0.02 Hz

Dropout Level:..................................................0.05 Hz

Time Delay:........................................................0.0 to 255.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±100 ms or ±0.5% of total trip time

81 OVERFREQUENCY

Pickup Level: .....................................................20.00 to 70.00 Hz in steps of 0.01

Pickup Accuracy: ............................................±0.02 Hz

Dropout Level:..................................................0.05 Hz

Time Delay:........................................................0.0-255.0 s in steps of 0.1

Start Delay:........................................................0-5000 s in steps of 1

Timing Accuracy:............................................±100 ms or ±0.5% of total trip time

55 LEAD POWER FACTOR

Pickup Level: .....................................................0.99 to 0.05 in steps of 0.01

Pickup Accuracy: ............................................±0.02

Dropout Level:..................................................0.03 of pickup

Time Delay:........................................................0.1 to 255.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

55 LAG POWER FACTOR

Pickup Level: .....................................................0.99 to 0.05 in steps of 0.01

Pickup Accuracy: ............................................±0.02

Dropout Level:..................................................0.03 of pickup

Time Delay:........................................................0.1 to 255.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

POSITIVE REACTIVE POWER

Pickup Level: .....................................................1 to 25000 in steps of 1

Pickup Accuracy: ............................................±2%

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0.1 to 255.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

NEGATIVE REACTIVE POWER

Pickup Level: .....................................................1 to 25000 kvar in steps of 1

Pickup Accuracy: ............................................±2%

Dropout Level:..................................................96 to 98% of pickup

Time Delay:........................................................0.1 to 255.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

37 UNDERPOWER

Pickup Level: .....................................................1 to 25000 kW in steps of 1

Pickup Accuracy: ............................................±2%

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

Dropout Level:..................................................102 to 104% of pickup

Time Delay: .......................................................0.5 to 255.0 s in steps of 0.5

Start Delay:........................................................0 to 15000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

REVERSE POWER

Pickup Level:.....................................................1 to 25000 kW in steps of 1

Pickup Accuracy: ............................................±2%

Dropout Level:..................................................96 to 98% of pickup

Time Delay: .......................................................0.5 to 30.0 s in steps of 0.5

Start Delay:........................................................0 to 50000 s in steps of 1

Timing Accuracy:............................................±300 ms or ±0.5% of total trip time

87 DIFFERENTIAL SWITCH

Time Delay: .......................................................<200 ms

14 SPEED SWITCH

Time Delay: .......................................................0.5 to 100.0 s in steps of 0.5

Timing Accuracy:............................................±200 ms or ±0.5% of total trip time

GENERAL SWITCH

Time Delay: .......................................................0.1 to 5000.0 s in steps of 0.1

Start Delay:........................................................0 to 5000 s in steps of 1

Timing Accuracy:............................................±200 ms or ±0.5% of total trip time

DIGITAL COUNTER

Pickup: .................................................................on count equaling level

Time Delay: .......................................................<200 ms

BACKSPIN DETECTION

Dynamic BSD:...................................................20 mV to 480 V RMS

Pickup Level:.....................................................3 to 120 Hz in steps of 1

Dropout Level:..................................................2 to 30 Hz in steps of 1

Level Accuracy: ...............................................±0.02 Hz

Timing Accuracy:............................................±500 ms or ±0.5% of total trip time

2.2.6 Monitoring Elements

STARTER FAILURE

Pickup level: ......................................................motor run condition when tripped

Dropout level:...................................................motor stopped condition

Time delay:........................................................10 to 1000 ms in steps of 10

Timing accuracy:............................................±100 ms

CURRENT DEMAND ALARM

Demand period: ..............................................5 to 90 min. in steps of 1

Pickup level: ......................................................0 to 65000 A in steps of 1

Pickup accuracy: ............................................as per phase current inputs

Dropout level:...................................................96 to 98% of pickup

Time delay:........................................................<2 min.

kW DEMAND ALARM

Demand period: ..............................................5 to 90 min. in steps of 1

Pickup level: ......................................................1 to 50000 kW in steps of 1

Pickup accuracy: ............................................±2%

Dropout level:...................................................96 to 98% of pickup

Time delay:........................................................<2 min.

kvar DEMAND ALARM

Demand period: ..............................................5 to 90 min. in steps of 1

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

Pickup level:.......................................................1 to 50000 kvar in steps of 1

Pickup accuracy:.............................................±2%

Dropout level:...................................................96 to 98% of pickup

Time delay:........................................................<2 min.

kVA DEMAND ALARM

Demand period: ..............................................5 to 90 min in steps of 1

Pickup level:.......................................................1 to 50000 kVA in steps of 1

Pickup accuracy:.............................................±2%

Dropout level:...................................................96 to 98% of pickup

Time delay:........................................................<2 min.

TRIP COUNTER

Pickup: .................................................................on count equaling level

Time delay:........................................................<200 ms

2.2.7 Control Elements

REDUCED VOLTAGE START

Transition Level: ..............................................25 to 300% FLA in steps of 1

Transition Time:...............................................1 to 250 sec. in steps of 1

Transition Control:..........................................Current, Timer, Current and Timer

UNDERVOLTAGE AUTORESTART

Pickup/Restoration level: ...........................0.50 to 1.00 × rated in steps of 0.01

Immediate Restart Power Loss Time: ..100 to 500 ms in steps of 100ms

Delay 1 Restart Power Loss Time: .........0.1 to 10 s in steps of 0.1 s, or OFF.

Delay 1 Restart Time Delay: .....................0 to 1200.0 s in steps of 0.2 s

Delay 2 Restart Power Loss Time: ........1 to 3600s in steps of 1s, Off or Unlimited

Delay 2 Restart Time Delay: .....................0 to 1200.0 s in steps of 0.2 s

Time Accuracy: ...............................................± 200ms

1 to 9 seconds (with loss of control power)

2.2.8 Environmental Specifications

AMBIENT TEMPERATURE

Operating Range: ..........................................-40°C to +60°C

Storage Range: ...............................................-40°C to +80°C

T-Code Rating: .................................................T4A (for MOD 502 only)

NoteNOTE:

For 369 units with the Profibus, Modbus/TCP, or DeviceNet option the operating and

storage ranges are as follows:

Operating Range: ..........................................+5°C to +60°C

Storage Range: ...............................................+5°C to +80°C

HUMIDITY

Up to 95% non condensing

DUST/MOISTURE

IP50

VENTILATION

No special ventilation required as long as ambient temperature remains within specifications.

Ventilation may be required in enclosures exposed to direct sunlight.

2–22

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 2: PRODUCT DESCRIPTIONSPECIFICATIONS

OVERVOLTAGE CATEGORY II

CLEANING

May be cleaned with a damp cloth.

2.2.9 Long-term storage

LONG-TERM STORAGE

Environment: ...................................................In addition to the above environmental considerations,

the relay should be stored in an environment that is dry,

corrosive-free, and not in direct sunlight.

Correct storage:..............................................Prevents premature component failures caused by

environmental factors such as moisture or corrosive

gases. Exposure to high humidity or corrosive

environments will prematurely degrade the electronic

components in any electronic device regardless of its use

or manufacturer, unless specific precautions, such as

those mentioned in the Environmental section above, are

taken.

Note

It is recommended that all relays be powered up once per year, for one hour

continuously, to avoid deterioration of electrolytic capacitors and subsequent relay

failure.

2.2.10 Approvals/Certification

ISO:........................................................................Designed and manufactured to an ISO9001 registered

process.

UL:..........................................................................UL Listed (File E234799*)

(File E83849)

UL 508 - Industrial Control Equipment

UL 1053 - Ground Fault Protection Equipment

UL 1604* - Electrical Equipment for use in Class 1 Div 2

Hazardous Locations

CSA:.......................................................................Certified per: C22.2 No. 142 - Process Control Equipment

C22.2 No. 213* - Non-incendive Electrical Equipment for

use in class 1 Div 2 Hazardous Locations

CE:..........................................................................Conforms to EN 55011/CISPR 11, EN50082-2, IEC 947-1,

1010-1

* For MOD502 only

DeviceNet CONFORMANCE TESTED™

2.2.11 Type Test Standards

SURGE WITHSTAND CAPABILITY

ANSI/IEEE C37.90.1 Oscillatory (2.5 kV/1 MHz)

ANSI/IEEE C37.90.1 Fast Rise (5 kV/10 ns)

IEC / EN 61000-4-4, Level 4

INSULATION RESISTANCE

IEC / EN 60255-5

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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SPECIFICATIONSCHAPTER 2: PRODUCT DESCRIPTION

IMPULSE TEST

IEC / EN 60255-5

DIELECTRIC STRENGTH: ...............................ANSI/IEEE C37.90

IEC / EN 60255-5

CSA C22.2 No.14

ELECTROSTATIC DISCHARGE

EN 61000-4-2, Level 2

IEC 60255-22-2 Level 2

SURGE IMMUNITY

IEC 1000-4-5, EN 61000-4-5

IEC 60255-22-5

CURRENT WITHSTAND

ANSI/IEEE C37.90

IEC 60255-6

RFI

ANSI/IEEE C37.90.2, 35 V/m

EN 61000-4-3 10V/m

CONDUCTED IMMUNITY:.............................IEC 1000-4-6

IEC 60255-22-6

CONDUCTED/RADIATED EMISSIONS

EN 55011 (IEC CISPR 11)

ENVIRONMENTAL

ANSI/IEEE C37.90

IEC 60255-6

IEC 60068-2-38 Part 2

IEC60068-2-1, 16h at -40°C

IEC60068-2-2, 16h at +85°C

IEC60068-2-30, 95% variant 1, 6 days

VIBRATION

IEC 60255-21-1 Class 1

IEC 60255-21-2 Class 1

VOLTAGE DEVIATION

IEC 1000-4-11 / EN 61000-4-11

MAGNETIC FIELD IMMUNITY

IEC 1000-4-8 / EN61000-4-8

T-CODE RATING

T4A

2.2.12 Production Tests

DIELECTRIC STRENGTH

2200 VAC for 1 second (as per UL & CE)

BURN IN

8 hours at 60°C sampling plan

CALIBRATION AND FUNCTIONALITY

100% hardware functionality tested

100% calibration of all metered quantities

2–24

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 3: Installation

Installation

3.1 Mechanical Installation

3.1.1 Mechanical Installation

The 369 is contained in a compact plastic housing with the keypad, display,

communication port, and indicators/targets on the front panel. The unit should be

positioned so the display and keypad are accessible. To mount the relay, make cutout and

drill mounting holes as shown below. Mounting hardware (bolts and washers) is provided

with the relay. Although the relay is internally shielded to minimize noise pickup and

interference, it should be mounted away from high current conductors or sources of

strong magnetic fields.

FIGURE 3–1: Physical Dimensions

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–27

MECHANICAL INSTALLATION

CHAPTER 3: INSTALLATION

FIGURE 3–2: Split Mounting Dimensions

3–28

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

TERMINAL IDENTIFICATION

3.2 Terminal Identification

3.2.1 369 Relay Terminal List

TERMINAL

WIRING CONNECTION

RTD1 +

RTD1 –

RTD1 COMPENSATION

RTD1 SHIELD

RTD2 +

RTD2 –

RTD2 COMPENSATION

RTD2 SHIELD

RTD3 +

RTD3 –

RTD3 COMPENSATION

RTD3 SHIELD

RTD4 +

RTD4 –

RTD4 COMPENSATION

RTD4 SHIELD

RTD5 +

RTD5 –

RTD5 COMPENSATION

RTD5 SHIELD

RTD6 +

RTD6 –

RTD6 COMPENSATION

RTD6 SHIELD

RTD7 +

RTD7 –

RTD7 COMPENSATION

RTD7 SHIELD

RTD8 +

RTD8 –

RTD8 COMPENSATION

RTD8 SHIELD

RTD9 +

RTD9 –

RTD9 COMPENSATION

RTD9 SHIELD

RTD10 +

RTD10 –

RTD10 COMPENSATION

RTD10 SHIELD

RTD11 +

RTD11 –

RTD11 COMPENSATION

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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TERMINAL IDENTIFICATION

CHAPTER 3: INSTALLATION

TERMINAL

WIRING CONNECTION

RTD11 SHIELD

100

101

102

103

104

105

106

RTD12 +

RTD12 –

RTD12 COMPENSATION

RTD12 SHIELD

SPARE SW

SPARE SW COMMON

DIFFERENTIAL INPUT SW

DIFFERENTIAL INPUT SW COMMON

SPEED SW

SPEED SW COMMON

ACCESS SW

ACCESS SW COMMON

EMERGENCY RESTART SW

EMERGENCY RESTART SW COMMON

EXTERNAL RESET SW

EXTERNAL RESET SW COMMON

COMM1 RS485 +

COMM1 RS485 –

COMM1 SHIELD

COMM2 RS485 +

COMM2 RS485 –

COMM2 SHIELD

COMM3 RS485 +

COMM3 RS485 –

COMM3 SHIELD

ANALOG OUT 1

ANALOG OUT 2

ANALOG OUT 3

ANALOG OUT 4

ANALOG COM

ANALOG SHIELD

BACKSPIN VOLTAGE

BACKSPIN NEUTRAL

PHASE A CURRENT 5A

PHASE A CURRENT 1A

PHASE A COMMON

PHASE B CURRENT 5A

PHASE B CURRENT 1A

PHASE B COMMON

PHASE C CURRENT 5A

PHASE C CURRENT 1A

PHASE C COMMON

NEUT/GND CURRENT 50:0.025A

NEUT/GND CURRENT 1A

NEUT/GND CURRENT 5A

NEUT/GND COMMON

PHASE A VOLTAGE

PHASE A NEUTRAL

3–30

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

TERMINAL IDENTIFICATION

TERMINAL

WIRING CONNECTION

107

PHASE B VOLTAGE

108

109

110

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

126

PHASE B NEUTRAL

PHASE C VOLTAGE

PHASE C NEUTRAL

TRIP NC

TRIP COMMON

TRIP NO

ALARM NC

ALARM COMMON

ALARM NO

AUX1 NC

AUX1 COMMON

AUX1 NO

AUX2 NC

AUX2 COMMON

AUX2 NO

POWER FILTER GROUND

POWER LINE

POWER NEUTRAL

POWER SAFETY

3.2.2 269 to 369 Relay Conversion Terminal List

269

WIRING CONNECTION

369

RTD1 +

RTD1 COMPENSATION

RTD1 –

RTD1 SHIELD

RTD2 +

RTD2 COMPENSATION

RTD2 –

RTD2 SHIELD

RTD3 +

RTD3 COMPENSATION

RTD3 –

RTD3 SHIELD

RTD4 +

RTD4 COMPENSATION

RTD4 –

RTD4 SHIELD

RTD5 +

RTD5 COMPENSATION

RTD5 –

RTD5 SHIELD

RTD6 +

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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TERMINAL IDENTIFICATION

CHAPTER 3: INSTALLATION

269

WIRING CONNECTION

369

RTD6 COMPENSATION

RTD6 –

RTD6 SHIELD

RTD7 +

RTD7 COMPENSATION

RTD7 –

RTD7 SHIELD

RTD8 +

RTD8 COMPENSATION

RTD8 –

RTD8 SHIELD

RTD9 +

RTD9 COMPENSATION

RTD9 –

RTD9 SHIELD

RTD10 +

RTD10 COMPENSATION

RTD10 –

RTD10 SHIELD

SPARE SW

SPARE SW COMMON

DIFFERENTIAL INPUT SW

DIFFERENTIAL INPUT SW COMMON

SPEED SW

SPEED SW COMMON

ACCESS SW

ACCESS SW COMMON

EMERGENCY RESTART SW

EMERGENCY RESTART SW COM

EXTERNAL RESET SW

EXTERNAL RESET SW COMMON

COMM1 RS485 +

COMM1 RS485 –

COMM1 SHIELD

ANALOG OUT 1

ANALOG COMMON

PHASE A CURRENT 1A

PHASE A COMMON

PHASE A CURRENT 5A

PHASE B CURRENT 1A

PHASE B COMMON

PHASE B CURRENT 5A

PHASE C CURRENT 1A

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

TERMINAL IDENTIFICATION

269

WIRING CONNECTION

369

100

PHASE C COMMON

PHASE C CURRENT 5A

NEUTRAL/GROUND COMMON

NEUTRAL/GROUND CURRENT 5A

NEUT/GND CURRENT 50:0.025A

TRIP NC

104

103

101

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

TRIP COMMON

TRIP NO

ALARM NC

ALARM COMMON

ALARM NO

AUX1 NC

AUX1 COMMON

AUX1 NO

AUX2 NC

AUX2 COMMON

AUX2 NO

POWER FILTER GROUND

POWER LINE

POWER NEUTRAL

Terminals not available on the 369

MTM B+

MTM A–

N/A

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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TERMINAL IDENTIFICATION

CHAPTER 3: INSTALLATION

3.2.3 MTM-369 Relay Conversion Terminal List

MTM

WIRING CONNECTION

369

123

105

107

109

POWER FILTER GROUND

PHASE A VOLTAGE

PHASE B VOLTAGE

PHASE C VOLTAGE

PHASE A COM

PHASE A CURRENT 5A

PHASE A CURRENT 1A

PHASE B COM

PHASE B CURRENT 5A

PHASE B CURRENT 1A

PHASE C COM

100

PHASE C CURRENT 5A

PHASE C CURRENT 1A

COMM1 RS485 +

COMM1 RS485 –

COMM1 SHIELD

ANALOG OUT 1

ANALOG OUT1 COM

ANALOG OUT 2

ANALOG OUT 2 COM

ANALOG OUT 3

ANALOG OUT 3 COM

ANALOG OUT 4

ANALOG OUT 4 COM

ANALOG SHIELD

ALARM NC

114

115

116

ALARM COM

ALARM NO

SPARE SW

SPARE SW COM

POWER LINE

124

125

POWER NEUTRAL

Terminals not available on the 369:

PULSE OUTPUT (P/O)

SW.B

N/A

3–34

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

TERMINAL IDENTIFICATION

3.2.4 MPM-369 Relay Conversion Terminal List

MPM

WIRING CONNECTION

369

PHASE A VOLTAGE

105

PHASE B VOLTAGE

PHASE C VOLTAGE

PHASE NEUTRAL

POWER FILTER GROUND

POWER SAFETY

POWER NEUTRAL

POWER LINE

107

109

108

123

126

125

124

PHASE A CURRENT 5A

PHASE A CURRENT 1A

PHASE A COM

PHASE B CURRENT 5A

PHASE B CURRENT 1A

PHASE B COM

PHASE C CURRENT 5A

PHASE C CURRENT 1A

PHASE C COM

100

ANALOG OUT 1

ANALOG OUT 2

ANALOG OUT 3

ANALOG OUT 4

ANALOG COM

ANALOG SHIELD

ALARM NC

114

115

116

ALARM COM

ALARM NO

COMM1 SHIELD

COMM1 RS485 –

COMM1 RS485 +

Terminals not available on the 369

SWITCH INPUT 1

SWITCH INPUT 2

SWITCH COM

N/A

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–35

TERMINAL IDENTIFICATION

CHAPTER 3: INSTALLATION

3.2.5 Terminal Layout

FIGURE 3–3: TERMINAL LAYOUT

3–36

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

3.3 Electrical Installation

3.3.1 Typical Wiring Diagram

FIGURE 3–4: Typical Wiring for Motor Forward/Reversing Application

3.3.2 Typical Wiring

The 369 can be connected to cover a broad range of applications and wiring will vary

depending upon the user’s protection scheme. This section will cover most of the typical

369 interconnections.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

In this section, the terminals have been logically grouped together for explanatory

purposes. A typical wiring diagram for the 369 is shown above in FIGURE 3–4: Typical

Wiring for Motor Forward/Reversing Application on page 3–37 and the terminal

arrangement has been detailed in FIGURE 3–3: TERMINAL LAYOUT on page 3–36. For

further information on applications not covered here, refer to Chapter : Applications or

contact the factory for further information.

Hazard may result if the product is not used for intended purposes. This equipment can

only be serviced by trained personnel.

Do not run signal wires in the same conduit or bundle that carries power mains or high

level voltage or currents.

3.3.3 Control Power

VERIFY THAT THE CONTROL POWER SUPPLIED TO THE RELAY IS WITHIN THE RANGE

COVERED BY THE ORDERED 369 RELAY’S CONTROL POWER.

Table 3–1: 369 POWER SUPPLY RANGES

369 POWER SUPPLY

AC RANGE

60 to 265 V

20 to 48 V

DC RANGE

50 to 300 V

20 to 60 V

The 369 has a built-in switchmode supply. It can operate with either AC or DC voltage

applied to it. The relay reboot time of the 369 is 2 seconds after the control power is

applied. For applications where the control power for the 369 is available from the same

AC source as that of the motor, it is recommended an uninterrupted power supply be used

to power up the relay or, alternatively, use a separate DC source to power up.

Extensive filtering and transient protection has been incorporated into the 369 to ensure

reliable operation in harsh industrial environments. Transient energy is removed from the

relay and conducted to ground via the ground terminal. This terminal must be connected

to the cubicle ground bus using a 10 AWG wire or a ground braid. Do not daisy-chain

grounds with other relays or devices. Each should have its own connection to the ground

bus.

The internal supply is protected via a 3.15 A slo-blo fuse that is accessible for replacement.

If it must be replaced ensure that it is replaced with a fuse of equal size (see FUSE on page

2–13).

3.3.4 Phase Current (CT) Inputs

The 369 requires one CT for each of the three motor phase currents to be input into the

relay. There are no internal ground connections for the CT inputs. Refer to Chapter :

Applications for information on two CT connections.

3–38

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

The phase CTs should be chosen such that the FLA of the motor being protected is no less

than 50% of the rated CT primary. Ideally, to ensure maximum accuracy and resolution,

the CTs should be chosen such that the FLA is 100% of CT primary or slightly less. The

maximum CT primary is 5000 A.

The 369 will measure 0.05 to 20 × CT primary rated current. The CTs chosen must be

capable of driving the 369 burden (see specifications) during normal and fault conditions

to ensure correct operation. See Section 7.4: CT Specification and Selection on page –230

for information on calculating total burden and CT rating.

For the correct operation of many protective elements, the phase sequence and CT

polarity is critical. Ensure that the convention illustrated in FIGURE 3–4: Typical Wiring for

Motor Forward/Reversing Application on page 3–37 is followed.

3.3.5 Ground Current Inputs

The 369 has an isolating transformer with separate 1 A, 5 A, and sensitive HGF (50:0.025)

ground terminals. Only one ground terminal type can be used at a time. There are no

internal ground connections on the ground current inputs.

The maximum ground CT primary for the 1 A and 5 A taps is 5000 A. Alternatively the

sensitive ground input, 50:0.025, can be used to detect ground current on high resistance

grounded systems.

The ground CT connection can either be a zero sequence (core balance) installation or a

residual connection. Note that only 1 A and 5 A secondary CTs may be used for the residual

connection. A typical residual connection is illustrated in below. The zero-sequence

connection is shown in the typical wiring diagram. The zero-sequence connection is

recommended. Unequal saturation of CTs, CT mismatch, size and location of motor,

resistance of the power system, motor core saturation density, etc. may cause false

readings in the residually connected ground fault circuit.

FIGURE 3–5: Typical Residual Connection

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

3.3.6 Zero Sequence Ground CT Placement

The exact placement of a zero sequence CT to properly detect ground fault current is

shown below. If the CT is placed over a shielded cable, capacitive coupling of phase current

into the cable shield during motor starts may be detected as ground current unless the

shield wire is also passed through the CT window. Twisted pair cabling on the zero

sequence CT is recommended.

FIGURE 3–6: Zero Sequence CT

3.3.7 Phase Voltage (VT/PT) Inputs

The 369 has three channels for AC voltage inputs each with an internal isolating

transformer. There are no internal fuses or ground connections on these inputs. The

maximum VT ratio is 240:1. These inputs are only enabled when the metering option (M) is

ordered.

The 369 accepts either open delta or wye connected VTs (see the figure below). The voltage

channels are connected wye internally, which means that the jumper shown on the delta

connection between the phase B input and the VT neutral terminals must be installed.

Polarity and phase sequence for the VTs is critical for correct power and rotation

measurement and should be verified before starting the motor. As long as the polarity

markings on the primary and secondary windings of the VT are aligned, there is no phase

3–40

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

shift. The markings can be aligned on either side of the VT. VTs are typically mounted

upstream of the motor breaker or contactor. Typically, a 1 A fuse is used to protect the

voltage inputs.

FIGURE 3–7: Wye/Delta Connection

3.3.8 Backspin Voltage Inputs

The Backspin voltage input is only operational if the optional backspin detection (B) feature

has been purchased for the relay. This input allows the 369 to sense whether the motor is

spinning after the primary power has been removed (breaker or contactor opened).

These inputs must be supplied by a separate VT mounted downstream (motor side) of the

breaker or contactor. The correct wiring is illustrated below.

FIGURE 3–8: Backspin Voltage Wiring

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

3.3.9 RTD Inputs

The 369 can monitor up to 12 RTD inputs for Stator, Bearing, Ambient, or Other

temperature applications. The type of each RTD is field programmable as: 100 ohm

Platinum (DIN 43760), 100 ohm Nickel, 120 ohm Nickel, or 10 ohm Copper. RTDs must be

the three wire type. There are no provisions for the connection of thermistors.

The 369 RTD circuitry compensates for lead resistance, provided that each of the three

leads is the same length. Lead resistance should not exceed 25 ohms per lead for platinum

and nickel type RTDs or 3 ohms per lead for Copper type RTDs.

Shielded cable should be used to prevent noise pickup in industrial environments. RTD

cables should be kept close to grounded metal casings and avoid areas of high

electromagnetic or radio interference. RTD leads should not be run adjacent to or in the

same conduit as high current carrying wires.

The shield connection terminal of the RTD is grounded in the 369 and should not be

connected to ground at the motor or anywhere else to prevent noise pickup from

circulating currents.

If 10 ohm Copper RTDs are used special care should be taken to keep the lead resistance

as low as possible to maintain accurate readings.

FIGURE 3–9: RTD Inputs

3.3.10 Digital Inputs

DO NOT CONNECT LIVE CIRCUITS TO THE 369 DIGITAL INPUTS. THEY ARE DESIGNED FOR

DRY CONTACT CONNECTIONS ONLY.

Other than the ACCESS switch input the other 5 digital inputs are programmable. These

programmable digital inputs have default settings to match the functions of the 269Plus

switch inputs (differential, speed, emergency restart, remote reset and spare). However in

addition to their default settings they can also be programmed for use as generic inputs to

set up trips and alarms or for monitoring purposes based on external contact inputs.

Note

A twisted pair of wires should be used for digital input connections.

3–42

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

3.3.11 Analog Outputs

The 369 provides 1 analog current output channel as part of the base unit and 3 additional

analog outputs with the metering option (M). These outputs are field programmable to a

full-scale range of either 0 to 1 mA (into a maximum 2.4 kΩ impedance) and 4 to 20 mA or

0 to 20 mA (into a maximum 600 Ω impedance).

As shown in the typical wiring diagram (FIGURE 3–4: Typical Wiring for Motor Forward/

Reversing Application on page 3–37), these outputs share one common return. Polarity of

these outputs must be observed for proper operation.

Shielded cable should be used for connections, with only one end of the shield grounded,

to minimize noise effects. The analog output circuitry is isolated. Transorbs limit this

isolation to 36 V with respect to the 369 safety ground.

If an analog voltage output is required, a burden resistor must be connected across the

input of the SCADA or measuring device (see the figure below). Ignoring the input

impedance of the input,

V_{FULL SCALE}

R_LOAD= -----------------------------

(EQ 3.1)

(EQ 3.2)

(EQ 3.3)

I_MAX

For 0-1 mA, for example, if 5 V full scale is required to correspond to 1 mA

V_{FULL SCALE}

5 V

0.001 A

R_LOAD= ----------------------------- = ------------------ = 5000 Ω

I_MAX

For 4-20 mA, this resistor would be

V_{FULL SCALE}

5 V

0.020 A

R_LOAD= ----------------------------- = ------------------ = 250 Ω

I_MAX

FIGURE 3–10: Analog Output Voltage Connection

3.3.12 Remote Display

The 369 display can be separated and mounted remotely up to 15 feet away from the

main relay. No separate source of control power is required for the display module. A 15

feet standard shielded network cable is used to make the connection between the display

module and the main relay. A recommended and tested cable is available from GE Multilin.

The cable should be wired as far away as possible from high current or voltage carrying

cables or other sources of electrical noise.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

In addition the display module must be grounded if mounted remotely. A ground screw is

provided on the back of the display module to facilitate this. A 12 AWG wire is

recommended and should be connected to the same ground bus as the main relay unit.

The 369 relay will still function and protect the motor without the display connected.

3.3.13 Output Relays

The 369 provides four (4) form C output relays. They are labeled Trip, Aux 1, Aux 2, and

Alarm. Each relay has normally open (NO) and normally closed (NC) contacts and can

switch up to 8 A at either 250 V AC or 30 V DC with a resistive load. The NO or NC state is

determined by the ‘no power’ state of the relay outputs.

All four output relays may be programmed for fail-safe or non-fail-safe operation. When in

fail-safe mode, output relay activation or a loss of control power will cause the contacts to

go to their power down state.

Example:

•

A fail-safe NO contact closes when the 369 is powered up (if no prior unreset trip

conditions) and will open when activated (tripped) or when the 369 loses control

power.

•

A non-fail-safe NO contact remains open when the 369 is powered up (unless a prior

unreset trip condition) and will close only when activated (tripped). If control power is

lost while the output relay is activated (NO contacts closed) the NO contacts will open.

Thus, in order to cause a trip on loss of control power to the 369, the Trip relay should be

programmed as fail-safe. See the figure below for typical wiring of contactors and

breakers for fail-safe and non-fail-safe operation. Output relays remain latched after

activation if the fault condition persists or the protection element has been programmed

as latched. This means that once this relay has been activated it remains in the active state

until the 369 is manually reset.

The Trip relay cannot be reset if a timed lockout is in effect. Lockout time will be adhered to

regardless of whether control power is present or not. The relay contacts may be reset if

motor conditions allow, by pressing the RESET key, using the REMOTE RESET switch or via

communications. The Emergency Restart feature overrides all features to reset the 369.

The rear of the 369 relay shows output relay contacts in their power down state.

Note

In locations where system voltage disturbances cause voltage levels to dip below the

control power range listed in specifications, any relay contact programmed as fail-safe

may change state. Therefore, in any application where the ‘process’ is more critical

3–44

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

than the motor, it is recommended that the trip relay contacts be programmed as non-

fail-safe. If, however, the motor is more critical than the ‘process’ then program the trip

contacts as fail-safe.

FIGURE 3–11: Hookup / Fail and Non-Failsafe Modes

Note

Latched trips and alarms are not retained after control power is removed from the 369

3.3.14 RS485 Communications

Three independent two-wire RS485 ports are provided. If option (F), the fiber optic port, is

installed and used, the COMM 3 RS485 port may not be used. The RS485 ports are isolated

as a group.

Up to 32 369s (or other devices) can be daisy-chained together on a single serial

communication channel without exceeding the driver capability. For larger systems,

additional serial channels must be added. Commercially available repeaters may also be

used to increase the number of relays on a single channel to a maximum of 254. Note that

there may only be one master device per serial communication link.

Connections should be made using shielded twisted pair cables (typically 24 AWG).

Suitable cables should have a characteristic impedance of 120 ohms (e.g. Belden #9841)

and total wire length should not exceed 4000 ft. Commercially available repeaters can be

used to extend transmission distances.

Voltage differences between remote ends of the communication link are not uncommon.

For this reason, surge protection devices are internally installed across all RS485 terminals.

Internally, an isolated power supply with an optocoupled data interface is used to prevent

noise coupling. The source computer/PLC/SCADA system should have similar transient

protection devices installed, either internally or externally, to ensure maximum reliability.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–45

ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

To ensure that all devices in a daisy-chain are at the same potential, it is imperative

that the common terminals of each RS485 port are tied together and grounded in one

location only, at the master. Failure to do so may result in intermittent or failed

communications.

Correct polarity is also essential. 369 relays must be wired with all ‘+’ terminals connected

together, and all ‘–’ terminals connected together. Each relay must be daisy-chained to the

next one. Avoid star or stub connected configurations. The last device at each end of the

daisy-chain should be terminated with a 120 ohm ¼ watt resistor in series with a 1 nF

capacitor across the ‘+’ and ‘–’ terminals. Observing these guidelines will result in a reliable

communication system that is immune to system transients.

FIGURE 3–12: RS485 Wiring

3–46

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

3.3.15 Typical Two-Speed (Low Speed/High Speed) Motor Wiring

ØA CT

100:5

GROUND CT

ØB CT

100:5

ØC CT

100:5

MOTOR

CIRCUIT

ØA CT

50:5

BREAKER

ØB CT

50:5

ØC CT

50:5

NOTES

- SPEED SWITCH INPUT DEDICATED AS TWO-SPEED MONITOR

- SPEED 1 = L & SPEED 2 = H

CONTACTORS:

H = High Speed

L = Low Speed

- SPEED 1 PROGRAMMED AS NORMAL

SPEED 2 ADDITIONAL SETPOINTS.

- ENABLE 2 SPEED MOTOR PROTECTION

- PROGRAM SPEED 2 PHASE CT PRIMARY & FLA

- SELECT SPEED 2 O/L CURVE

- PROGRAM SPEED 2 UNDERCURRENT AND/OR ACCELERATION

92 93 94 95 96 97 98 99 100

CT RATIOS SHOWN ARE JUST EXAMPLES

105 106 107 108 109 110

102 104 103 101

91 90

OPTIONAL

50:

0.025A

5A 1A COM 5A 1A COM 5A 1A COM 1A COM 5A

VA VN VB VN VC VN

Back Spin

Option (B)

VOLTAGE INPUTS

Phase A

Phase B

Phase C

Neut/Gnd

GROUND

BUS

WITH METERING OPTION (M)

CURRENT INPUTS

FILTER GROUND

LINE

NEUTRAL

123

124

125

126

CONTROL

POWER

STATOR

WINDING 1

RTD1

Com

SAFETY GROUND

GE Multilin

shld.

380VAC/125VDC

STATOR

WINDING 2

111

112

113

114

115

116

117

118

119

120

121

122

369

Motor Management

TRIP

RTD2

RTD3

RTD4

RTD5

RTD6

RTD7

RTD8

RTD9

RTD10

RTD11

RTD12

Com

shld.

Relay

ALARM

AUX. 1

AUX. 2

STATOR

WINDING 3

ALARM

NOTE

RELAY CONTACTS SHOWN

WITH

Com

shld.

RTD

ALARM

CONTROL POWER REMOVED

STATOR

WINDING 4

Com

shld.

SELF TEST

ALARM

STATOR

WINDING 5

SPARE

STARTER STATUS

DIFFERENTIAL

RELAY

Com

shld.

DIFFERENTIAL

RELAY

STATOR

WINDING 6

SPEED

SWITCH

SPEED 2 MONITOR SWITCH

Com

shld.

ACCESS

SWITCH

KEYSWITCH

OR JUMPER

MOTOR

BEARING 1

EMERGENCY

RESTART

Com

shld.

EXTERNAL

RESET

MOTOR

BEARING 2

load

RS485

Com

shld.

Watts

PUMP

BEARING 1

cpm-

Shield

Com-

shld.

Com

shld.

Shield

METER

PUMP

BEARING 2

PLC

Com

shld.

Profibus (option P or P1)

Modbus/TCP (option E)

DeviceNet

Option (D)

PUMP

CASE

ST CONNECTION

SCADA

Com

shld.

CHANNEL 1

RS485

CHANNEL 2

RS485

CHANNEL 3

OPTION (F)

DB-9

(front)

RS485

FIBER

SHLD Tx Rx

AMBIENT

SHLD

50/125 uM FIBER

62.5/125 uM FIBER

100/140 uM FIBER

Com

shld.

71 72 73 74 75 76 77 78 79

RTD1

369

COMPUTER

REMOTE

RTD

MODULE

TXD

RXD

TXD

RXD

RTD12

369 PC

PROGRAM

SGND

9 PIN

CONNECTOR

840837A1.CDR

25 PIN

CONNECTOR

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–47

ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

The following additional setpoints should be programmed:

ENABLE 2 SPEED MOTOR PROTECTION under 5.3.2: CT/VT Setup

Program SPEED2 PHASE CT PRIMARY, SPEED2 MOTOR FLA, and SPEED 2 SYSTEM

PHASE SEQUENCE under 5.3.2: CT/VT Setup.

Select SPEED2 O/L CURVES under 5.13: S12 Two-speed Motor.

Program SPEED2 UNDERCURRENT and SPEED2 ACCELERATION under 5.13: S12

Two-speed Motor.

Note

1. Speed switch input dedicated as Two-speed monitor.

2. Speed 1 = L (Low) ; Speed 2 = H (High).

3. Speed 1 programmed as normal.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

ELECTRICAL INSTALLATION

3.3.16 Typical Motor Forward/Reverse Wiring

REVERSE CONTACTOR

HGF-CT

CIRCUIT BREAKER

(5 Amp CT)

MOTOR

FORWARD CONTACTOR

Twisted

Pair

OPTIONAL

92 93 94 95 96 97 98 99 100

104

91 90

105 106 107 108 109 110

102

103 101

50:

5A 1A COM 5A 1A COM 5A 1A COM 1A COM 5A

VA VN VB VN VC VN

0.025A

Back Spin

Option (B)

Neut/Gnd

VOLTAGE INPUTS

Phase A

Phase B

Phase C

GROUND

BUS

WITH METERING OPTION (M)

CURRENT INPUTS

FILTER GROUND

123

124

125

126

CONTROL

POWER

LINE

STATOR

NEUTRAL

WINDING 1

RTD1

Com

SAFETY GROUND

GE Multilin

shld.

380VAC/125VDC

STATOR

111

112

113

114

115

116

117

118

119

120

121

122

369

Motor Management

WINDING 2

TRIP

RTD2

RTD3

RTD4

RTD5

RTD6

RTD7

RTD8

RTD9

RTD10

RTD11

RTD12

Com

shld.

Relay ^R

ALARM

AUX. 1

AUX. 2

STATOR

ALARM

WINDING 3

NOTE

RELAY CONTACTS SHOWN

WITH

Com

shld.

RTD

CONTROL POWER REMOVED

ALARM

STATOR

WINDING 4

Com

shld.

SELF TEST

ALARM

STATOR

WINDING 5

SPARE

STARTER STATUS

DIFFERENTIAL

Com

shld.

DIFFERENTIAL

RELAY

STATOR

SPEED

WINDING 6

SPEED 2 MONITOR SWITCH

SWITCH

Com

shld.

KEYSWITCH

OR JUMPER

ACCESS

SWITCH

MOTOR

EMERGENCY

RESTART

BEARING 1

Com

shld.

EXTERNAL

RESET

MOTOR

BEARING 2

load

RS485

Com

shld.

Watts

PUMP

BEARING 1

cpm-

Com-

shld.

Com

shld.

Shield

METER

Shield

PUMP

PLC

BEARING 2

HUB

Ethernet

Com

shld.

Profibus

Option (E)

DeviceNet

Option (P)

Option (D)

PUMP

CASE

RJ-45

ST CONNECTION

SCADA

Com

shld.

CHANNEL 1

RS485

CHANNEL 2

RS485

CHANNEL 3

OPTION (F)

DB-9

(front)

RS485

FIBER

AMBIENT

SHLD

SHLD Tx

50/125 uM FIBER

62.5/125 uM FIBER

100/140 uM FIBER

Com

shld.

71 72 73 74 75 76 77 78 79

RTD1

369

COMPUTER

REMOTE

RTD

TXD

RXD

TXD

MODULE

RTD12

369 PC

PROGRAM

SGND

9 PIN

CONNECTOR

840708A1.CDR

25 PIN

CONNECTOR

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ELECTRICAL INSTALLATION

CHAPTER 3: INSTALLATION

The following additional setpoints should be programmed:

Enable 2-SPEED MOTOR PROTECTION under 5.3.2: CT/VT Setup.

Program SPEED2 PHASE CT PRIMARY, SPEED2 MOTOR FLA, and SPEED2 SYSTEM

PHASE SEQUENCE under 5.3.2: CT/VT Setup.

Select SPEED2 O/L CURVES under 5.13: S12 Two-speed Motor.

Program SPEED2 UNDERCURRENT and SPEED2 ACCELERATION under 5.13: S12

Two-speed Motor.

Note

1. VT must be connected on the breaker side of the contactor for proper power metering

and phase reversal trip protection.

2. The system phase sequence of the VT input to the 369 must be the same as the

system phase sequence setpoint and the phase sequence for forward rotation of the

motor.

3. The phase sequence for the reverse direction must be set as the Speed 2 phase

sequence.

4. Speed switch input dedicated as the Two-Speed monitor.

5. Speed 1 = F (Forward); Speed 2 = R (Reverse).

6. Speed 1 programmed as normal.

3–50

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

REMOTE RTD MODULE (RRTD)

3.4 Remote RTD Module (RRTD)

3.4.1 Mechanical Installation

The optional remote RTD module is designed to be mounted near the motor. This

eliminates the need for multiple RTD cables to run back from the motor which may be in a

remote location to the switchgear. Although the module is internally shielded to minimize

noise pickup and interference, it should be mounted away from high current conductors or

sources of strong magnetic fields.

The remote RTD module physical dimensions and mounting (drill diagram) are shown

below. Mounting hardware (bolts and washers) and instructions are provided with the

module.

FIGURE 3–13: Remote RTD Dimensions

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–51

REMOTE RTD MODULE (RRTD)

CHAPTER 3: INSTALLATION

FIGURE 3–14: Remote RTD Rear View

3–52

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

REMOTE RTD MODULE (RRTD)

3.4.2 Electrical Installation

FIGURE 3–15: Remote RTD Module

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

3–53

CT INSTALLATION

CHAPTER 3: INSTALLATION

3.5 CT Installation

3.5.1 Phase CT Installation

FIGURE 3–16: Phase CT Installation

3–54

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 3: INSTALLATION

CT INSTALLATION

3.5.2 5 Amp Ground CT Installation

FIGURE 3–17: 5 A Ground CT Installation

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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CT INSTALLATION

CHAPTER 3: INSTALLATION

3.5.3 HGF (50:0.025) Ground CT Installation

FIGURE 3–18: HGF (50:0.025) Ground CT Installation, 3" and 5" Window

FIGURE 3–19: HGF (50:0.025) Ground CT Installation, 8" Window

3–56

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 4: User Interfaces

User Interfaces

4.1 Faceplate Interface

4.1.1 Display

All messages are displayed on a 40-character LCD display to make them visible under poor

lighting conditions and from various viewing angles. Messages are displayed in plain

English and do not require the aid of an instruction manual for deciphering. While the

keypad and display are not actively being used, the display will default to user defined

status messages. Any trip, alarm, or start inhibit will automatically override the default

messages and appear on the display.

4.1.2 LED Indicators

There are ten LED indicators, as follows:

•

TRIP: Trip relay has operated (energized)

ALARM: Alarm relay has operated (energized)

AUX 1: Auxiliary relay has operated (energized)

AUX 2: Auxiliary relay has operated (energized)

SERVICE: Relay in need of technical service.

STOPPED: Motor is in the Stopped condition

STARTING: Motor is in the Starting condition

RUNNING: Motor is in the Running condition

OVERLOAD: Motor is in the Overload condition

LOCKOUT: Motor is in the Lockout condition

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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FACEPLATE INTERFACE

CHAPTER 4: USER INTERFACES

FIGURE 4–1: LED Indicators - Enhanced Faceplate

FIGURE 4–2: LED Indicators - Basic Faceplate

4.1.3 RS232 Program Port

This port is intended for connection to a portable PC. Setpoint files may be created at any

location and downloaded through this port using the EnerVista 369 Setup software. Local

interrogation of Setpoints and Actual Values is also possible. New firmware may be

downloaded to the 369 Relay flash memory through this port. Upgrading of the relay

firmware does not require a hardware EPROM change.

4.1.4 Keypad

The 369 Relay messages are organized into pages under the main headings, Setpoints and

Actual Values. The [SETPOINTS] key is used to navigate through the page headers of the

programmable parameters. The [ACTUAL VALUES] key is used to navigate through the

page headers of the measured parameters.

Each page is broken down further into logical subgroups of messages. The [PAGE] up and

down keys may be used to navigate through the subgroups.

•

[SETPOINTS]: This key may be used to navigate through the page headers of the

programmable parameters. Alternately, one can press this key followed by using

the Page Up / Page Down keys.

•

[ACTUAL VALUES]: This key is used to navigate through the page headers of the

measured parameters. Alternately, one can scroll through the pages by pressing

the Actual Values key followed by using the Page Up / Page Down keys.

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•

[PAGE]: The Page Up/ Page Down keys may be used to scroll through page headers

for both Setpoints and Actual Values.

[LINE]: Once the required page is found, the Line Up/ Line Down keys may be used

to scroll through the sub-headings.

[VALUE]: The Value Up and Value Down keys are used to scroll through variables in

the Setpoint programming mode. It will increment and decrement numerical

Setpoint values, or alter yes/no options.

•

[RESET]: The reset key may be used to reset a trip or latched alarm, provided it has

been activated by selecting the local reset.

[ENTER] The key is dual purpose. It is used to enter the subgroups or store altered

setpoint values.

[CLEAR] The key is also dual purpose. It may be used to exit the subgroups or to

return an altered setpoint to its original value before it has been stored.

[HELP]: The help key may be pressed at any time for context sensitive help

messages; such as the Setpoint range, etc.

To enter setpoints, select the desired page header. Then press the [LINE UP] / [LINE DOWN]

keys to scroll through the page and find the desired subgroup. Once the desired subgroup

is found, press the [VALUE UP] / [VALUE DOWN] keys to adjust the setpoints. Press the

[ENTER] key to save the setpoint or the [CLEAR] key to revert back to the old setpoint.

4.1.5 Setpoint Entry

In order to store any setpoints, Terminals 57 and 58 (access terminals) must be shorted (a

key switch may be used for security). There is also a Setpoint Passcode feature that may be

enabled to restrict access to setpoints. The passcode must be entered to allow the

changing of setpoint values. A passcode of 0 effectively turns off the passcode feature and

only the access jumper is required for changing setpoints.

If no key is pressed for 30 minutes, access to setpoint values will be restricted until the

passcode is entered again. To prevent setpoint access before the 30 minutes expires, the

unit may be turned off and back on, the access jumper may be removed, or the SETPOINT

ACCESS setpoint may be changed to Restricted. The passcode cannot be entered until

terminals 57 and 58 (access terminals) are shorted.

Setpoint changes take effect immediately, even when motor is running. It is not

recommended, however, to change setpoints while the motor is running as any mistake

could cause a nuisance trip.

Refer to Section 5.2.1: Setpoint Access on page –111 for a detailed description of the

setpoint access procedure.

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4.2 EnerVista 369 Setup Interface

4.2.1 Hardware and Software Requirements

The following minimum requirements must be met for the EnerVista 369 Setup software to

operate on your computer.

•

Pentium class or higher processor (Pentium II 300 MHz or better recommended)

Microsoft Windows 95, 98, 98SE, ME, NT 4.0 (SP4 or higher), 2000, XP

64 MB of RAM (256 MB recommended)

Minimum of 50 MB hard disk space (200 MB recommended)

If EnerVista 369 Setup is currently installed, note the path and directory name. It may be

required during upgrading.

The EnerVista 369 Setup software is included on the GE enerVista CD that accompanied

the 369 Relay. The software may also be downloaded from the GE Multilin website at http:/

/www.GEindustrial.com/multilin.

4.2.2 Installing EnerVista 369 Setup

After ensuring these minimum requirements, use the following procedure to install the

EnerVista 369 Setup software from the enclosed GE enerVista CD.

Z Insert the GE enerVista CD into your CD-ROM drive.

Z Click the Install Now button and follow the installation instructions

to install the no-charge enerVista software on the local PC.

Z When installation is complete, start the enerVista Launchpad

application.

Z Click the IED Setup section of the Launch Pad window.

Z In the enerVista LaunchPad window, click the Add Product button

and select the “369 Motor Management Relay” as shown below.

Select the “Web” option to ensure the most recent software release,

or select “CD” if you do not have a web connection, then click the

Add Now button to list software items for the 369 Relay.

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EnerVista Launchpad will obtain the installation program from the Web or CD.

Z Once the download is complete, double-click the installation

program to install the EnerVista 369 Setup software.

The program will request the user to create a backup 3.5" floppy-disk set.

Z If this is desired, click on the Start Copying button; otherwise, click

on the CONTINUE WITH 369 Relay INSTALLATION button.

Z Select the complete path, including the new directory name, where

the EnerVista 369 Setup software will be installed.

Z Click on Next to begin the installation.

The files will be installed in the directory indicated and the

installation program will automatically create icons and add

EnerVista 369 Setup software to the Windows start menu.

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Z Click Finish to end the installation.

The 369 Relay device will be added to the list of installed IEDs in the

enerVista Launchpad window, as shown below.

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4.3 Connecting EnerVista 369 Setup to the Relay

4.3.1 Configuring Serial Communications

Before starting, verify that the serial cable is properly connected to either the RS232 port

on the front panel of the device (for RS232 communications) or to the RS485 terminals on

the back of the device (for RS485 communications).

This example demonstrates an RS232 connection. For RS485 communications, the GE

Multilin F485 converter will be required. Refer to the F485 manual for additional details. To

configure the relay for Ethernet communications, see Configuring Ethernet

Communications on page 4–65.

Z Install and start the latest version of the EnerVista 369 Setup

software (available from the GE enerVista CD).

See the previous section for the installation procedure.

Z Click on the Device Setup button to open the Device Setup window.

Z Click the Add Site button to define a new site.

Z Enter the desired site name in the Site Name field.

If desired, a short description of site can also be entered along with

the display order of devices defined for the site. In this example, we

will use “Substation 1” as the site name.

Z Click the OK button when complete.

The new site will appear in the upper-left list in the EnerVista 369 Setup window.

Z Click the Add Device button to define the new device.

Z Enter the desired name in the Device Name field and a description

(optional) of the site.

Z Select “Serial” from the Interface drop-down list.

This will display a number of interface parameters that must be

entered for proper RS232 functionality.

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Z Enter the slave address and COM port values (from the S1 369

RELAY SETUP ÖØ 369 RELAY COMMUNICATIONS menu) in the

Slave Address and COM Port fields.

Z Enter the physical communications parameters (baud rate and

parity settings) in their respective fields.

Z Click the Read Order Code button to connect to the 369 Relay device

and upload the order code.

If an communications error occurs, ensure that the 369 Relay serial

communications values entered in the previous step correspond to

the relay setting values.

Z Click OK when the relay order code has been received.

The new device will be added to the Site List window (or Online

window) located in the top left corner of the main EnerVista 369

Setup window.

The 369 Relay Site Device has now been configured for serial communications. Proceed to

Connecting to the Relay on page 4–67 to begin communications.

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4.3.2 Using the Quick Connect Feature

The Quick Connect button can be used to establish a fast connection through the front

panel RS232 port of a 369 Relay relay. The following window will appear when the Quick

Connect button is pressed:

As indicated by the window, the Quick Connect feature quickly connects the EnerVista 369

Setup software to a 369 Relay front port with the following settings: 9600 baud, no parity, 8

bits, 1 stop bit. Select the PC communications port connected to the relay and press the

Connect button.

The EnerVista 369 Setup software will display a window indicating the status of

communications with the relay. When connected, a new Site called “Quick Connect” will

appear in the Site List window. The properties of this new site cannot be changed.

The 369 Relay Site Device has now been configured via the Quick Connect feature for serial

communications. Proceed to Connecting to the Relay on page 4–67 to begin

communications.

4.3.3 Configuring Ethernet Communications

Before starting, verify that the Ethernet cable is properly connected to the MultiNET device,

and that the MultiNET has been configured and properly connected to the relay. Refer to

the MultiNET manual for additional details on configuring the MultiNET to work with the

369 Relay.

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Z Install and start the latest version of the EnerVista 369 Setup

software (available from the GE enerVista CD).

See the previous section for the installation procedure.

Z Click on the Device Setup button to open the Device Setup window.

Z Click the Add Site button to define a new site.

Z Enter the desired site name in the Site Name field.

If desired, a short description of site can also be entered along with

the display order of devices defined for the site. In this example, we

will use “Substation 2” as the site name.

Z Click the OK button when complete.

The new site will appear in the upper-left list in the EnerVista 369 Setup window.

Z Click the Add Device button to define the new device.

Z Enter the desired name in the Device Name field and a description

(optional) of the site.

Z Select Ethernet from the Interface drop-down list.

This will display a number of interface parameters that must be

entered for proper Ethernet functionality.

Z Enter the IP address assigned to the MultiNET adapter.

Z Enter the slave address and Modbus port values (from the S1 369

RELAY SETUP ÖØ 369 RELAY COMMUNICATIONS menu) in the

Slave Address and Modbus Port fields.

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Z Click the Read Order Code button to connect to the 369 Relay device

and upload the order code.

If an communications error occurs, ensure that the 369 Relay

Ethernet communications values entered in the previous step

correspond to the relay and MultiNET setting values.

Z Click OK when the relay order code has been received.

The new device will be added to the Site List window (or Online

window) located in the top left corner of the main EnerVista 369

Setup window.

The 369 Relay Site Device has now been configured for Ethernet communications. Proceed

to the following section to begin communications.

4.3.4 Connecting to the Relay

Now that the communications parameters have been properly configured, the user can

easily connect to the relay.

Z Expand the Site list by double clicking on the site name or clicking on

the «+» box to list the available devices for the given site (for

example, in the “Substation 1” site shown below).

Z Desired device trees can be expanded by clicking the «+» box. The

following list of headers is shown for each device:

•

Device Definitions

Settings

Actual Values

Commands

Communications

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Z Expand the Settings > Relay Setup list item and double click on Front

Panel to open the Front Panel settings window as shown below:

FIGURE 4–3: Main Window After Connection

The Front Panel settings window will open with a corresponding status indicator

on the lower left of the EnerVista 369 Setup window.

Z If the status indicator is red, verify that the serial or Ethernet cable is

properly connected to the relay, and that the relay has been properly

configured for communications (steps described earlier).

The Front Panel settings can now be edited, printed, or changed according to user

specifications. Other setpoint and commands windows can be displayed and edited in a

similar manner. Actual values windows are also available for display. These windows can

be locked, arranged, and resized at will.

Note

Refer to the EnerVista 369 Setup Help File for additional information about the using

the software.

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4.4 Working with Setpoints and Setpoint Files

4.4.1 Engaging a Device

The EnerVista 369 Setup software may be used in on-line mode (relay connected) to

directly communicate with a 369 Relay relay. Communicating relays are organized and

grouped by communication interfaces and into sites. Sites may contain any number of

relays selected from the SR or UR product series.

4.4.2 Entering Setpoints

The System Setup page will be used as an example to illustrate the entering of setpoints. In

this example, we will be changing the current sensing setpoints.

Z Establish communications with the relay.

Z Select the Setpoint > S2 System Setup > CT/VT Setup menu item.

This can be selected from the device setpoint tree or the main

window menu bar.

Z Select the PHASE CT PRIMARY setpoint by clicking anywhere in

the parameter box.

This will display three arrows: two to increment/decrement the value

and another to launch the numerical calculator.

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Z Clicking the arrow at the end of the box displays a numerical keypad

interface that allows the user to enter a value within the setpoint

range displayed near the top of the keypad:

Z Click Accept to exit from the keypad and keep the new value.

Z Click on Cancel to exit from the keypad and retain the old value.

Z For setpoints requiring non-numerical pre-set values (e.g. GROUND

CT TYPE above), clicking anywhere within the setpoint value box

displays a drop-down selection menu arrow. Select the desired value

from this list.

Z For setpoints requiring an alphanumeric text string (e.g. message

scratchpad messages), the value may be entered directly within the

setpoint value box.

Z Click on Save to save the values into the 369 Relay.

Z Click OK to accept any changes and exit the window.

Z Otherwise, click Restore to retain previous values and exit.

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4.4.3 File Support

Opening any EnerVista 369 Setup file will automatically launch the application or provide

focus to the already opened application. If the file is a settings file (has a ‘369 Relay’

extension) which had been removed from the Settings List tree menu, it will be added back

to the Settings List tree.

New files will be automatically added to the tree, which is sorted alphabetically with

respect to settings file names.

4.4.4 Using Setpoints Files

Overview

The EnerVista 369 Setup software interface supports three ways of handling changes to

relay settings:

•

In off-line mode (relay disconnected) to create or edit relay settings files for later

download to communicating relays.

Directly modifying relay settings while connected to a communicating relay, then

saving the settings when complete.

Creating/editing settings files while connected to a communicating relay, then

saving them to the relay when complete.

Settings files are organized on the basis of file names assigned by the user. A settings file

contains data pertaining to the following categories of relay settings:

•

Device Definition

Product Setup

System Setup

Grouped Elements

Control Elements

Inputs/Outputs

Testing

Factory default values are supplied and can be restored after any changes.

The EnerVista 369 Setup software displays relay setpoints with the same hierarchy as the

front panel display. For specific details on setpoints, refer to Chapter 5.

Downloading and Saving Setpoints Files

Setpoints must be saved to a file on the local PC before performing any firmware

upgrades. Saving setpoints is also highly recommended before making any setpoint

changes or creating new setpoint files.

The EnerVista 369 Setup window, setpoint files are accessed in the Settings List control bar

window or the Files Window. Use the following procedure to download and save setpoint

files to a local PC.

Z Ensure that the site and corresponding device(s) have been properly

defined and configured as shown in Connecting EnerVista 369 Setup

to the Relay on page 4–63.

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Z Select the desired device from the site list.

Z Select the File > Read Settings from Device menu item to obtain

settings information from the device.

After a few seconds of data retrieval, the software will request the name and

destination path of the setpoint file. The corresponding file extension will be

automatically assigned.

Z Press Save to complete the process.

A new entry will be added to the tree, in the File pane, showing path

and file name for the setpoint file.

Adding Setpoints Files to the Environment

The EnerVista 369 Setup software provides the capability to review and manage a large

group of setpoint files. Use the following procedure to add a new or existing file to the list.

Z In the files pane, right-click on ‘Files’.

Z Select the Add Existing Setting File item as shown

The Open dialog box will appear, prompting the user to select a previously saved

setpoint file.

Z As for any other Microsoft Windows^®application, browse for the file

to be added then

Z Click Open.

The new file and complete path will be added to the file list.

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Creating a New Settings File using Motor Settings Auto-Config

The EnerVista 369 Setup software allows the user to create new Settings files independent

of a connected device. These can be uploaded to a relay at a later date.

One method of doing this - the EnerVista Motor Settings Auto-Config option - allows the

user to easily create new Settings Files automatically, using a guided step-by-step process

as outlined below.

Note

The Motor Settings Auto-Config option does NOT allow the user to configure existing

Settings Files.

The following procedure illustrates how to create new Settings Files using the Motor

Settings Auto-Config option:

Z At the top of the screen, click on the Motor Settings Auto-Config

button.

Z On the main menu, select File > Motor Settings Auto-Configurator

The EnerVista 369 Setup software displays the following box, allowing the

configuration of the Settings File as shown.

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Note

It is important to define the correct firmware version to ensure that settings not available

in a particular version are not downloaded into the relay

Z Select the Firmware Version for the new Settings File.

Z For future reference, enter some useful information in the

Description box to facilitate the identification of the device and the

purpose of the file.

Z To select a file name and path for the new file, click the button [...]

beside the File Name box.

Z Select the file name and path to store the file, or select any displayed

file name to update an existing file.

All 369 Relay Settings Files should have the extension ‘369 Relay’ (for

example, ‘motor1.369 Relay’).

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Z Click Next and OK to continue the process.

A new window - Step 1 - will appear:

Z Fill in the fields as indicated.

Z When complete, press Next.

The next window - Step 2 - will appear as follows:

Note

As each Step is completed, the user will be prompted to make appropriate changes to

what has been entered, if the Auto-Configurator determines that the parameter

entered is incorrect or inappropriate for the situation.

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Z Continue filling in the fields as indicated.

Once you have completed all 6 Steps, the final window will show as follows:

Z Click Finish to complete the Auto-Config procedure.

The Motor Settings Auto-Configurator window will disappear.

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A new Settings File containing the parameters you have just input will appear in

the Files pane as shown:

Creating a New Settings File without using Motor Settings Auto-Config

The EnerVista 369 Setup software allows the user to create new Settings files independent

of a connected device. These can be uploaded to a relay at a later date. The following

manual procedure - as distinct from the Motor Settings Auto-Config option described

above - illustrates how to create new Settings Files.

Z In the File pane, right click on File.

Z Select the New Settings File item.

The EnerVista 369 Setup software displays the following window,

allowing the configuration of the Settings File as shown below.

Note

Note that this window allows you to choose between creating your Settings File

manually or using the Motor Settings Auto-Configurator as detailed above.

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Note

It is important to define the correct firmware version to ensure that settings not available

in a particular version are not downloaded into the relay

Z Select the Firmware Version for the new Settings File.

Z For future reference, enter some useful information in the

Description box to facilitate the identification of the device and the

purpose of the file.

Z To select a file name and path for the new file, click the button

beside the File Name box [...].

Z Select the file name and path to store the file, or select any displayed

file name to update an existing file.

All 369 Relay Settings Files should have the extension ‘369 Relay’ (for

example, ‘motor1.369 Relay’).

Z Click the appropriate radio button (yes or no) to choose between

Auto-Configurator or manual creation of the Settings File.

Z Click OK to complete the process.

Once this step is completed, the new file, with a complete path, will

be added to the EnerVista 369 Setup software environment.

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Z Enter the appropriate settings manually to complete the new

Settings File.

Creating a New Setpoint File

The EnerVista 369 Setup software allows the user to create new setpoint files independent

of a connected device. These can be uploaded to a relay at a later date. The following

procedure illustrates how to create new setpoint files.

Z In the File pane, right click on File.

Z Select the New Settings File item.

The EnerVista 369 Setup software displays the following box will

appear, allowing the configuration of the setpoint file for the correct

firmware version. It is important to define the correct firmware

version to ensure that setpoints not available in a particular version

are not downloaded into the relay.

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Z Select the firmware version.

Z For future reference, enter some useful information in the

Description box to facilitate the identification of the device and the

purpose of the file.

Z Enter any installed options (metering/backspin and Profibus), as well

as the slave addresses of any remote RTDs.

Note that the RRTD units must be connected in order from 1 to 4. If

only one RRTD is used, it's slave address must be programmed under

RRTD1 Slave Address. The next RRTD to be connected would be set

up under RRTD2 Slave Address, and so forth.

Z To select a file name and path for the new file, click the button

beside the Enter File Name box.

Z Select the file name and path to store the file, or select any displayed

file name to update an existing file.

All 369 Relay setpoint files should have the extension ‘369 Relay’ (for

example, ‘motor1.369 Relay’).

Z Click Save and OK to complete the process.

Once this step is completed, the new file, with a complete path, will

be added to the EnerVista 369 Setup software environment.

Upgrading Setpoint Files to a New Revision

It is often necessary to upgrade the revision code for a previously saved setpoint file after

the 369 Relay firmware has been upgraded (for example, this is required for firmware

upgrades). This is illustrated in the following procedure.

Z Establish communications with the 369 Relay.

Z Select the Actual > A5 Product Info menu item and record the

Software Revision identifier of the relay firmware.

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Z Load the setpoint file to be upgraded into the EnerVista 369 Setup

environment as described in Adding Setpoints Files to the

Environment on page 4–72.

Z In the File pane, select the saved setpoint file.

Z From the main window menu bar, select the File > Properties menu

item.

Z Note the File Version of the setpoint file.

If this version (e.g. 5.00 shown below) is different from the Software

Revision code noted in step 2, select a New File Version that

matches the Software Revision code from the pull-down menu.

For example, if the firmware revision is 27I600A4.000 (software revision 6.00) and

the current setpoint file revision is 5.00, change the setpoint file revision to “6.0X”.

Z When complete, click Convert to convert the setpoint file to the

desired revision.

A dialog box will request confirmation. See Loading Setpoints from a

File on page 4–82 for instructions on loading this setpoint file into the

369 Relay.

Printing Setpoints and Actual Values

The EnerVista 369 Setup software allows the user to print partial or complete lists of

setpoints and actual values. Use the following procedure to print a list of setpoints:

Z Select a previously saved setpoints file in the File pane or establish

communications with a 369 Relay device.

Z From the main window, select the File > Print Settings menu item.

The Print/Export Options dialog box will appear.

Z Select Settings in the upper section.

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Z Select either Include All Features (for a complete list) or Include Only

Enabled Features (for a list of only those features which are

currently used) in the filtering section.

Z Click OK.

The process for File > Print Preview Settings is identical to the steps above.

Setpoints lists can be printed in the same manner by right clicking on the desired file (in the

file list) or device (in the device list) and selecting the Print Device Information or Print

Settings File options.

A complete list of actual values can also be printed from a connected device with the

following procedure:

Z Establish communications with the desired 369 Relay device.

Z From the main window, select the File > Print Settings menu item.

The Print/Export Options dialog box will appear.

Z Select Actual Values in the upper section.

Z Select either Include All Features (for a complete list) or Include Only

Enabled Features (for a list of only those features which are

currently used) in the filtering section.

Z Click OK.

Z Actual values lists can be printed in the same manner by right

clicking on the desired device (in the device list) and selecting the

Print Device Information option.

Loading Setpoints from a File

Note

An error message will occur when attempting to download a setpoint file with a

revision number that does not match the relay firmware. If the firmware has been

upgraded since saving the setpoint file, see Upgrading Setpoint Files to a New Revision

on page 4–80 for instructions on changing the revision number of a setpoint file.

The following procedure illustrates how to load setpoints from a file. Before loading a

setpoints file, it must first be added to the EnerVista 369 Setup environment as described

in Adding Setpoints Files to the Environment on page 4–72.

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Z Select the previously saved setpoints file from the File pane of the

EnerVista 369 Setup software main window.

Z Select the File > Properties menu item and verify that the

corresponding file is fully compatible with the hardware and

firmware version of the target relay.

If the versions are not identical, see Upgrading Setpoint Files to a

New Revision on page 4–80 for details on changing the setpoints file

version.

Z Right-click on the selected file.

Z Select the Write Settings to Device item.

Z Select the target relay from the list of devices shown.

Z Click Send.

If there is an incompatibility, an error will occur: If there are no

incompatibilities between the target device and the settings file, the

data will be transferred to the relay. An indication of the percentage

completed will be shown in the bottom of the main window.

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4.5 Upgrading Relay Firmware

4.5.1 Description

To upgrade the 369 Relay firmware, follow the procedures listed in this section. Upon

successful completion of this procedure, the 369 Relay will have new firmware installed

with the original setpoints.

The latest firmware files are available from the GE Multilin website at http://

www.GEindustrial.com/multilin.

4.5.2 Saving Setpoints to a File

Before upgrading firmware, it is very important to save the current 369 Relay settings to a

file on your PC. After the firmware has been upgraded, it will be necessary to load this file

back into the 369 Relay.

Refer to Downloading and Saving Setpoints Files on page 4–71 for details on saving relay

setpoints to a file.

4.5.3 Loading New Firmware

Loading new firmware into the 369 Relay flash memory is accomplished as follows:

Z Connect the relay to the local PC and save the setpoints to a file as

shown in Downloading and Saving Setpoints Files on page 4–71.

Z Select the Communications > Update Firmware menu item.

The following warning message will appear: Select Yes to proceed or

No the cancel the process.

Z Do NOT proceed unless you have saved the current setpoints.

The EnerVista 369 Setup software will request the new firmware file.

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Z Locate the firmware file to load into the 369 Relay.

The firmware filename has the following format:

53 CMC 320 . 000

Modification Number (000 = None)

Firmware Version (320 = 3.20)

Internal Identifier

Product Code (53 = 369)

The EnerVista 369 Setup software automatically lists all filenames beginning with

‘53’.

Z Select the appropriate file.

Z Click OK to continue.

The software will prompt with another Upload Firmware Warning window. This will

be the final chance to cancel the firmware upgrade before the flash memory is

erased.

Z Click Yes to continue or No to cancel the upgrade.

The EnerVista 369 Setup software now prepares the 369 Relay to receive the new

firmware file. The 369 Relay will display a message indicating that it is in Upload

Mode. While the file is being loaded into the 369 Relay, a status box appears

indicating how much of the new firmware file has been transferred and how much

is remaining, as well as the upgrade status. The entire transfer process takes

approximately five minutes.

The EnerVista 369 Setup software will notify the user when the 369 Relay has

finished loading the file.

Z Carefully read any displayed messages.

Z Click OK to return the main screen.

Note

Cycling power to the relay is highly recommended after a firmware upgrade.

After successfully updating the 369 Relay firmware, the relay will not be in service and will

require setpoint programming. To communicate with the relay, the following settings will

have to be manually programmed.

SLAVE ADDRESS

BAUD RATE

PARITY (if applicable)

When communications is established, the saved setpoints must be reloaded back into the

relay. See Loading Setpoints from a File on page 4–82 for details.

Modbus addresses assigned to firmware modules, features, settings, and corresponding

data items (i.e. default values, min/max values, data type, and item size) may change

slightly from version to version of firmware.

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The addresses are rearranged when new features are added or existing features are

enhanced or modified. The EEPROM DATA ERROR message displayed after upgrading/

downgrading the firmware is a resettable, self-test message intended to inform users that

the Modbus addresses have changed with the upgraded firmware. This message does not

signal any problems when appearing after firmware upgrades.

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4.6 Advanced EnerVista 369 Setup Features

4.6.1 Triggered Events

While the interface is in either on-line or off-line mode, data generated by triggered

specified parameters can be viewed and analyzed via one of the following features:

•

Event Recorder: The event recorder captures contextual data associated with the

last 512 events, listed in chronological order from most recent to the oldest.

•

Oscillography: The oscillography waveform traces and digital states provide a

visual display of power system and relay operation data captured during specific

triggered events.

4.6.2 Trending

Trending from the 369 Relay is accomplished via EnerVista 369 Setup. Many different

parameters can be trended and graphed at sampling periods from 1 second up to 1 hour.

The parameters which can be trended by EnerVista 369 Setup are:

•

Currents/Voltages: phase currents A/B/C; average phase current; motor load;

current unbalance; ground current; and voltages Vab, Vbc, Vca Van, Vbn and Vcn

•

Power: power factor; real power (kW); reactive power (kvar); Apparent Power (kVA);

positive watthours; positive varhours; and negative varhours

•

Temperature: Hottest Stator RTD; RTDs 1 through 12; and RRTDs 1 through 12

Other: thermal capacity used and system frequency

Z To use the Trending function, run the EnerVista 369 Setup software

and establish communications with a connected 369 Relay unit.

Z Select the Actual > Trending menu item to open the Trending

window.

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FIGURE 4–4: Trending View

Z Program the parameters to display by selecting them from the pull

down menus.

Z Select the Sample Rate.

Z Select RUN to begin the trending sampling.

The trended values can be printed using Print Trending Graph

button.

The Trending File Setup button can be used to write the graph data

to a file in a standard spreadsheet format.

Z Ensure that the Write Trended Data to File box is checked, and that

the Sample Rate is at a minimum of 5 seconds.

Z Set the file capacity limit to the amount of memory available for

trended data.

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4.6.3 Waveform Capture (Trace Memory)

The EnerVista 369 Setup software can be used to capture waveforms (or view trace

memory) from the 369 Relay relay at the instance of a trip. A maximum of 16 cycles can be

captured and the trigger point can be adjusted to anywhere within the set cycles. The last

three waveform events are viewable.

The following waveforms can be captured:

•

Phase A, B, and C currents (I_a, I_b, and I_c)

Ground and current (I_g)

Phase A-N, B-N, and C-N voltages (V_an, V_bn, and V_cn) if wye-connected

Phase A-B and C-B (V_aband V_cb) if open-delta connected

•

Digital data for output relays and contact input states.

Z With the EnerVista 369 Setup software running and communications

established, select the Actual > Waveform Capture menu item to

open the waveform capture setup window:

Z Click on Trigger Waveform to trigger a waveform capture.

The waveform file numbering starts with the number zero in the 369

Relay; therefore, the maximum trigger number will always be one

less then the total number triggers available.

Z Click on the Save to File button to save the selected waveform to the

local PC.

A new window will appear requesting for file name and path.

The file is saved as a COMTRADE File, with the extension ‘CFG’. In addition to the

COMTRADE file, two other files are saved. One is a CSV (comma delimited values)

file, which can be viewed and manipulated with compatible third-party software.

The other file is a DAT File, required by the COMTRADE file for proper display of

waveforms.

Z To view a previously saved COMTRADE File, click the Open button.

Z Select the corresponding COMTRADE File.

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Z To view the captured waveforms, click the Launch Viewer button.

A detailed Waveform Capture window will appear as shown below:

FIGURE 4–5: Waveform Capture Window Attributes

The red vertical line indicates the trigger point of the relay.

The date and time of the trip is displayed at the top left corner of the window. To

match the captured waveform with the event that triggered it, make note of the

time and date shown in the graph. Then, find the event that matches the same

time and date in the event recorder. The event record will provide additional

information on the cause and the system conditions at the time of the event.

Additional information on how to download and save events is shown in Event

Recorder on page 4–99.

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4.6.4 Motor Start Data Logger

In addition to the learned information captured for every start, the Motor Start Data

Logger will record up to 30 seconds of digital and analog waveforms during motor starts.

Captured information includes:

•

Individual and average phase current

Current unbalance

Ground current

Individual and average phase voltages

Thermal capacity used

System frequency

Breaker status contact

Motor speed (low/high)

4.6.5 Data Logger

The user-configurable Data Logger allows users to trend information to help configure

protection setpoints, as well as to schedule preventative maintenance. The Data Logger:

•

allows trending of up to 16 analog or digital parameters at a time

allows trending of any metered or calculated analog value within a provided list

allows trending of digital input and output states

stores all trended information in the relay’s volatile memory (RAM)

allows user-configurable resolution of trending from 1 second to 1 hour (3600s)

allows up to 50 Logs to be created

is available only with the Enhanced “E” option.

4.6.5.1Support in Enervista PC Software

Enervista PC Program supports the Data Logger on two screens on the Online Device

tree:

1. Setpoints: Settings > S1 Setup > Data Logger

2. Actual Values: Actual Values > A1 Motor Status > Data Logger

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4.6.5.2Setpoints

Users can configure the Data Logger Settings from Settings > S1 Setup > Data Logger

A typical Data Logger Settings screen is as follows:

The Settings in the Data Logger screen are:

Log Interval : The user can configure the Data Logger interval 1 sec to 3600 sec

Recording Type : The user can select from the two available methods of logging.

Run to Fill: Allows logging of Channel data until the memory is full, then stops.

Circulate: Allows continuous logging of Channel data .

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4.6.5.3Channel 1 to 16 Assignment

Users can configure 16 channels from the available 102 inputs (97 Analog inputs and 5

Digital Inputs/Outputs) from the screen.

The following is the list of Inputs which can be assigned to any of the 16 Channels:

Motor Thermal

Capacity Used

Local RTD #5

Temperature

RRTD 2 - RTD #7

Temperature

Digital Input and

Output Relays Status

Local RTD #6

Temperature

RRTD 2 - RTD #8

Temperature

Local RTD #7

Temperature

RRTD 2 - RTD #9

Temperature

Phase A Current

Phase B Current

Phase C Current

Local RTD #8

Temperature

RRTD 2 - RTD #10

Temperature

Local RTD #9

Temperature

RRTD 2 - RTD #11

Temperature

Average Phase

Current

Local RTD #10

Temperature

RRTD 2 - RTD #12

Temperature

Local RTD #11

Temperature

RRTD 3 - RTD #1

Temperature

Motor Load

Local RTD #12

Temperature

RRTD 3 - RTD #2

Temperature

Current Unbalance

Unbalanced Biased

Motor Load

RRTD 3 - RTD #3

Temperature

Current Demand

RRTD 3 - RTD #4

Temperature

Ground Current

Real Power Demand

Reactive Power

Demand

RRTD 3 - RTD #5

Temperature

Vab

Apparent Power

Demand

RRTD 3 - RTD #6

Temperature

Vbc

RRTD 3 - RTD #7

Temperature

Vca

Peak Current Demand 81

Peak Real Power

RRTD 3 - RTD #8

Temperature

Average Line Voltage

Demand

Peak Reactive Power

Demand

RRTD 3 - RTD #9

Temperature

Van

Vbn

Vcn

Peak Apparent Power

Demand

RRTD 3 - RTD #10

Temperature

RRTD 1 - RTD #1

RRTD 3 - RTD #11

Temperature

Average Phase

Voltage

RRTD 1 - RTD #2

RRTD 3 - RTD #12

Temperature

RRTD 1 - RTD #3

RRTD 4 - RTD #1

Temperature

System Frequency

Power Factor

Temperature

RRTD 1 - RTD #4

RRTD 4 - RTD #2

Temperature

RRTD 1 - RTD #5

RRTD 4 - RTD #3

Temperature

Real Power (kW)

Real Power (hp)

Reactive Power

Temperature

RRTD 1 - RTD #6

RRTD 4 - RTD #4

Temperature

RRTD 1 - RTD #7

RRTD 4 - RTD #5

Temperature

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RRTD 4 - RTD #6

RRTD 1 - RTD #8

Temperature

Apparent Power

Temperature

Positive

MegaWatthours

RRTD 1 - RTD #9

Temperature

RRTD 4 - RTD #7

Temperature

RRTD 1 - RTD #10

Temperature

RRTD 4 - RTD #8

Temperature

Positive Megavarhours 60

Negative

RRTD 1 - RTD #11

Temperature

RRTD 4 - RTD #9

Temperature

Megavarhours

RRTD 1 - RTD #12

Temperature

RRTD 4 - RTD #10

Temperature

Positive KiloWatthours 62

RRTD 2 - RTD #1

Temperature

RRTD 4 - RTD #11

Temperature

Positive Kilovarhours

RRTD 2 - RTD #2

Temperature

RRTD 4 - RTD #12

Temperature

Negative Kilovarhours 64

RRTD 1 – Digital Input

and Output Relays

Status

Local RTD #1

RRTD 2 - RTD #3

Temperature

RRTD 2 – Digital Input

and Output Relays

Status

Local RTD #2

RRTD 2 - RTD #4

Temperature

100

101

102

Temperature

RRTD 3 Digital Input

and Output Relays

Status

RRTD 4 Digital Input

and Output Relays

Status

Local RTD #3

RRTD 2 - RTD #5

Temperature

Local RTD #4

RRTD 2 - RTD #6

Temperature

4.6.5.4Actual Values

Actual Values > A1 Motor Status > Data Logger

This screen can be used to monitor the Datalog status , View and Save the Datalog, as well

as perform the Start/Stop operation on the Data Logger.

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A typical Actual Values screen is as follows:

4.6.5.5Log Status

Log Status displays the current state of the Data Logger, either Running or Stopped.

Memory Used displays the memory usage in % of total memory of the data logger which

varies from 0 to 100 %.

4.6.5.6Log Selection and Waveform View

Select Log allows the user to select a Log from the available logs ( maximum 50 logs

available).

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Launch Viewer button allows the user to launch and view the trend for the selected log

from the drop down box.

Save to File button allows the user to save the selected log as .CSV and .CFG file which

can be opened from the viewer (setup software) in offline mode.

Open button allows the user to open CSV and CFG files in offline mode and view the

trending information from a Log.

4.6.5.7Start /Stop/Clear Operations on the Datalogger

Start Log button allows the user to start a new Log in the Datalogger.

Stop Log button allows the user to stop a Log that is currently running

Clear Logs button allows the user to clear all the available Logs in the Datalogger

memory.

Total Logs Since Last Clear displays the number of Logs generated in data logger since

the last time the datalogger was cleared. The number varies from 0 to 65535. Starting a

new Log increments this value by 1. Clicking on Clear Logs reverts this value to 0.

4.6.5.8Log information grid

Log column displays the Log numbers that are currently available in the Datalogger

memory

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Log Start Time column displays the Date and Time (in MM/DD/YYYY, HH:MM:SS format)

when the corresponding Log is generated

Start Method column displays the method by which the Log is started . This value can be

either

•

Manual Start - if the Log is generated by clicking the Start button

Motor Start - if the Log is generated when the Motor is started from the OFF state.

Stop Method column displays the method by which the Log is stopped . This value can

be either

•

Manual Stop - if the Log is stopped by clicking the Stop button

Motor Stop - if the Log is stopped when the motor is stopped from the Running

state.

Records column displays the number of records stored in each Log.

4.6.5.9Grid Update

If the screen is kept open when the Data Log is running, information in the grid is

automatically updated in the following cases:

•

Start of a new Log (either manual start or motor start)

Stopping the current Log (either manual stop or motor stop)

Any of the existing Logs are erased when the log is running in Circulate mode

Clearing the existing Logs.

Note

If any of the above events do not occur, the data log screen will be updated

automatically every 60 seconds.

4.6.6 Motor Health Report

This reporting function is included with every 369 relay, providing critical information on

the historical operating characteristics of your motor during motor starting and stopping

operations. Included in the report are:

•

Trip summary

Motor operation historical timeline, displaying start, emergency restart, stop, trip,

and alarm conditions

•

Motor starting learned information (trending information over a maximum of 1250

motor start operations)

Motor start data logger trends, including current, current unbalance, voltage,

frequency, TCU, breaker contact status during start, and motor speed (low/high).

4.6.7 Phasors

The EnerVista 369 Setup software can be used to view the phasor diagram of three-phase

currents and voltages. The phasors are for: Phase Voltages Va, Vb, and Vc; Phase Currents

Ia, Ib, and Ic.

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Z With the EnerVista 369 Setup software running and communications

established, open the Actual Values > Metering Data window, then

Z Click on the Phasors tab.

The EnerVista 369 Setup software will display the following window:

Z Press the “View” button to display the following window:

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The 369 Motor Management Relay was designed to display lagging angles.

Therefore, if a system condition would cause the current to lead the voltage by 45°,

the 369 Relay relay will display such angle as 315° Lag instead of 45° Lead.

When the currents and voltages measured by the relay are zero, the angles displayed

by the relay and those shown by the EnerVista 369 Setup software are not fixed values.

4.6.8 Event Recorder

The 369 Relay event recorder can be viewed through the EnerVista 369 Setup software.

The event recorder stores motor and system information each time an event occurs (e.g.

breaker failure). The 369 Relay supports 512 event records. Event 512 is the most recent

event and Event 001 is the oldest event. Event 001 is overwritten whenever a new event

occurs. Refer to Event Records on page 6–20 for additional information on the event

recorder.

Use the following procedure to view the event recorder with EnerVista 369 Setup:

Z With EnerVista 369 Setup running and communications established,

select the Actual > A5 Event Recorder item from the main menu.

This displays the Event Recorder window indicating the list of

recorded events, with the most current event displayed first.

Z To view detailed information for a given event and the system

information at the moment of the event occurrence, change the

event number on the Select Event box.

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4.6.9 Modbus User Map

The EnerVista 369 Setup software provides a means to program the 369 Relay User Map

(Modbus addresses 0180h to 01FCh). Refer to User Definable Memory Map Area in the 369

Communications Guide for additional information on the User Map.

Z Select a connected device in EnerVista 369 Setup.

Z Select the Setpoint > User Map menu item to open the following

window.

The above window allows the desired addresses to be written to User Map

locations. The User Map values that correspond to these addresses are then

displayed.

4.6.10 Viewing Actual Values

You can view real-time relay data such as input/output status and measured parameters.

From the main window menu bar, selecting Actual Values opens a window with tabs, each

tab containing data in accordance to the following list:

•

Motor Status: Motor, Last Trip, Alarm Status, Start Inhibit, Local DI Status, Local

Relay Outputs, and Real Time Clock

•

Metering Data: Currents, Voltages, Power, Backspin, Local RTDs, Demand, Phasor,

and RRTDs 1 to 4

•

Learned Data: Motor Learned Data, Local RTD Maximums, RRTD 1 to 4 Maximums

Statistical Data: Trip Counters and Motor Statistics

Product Information: Revision Codes and Calibration Dates

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Selecting an actual values window also opens the actual values tree from the

corresponding device in the site list and highlights the current location in the hierarchy.

For complete details on actual values, refer to Chapter 6.

Z To view a separate window for each group of actual values, select

the desired item from the tree.

Z Double click with the left mouse button.

Each group will be opened on a separate tab. The windows can be

rearranged to maximize data viewing as shown in the following

figure (showing actual current, voltage, and power values tiled in the

same window):

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4.7 Using EnerVista Viewpoint with the 369 Relay

4.7.1 Plug and Play Example

EnerVista Viewpoint is an optional software package that puts critical 369 Relay

information onto any PC with plug-and-play simplicity. EnerVista Viewpoint connects

instantly to the 369 Relay via serial, ethernet or modem and automatically generates

detailed overview, metering, power, demand, energy and analysis screens. Installing

EnerVista Launchpad (see previous section) allows the user to install a fifteen-day trial

version of enerVista Viewpoint. After the fifteen day trial period you will need to purchase a

license to continue using enerVista Viewpoint. Information on license pricing can be found

at http://www.enerVista.com.

Z Install the EnerVista Viewpoint software from the GE enerVista CD.

Z Ensure that the 369 Relay device has been properly configured for

either serial or Ethernet communications (see previous sections for

details).

Z Click the Viewpoint window in EnerVista to log into EnerVista

Viewpoint.

At this point, you will be required to provide a login and password if

you have not already done so.

FIGURE 4–6: enerVista Viewpoint Main Window

Z Click the Device Setup button to open the Device Setup window.

Z Click the Add Site button to define a new site.

Z Enter the desired site name in the Site Name field.

If desired, a short description of site can also be entered along with

the display order of devices defined for the site.

Z Click the OK button when complete.

The new site will appear in the upper-left list in the EnerVista 369

Setup window.

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Z Click the Add Device button to define the new device.

Z Enter the desired name in the Device Name field and a description

(optional) of the site.

Z Select the appropriate communications interface (Ethernet or Serial)

and fill in the required information for the 369 Relay.

See Connecting EnerVista 369 Setup to the Relay on page 4–63 for

details.

FIGURE 4–7: Device Setup Screen (Example)

Z Click the Read Order Code button to connect to the 369 Relay device

and upload the order code.

If a communications error occurs, ensure that communications

values entered in the previous step correspond to the relay setting

values.

Z Click OK when complete.

Z From the EnerVista main window, select the IED Dashboard item to

open the Plug and Play IED dashboard.

An icon for the 369 Relay will be shown.

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FIGURE 4–8: ‘Plug and Play’ Dashboard

Z Click the Dashboard button below the 369 Relay icon to view the

device information.

We have now successfully accessed our 369 Relay through EnerVista

Viewpoint.

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FIGURE 4–9: EnerVista Plug and Play Screens (Example)

For additional information on EnerVista viewpoint, please visit the EnerVista website at

http://www.EnerVista.com.

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Digital Energy

Multilin

369 Motor Management Relay

Chapter 5: Setpoints

Setpoints

5.1 Overview

5.1.1 Setpoints Main Menu

S1 SETPOINTS

369 SETUP

SETPOINT ACCESS

See page 5–111

DISPLAY PREFERENCES See page 5–111

369 COMMUNICATIONS

REAL TIME CLOCK

WAVEFORM CAPTURE

DATA LOGGER

EVENT RECORDS

MESSAGE SCRATCHPAD

DEFAULT MESSAGES

CLEAR/PRESET DATA

MODIFY OPTIONS

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OVERVIEW

CHAPTER 5: SETPOINTS

FACTORY SERVICE

See page 5–121

S2 SETPOINTS

SYSTEM SETUP

CT/VT SETUP

See page 5–122

See page 5–125

MONITORING SETUP

BLOCK FUNCTIONS

OUTPUT RELAY SETUP

CONTROL FUNCTIONS

See page 5–130

See page 5–131

S3 SETPOINTS

OVERLOAD PROTECTION

THERMAL MODEL

OVERLOAD CURVES

OVERLOAD ALARM

See page 5–142

See page 5–144

See page 5–154

S4 SETPOINTS

CURRENT ELEMENTS

SHORT CIRCUIT

MECHANICAL JAM

UNDERCURRENT

CURRENT UNBALANCE

GROUND FAULT

S5 SETPOINTS

MOTOR START/INHIBITS

ACCELERATION TRIP

START INHIBIT

See page 5–161

See page 5–162

See page 5–163

BACKSPIN DETECTION

S6 SETPOINTS

RTD TEMPERATURE

LOCAL RTD PROTECTION See page 5–165

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OVERVIEW

REMOTE RTD PROTECTN See page 5–166

OPEN RTD ALARM See page 5–169

SHORT/LOW RTD ALARM See page 5–169

LOSS OF RRTD COMMS

See page 5–170

S7 SETPOINTS

VOLTAGE ELEMENTS

UNDERVOLTAGE

OVERVOLTAGE

PHASE REVERSAL

UNDERFREQUENCY

OVERFREQUENCY

S8 SETPOINTS

POWER ELEMENTS

LEAD POWER FACTOR

LAG POWER FACTOR

POSITIVE REACTIVE

POWER (kvar)

NEGATIVE REACTIVE

POWER (kvar)

UNDERPOWER

REVERSE POWER

S9 SETPOINTS

DIGITAL INPUTS

SPARE SWITCH

EMERGENCY RESTART

DIFFERENTIAL

SPEED SWITCH

REMOTE RESET

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OVERVIEW

CHAPTER 5: SETPOINTS

S10 SETPOINTS

ANALOG OUTPUTS

ANALOG OUTPUT 1

ANALOG OUTPUT 2

ANALOG OUTPUT 3

ANALOG OUTPUT 4

See page 5–190

S11 SETPOINTS

369 TESTING

TEST OUTPUT RELAYS

See page 5–192

TEST ANALOG OUTPUTS See page 5–193

S12 SETPOINTS

SPEED2 O/L CURVES

See page 5–194

TWO-SPEED MOTOR

SPEED2 UNDERCURRENT See page 5–196

SPEED2 ACCELERATION See page 5–197

1.Only shown if option R installed or Channel 3 Application is programmed as RRTD

2.Only shown if option R installed

3.Only shown if Channel 3 Application is programmed as RRTD

4.Only shown if option M or B are installed

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5.2 S1 369 Setup

5.2.1 Setpoint Access

PATH: S1 369 SETUP Ø SETPOINT ACCESS

Range: Read Only, Read & Write

SETPOINT ACCESS

FRONT PANEL ACCESS:

Read & Write

Range: Read Only, Read & Write

Range: 8 alphabetic characters

COMM ACCESS

Read & Write

ENCRYPTED COMM

PASSCODE: AIKFBAIK

There are two levels of access security: “Read Only” and “Read & Write”. The access

terminals (57 and 58) must be shorted to gain read/write access via the front panel. The

FRONT PANEL ACCESS setpoint indicates the access level based on the condition of the

access switch. If set to “Read Only”, setpoints and actual values may be viewed but, not

changed. If set to “Read & Write”, actual values may be viewed and setpoints changed and

stored.

Communication access can be changed with EnerVista 369 Setup via the Setpoint > S1

Setup menu. An access tab is shown only when communicating with the relay. To set a

password, click the Change Password button, then enter and verify the new passcode.

After a passcode is entered, setpoint access changes to “Read Only”. When setpoints are

changed through EnerVista 369 Setup during read-only access, the passcode must be

entered to store the new setpoint. To allow extended write access, click Allow Write

Access and enter the passcode. To return the access level to read-only, click Restrict

Write Access. Access automatically reverts to read-only after 30 minutes of inactivity or if

control power is cycled.

If the access level is Read/Write, write access to setpoints is automatic and a 0 password

need not be entered. If the password is not known, consult the factory service department

with the ENCRYPTED COMM PASSCODE value to be decoded.

5.2.2 Display Preferences

PATH: S1 369 SETUP ØØ DISPLAY PREFERENCES

Range: 5 to 100 s in steps of 1

DISPLAY PREFERENCES

DEFAULT MESSAGE

CYCLE TIME: 20 s

Range: 10 to 900 s in steps of 1

Range: 1 to 10 s in steps of 1

DEFAULT MESSAGE

TIMEOUT: 300 s

FLASH MESSAGE

DURATION: 2s

Range: Celsius, Fahrenheit

TEMPERATURE DISPLAY:

Celsius

Shown if option R installed or RRTD added

Range: Mega, Kilo

ENERGY UNIT DISPLAY:

Mega

Shown only if option M or B installed

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If no keys are pressed for the time defined by the DEFAULT MESSAGE TIMEOUT, the

369 automatically displays a series of default messages. This time can be modified to

ensure messages remain on the screen long enough during programming or reading of

actual values. Each default message remains on the screen for the default message cycle

time.

Flash messages are status, warning, error or information messages displayed for several

seconds in response to certain key presses during setpoint programming. These messages

override any normal messages. The duration of a flash message on the display can be

changed to accommodate different reading rates.

Temperatures may be displayed in either Celsius or Fahrenheit degrees. RTD setpoints are

programmed in Celsius only.

The energy units for watthours and varhours can be viewed in either “Mega” (MWh or

Mvarh) or “Kilo” (kWh or kvarh) units. Both registers accumulate energy regardless of the

preference set. The actual energy is a summation of both the kilo and Mega values.

5.2.3 369 Communications

PATH: S1 369 SETUP ØØØ 369 COMMUNICATIONS

Range: 1 to 254 in steps of 1

369 COMMUNICATIONS

SLAVE ADDRESS:

254

Range: 4800, 9600, 19200

Range: None, Odd, Even

COMPUTER RS232

BAUD RATE: 19200 Baud

COMPUTER RS232

PARITY: None

Range: 1200, 2400, 4800, 9600, 19200

Range: None, Odd, Even

CHANNEL 1 RS485

BAUD RATE: 19200 Baud

CHANNEL 1 RS485

PARITY: None

Range: 1200, 2400, 4800, 9600, 19200

Range: None, Odd, Even

CHANNEL 2: RS485

BAUD RATE: 19200 Baud

CHANNEL 2: RS485

PARITY: None

Range: Modbus, RRTD

CHANNEL 3

APPLICATION: Modbus

Range: RS485, Fiber.

CHANNEL 3

Only shown if option F is installed.

CONNECTION: RS485

Range: 1200, 2400, 4800, 9600, 19200

CHANNEL 3 RS485

BAUD RATE: 19200 Baud

Range: None, Odd, Even

CHANNEL 3 RS485

PARITY: None

Range: 0 to 254 in steps of 1 or RRTD not available

RRTD #1 ADDRESS :

RRTD not available

RRTD #2 ADDRESS :

RRTD not available

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Range: 0 to 254 in steps of 1 or RRTD not available

RRTD #3 ADDRESS :

RRTD not available

RRTD #4 ADDRESS :

RRTD not available

Range: 1 to 126 in steps of 1

PROFIBUS ADDRESS:

125

Only in models with Profibus (Option P or P1)

Range: 0 (use Default Input Data Map) to 110 registers

Only in models with Profibus-DPV1 (option P1)

PROFIBUS CYCLIC IN

DATA: Default Map

Range: Off, Latched, Unlatched

FIELDBUS LOSS OF

COMMUNICATION: Off

Only in models with Profibus, Ethernet &

DeviceNet Option (option P, P1,E & D)

Range: 0.25 s to 10.0 s in steps of 0.25 s

Only in models with Profibus & Ethernet (option

P, P1, & E).

FIELDBUS LOSS OF

COMMS DELAY : 0.25 s

Range: None, Trip, Alarm, Aux 1, Aux 2, or

combinations of these. Only in models with

Profibus & Ethernet (option P, P1, & E).

ASSIGN LOSS OF COMMS

RELAY : Trip

Range: 0 to 255 in steps of 1

IP ADDRESS OCTET 1:

127

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

IP ADDRESS OCTET 2:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

IP ADDRESS OCTET 3:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

IP ADDRESS OCTET 4:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

SUBNET MASK OCTET 1:

255

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

SUBNET MASK OCTET 2:

255

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

SUBNET MASK OCTET 3:

255

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

SUBNET MASK OCTET 4:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

GATEWAY ADD. OCTET 1:

127

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

GATEWAY ADD. OCTET 2:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

GATEWAY ADD. OCTET 3:

Shown only with Modbus/TCP (Option E)

Range: 0 to 255 in steps of 1

GATEWAY ADD. OCTET 4:

Shown only with Modbus/TCP (Option E)

Range: 0 to 63 in steps of 1

DEVICENET MAC ID:

Shown only with DeviceNet (Option D)

Range: 125, 250, 500 kbps

DEVICENET BAUD RATE:

125 kbps

Shown only with DeviceNet (Option D)

Range: Group 1, Group 2, User-Defined

Shown only with DeviceNet (Option D)

DEVICENET INPUT POLL

DATA: User-Defined

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Range: 1 to 110 Registers

USER-DEFINED DATA

SIZE: 110 Registers

Shown only if DeviceNet Input Poll Data is

programmed as User-Defined

Range: No, Yes

RESET FIELDBUS COMMS

INTERFACE: No

Only in models with Profibus (Option P or P1),

DeviceNet (Option D), or Modbus/TCP (E)

1.RRTD units must be connected in order from RRTD #1 ADDRESS to RRTD #4 ADDRESS. If only one RRTD is used, it's slave address must

be programmed under RRTD #1 ADDRESS. The next RRTD to be connected would be set up under RRTD #2 ADDRESS, and so forth.

2.Only shown if "FIELDBUS LOSS OF COMMUNICATION" setting is not 'Off'

The 369 is equipped with four independent serial ports. The RS232 port is for local use and

responds regardless of the programmed slave address; the rear RS485 communication

ports are addressed. If an RRTD module is used in conjunction with the 369, channel 3 must

be used for communication between the two devices and the CHANNEL 3

APPLICATION setpoint must be set to “RRTD” (note that the corresponding RRTD setting

must be set to “Modbus”). A fiber optic port (option F) may be ordered for channel 3. If the

channel 3 fiber optic port is used, the channel 3 RS485 connection is disabled.

The RS232 port may be connected to a personal computer running EnerVista 369 Setup.

This may be used for downloading and uploading setpoints files, viewing actual values,

and upgrading the 369 firmware. See Section 4.2: EnerVista 369 Setup Interface on page –

60 for details on using EnerVista 369 Setup.

The RS485 ports support a subset of the Modbus RTU protocol. Each port must have a

unique address between 1 and 254. Address 0 is the broadcast address listened to by all

relays. Addresses need not be sequential; however, no two devices can have the same

address. Generally, each addition to the link uses the next higher address, starting at 1. A

maximum of 32 devices can be daisy-chained and connected to a DCS, PLC, or PC using

the RS485 ports. A repeater may be used to allow more than 32 relays on a single link.

Either Profibus-DP or Profibus-DPV1 communications are supported with the optional

Profibus protocol interface (option P or P1). The bus address of the Profibus-DP/V1 node is

set with the PROFIBUS ADDRESS setpoint, with an address range from 1 to 126. Address

126 is used only for commissioning purposes and should not be used to exchange user

data.

The RESET FIELDBUS COMMS INTERFACE setpoint command resets the Fieldbus

module. This allows the Fieldbus module to be reset if the Fieldbus module stops

communicating with the Fieldbus master, without having to shut down the motor and

cycle power to the relay.

The Modbus/TCP protocol is also supported with the optional Modbus/TCP protocol

interface (option E). For more information, refer to the 369 Communications Guide.

Note

After changing or setting the IP address of the relay, please RESET FIELDBUS COMMS

INTERFACE or cycle the power supply of the 369 in order to make the new IP address

active.

The DeviceNet protocol is supported with the optional DeviceNet communication interface

(option D), and is certified as ODVA DeviceNet CONFORMANCE TESTED™. The DEVICENET

MAC ID sets the MAC ID with a range from 0 to 63. The DEVICENET BAUD RATE selects

a baud rate of 125, 250, or 500 kbps. DeviceNet communications must be stopped before

changing DeviceNet setpoints. There will be a delay of 5 to 6 seconds for the new

DeviceNet settings to take effect.

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Note

Previous to FW v3.30 release, the FIELDBUS LOSS OF COMMUNICATION feature was

used in the 369 with Profibus Comm. option (P/P1) only and was referred to as “PROFIBUS

LOSS OF COMMUNICATION”. In FW v3.30 and V3.31 revisions, the FIELDBUS LOSS OF

COMMUNICATION feature is available for Profibus and Ethernet comm. options.

In FW v3.40 and later revisions, FIELDBUS LOSS OF COMMUNICATION feature is

available for Profibus, Ethernet and DeviceNet comm. options.

5.2.4 Real Time Clock

PATH: S1 369 SETUP ØØØØ REAL TIME CLOCK

Range: 1 to 12 in steps of 1

REAL TIME CLOCK

SET MONTH [1...12]:

Range: 1 to 31 in steps of 1

SET DAY [1...31]:

Range: 1998 to 2097 in steps of 1

SET

YEAR[1998...2097]:

Range: 0 to 23 in steps of 1

Range: 0 to 59 in steps of 1

SET HOUR [0...23]:

SET MINUTE [0...59]:

SET SECOND [0...59]:

The time/date stamp is used to track events for diagnostic purposes. The date and time

are preset but may be changed manually. A battery backed internal clock runs

continuously even when power is off. It has the same accuracy as an electronic watch

approximately ±1 minute per month. It may be periodically corrected either manually

through the keypad or via the clock update command over the serial link using EnerVista

369 Setup.

Enter the current date using two digits for the month and day, and four digits for the year.

For example, enter February 28, 2007 as “02 28 2007". If entered from the keypad, the new

date takes effect the moment [ENTER] is pressed. Set the time by using two digits for the

hour (in 24 hour time), minutes, and seconds. If entered from the keypad, the new time

takes effect the moment the [ENTER] key is pressed.

If the serial communication link is used, then all the relays can keep time in synchronization

with each other. A new clock time is pre-loaded into the memory map via the

communications port by a remote computer to each relay connected on the

communications channel. The computer broadcasts (address 0) a “set clock” command to

all relays. Then all relays in the system begin timing at the exact same instant. There can

be up to 100 ms of delay in receiving serial commands so the clock time in each relay is

±100 ms, ± the absolute clock accuracy, in the PLC or PC (see 369 Communications Guide

for information on programming the time and synchronizing commands.)

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5.2.5 Waveform Capture

PATH: S1 369 SETUP ØØØØØ WAVEFORM CAPTURE

Range: 0 to 100% in steps of 1

WAVEFORM CAPTURE

TRIGGER POSITION:

50 %

Waveform capture records contain waveforms captured at the sampling rate as well as

contextual information at the point of trigger. These records are triggered by trip functions,

digital input set to capture or via the EnerVista 369 Setup software. Multiple waveforms are

captured simultaneously for each record: Ia, Ib, Ic, Ig, Va, Vb, and Vc.

The trigger position is programmable as a percent of the total buffer size (e.g. 10%, 50%,

etc.). The trigger position determines the number of pre- and post-fault cycles to divide the

record. The relay sampling rate is 16 samples per cycle.

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5.2.6 Data Logger

PATH: SETTINGS Ø S1 369 SETUP ØØØØ

Range: Select Command, Start, Stop

Default: Select Command

DATA LOGGER

START/STOP DATA LOG:

Select Command

Range: 1 to 3600 seconds in steps of 1 s.

Default: 3600 sec

LOG INTERVAL:

3600 seconds

Range: Run To Fill, Circulate

Default: Run To Fill

RECORDING TYPE:

Run To Fill

Range: See format below

Default: None

CHANNEL 1:

None

Range: See format below

Default: None

CHANNEL 2:

None

Range: See format below

Default: None

CHANNEL 3:

None

Range: See format below

Default: None

CHANNEL 4:

None

Range: See format below

Default: None

CHANNEL 5:

None

Range: See format below

Default: None

CHANNEL 6:

None

Range: See format below

Default: None

CHANNEL 7:

None

Range: See format below

Default: None

CHANNEL 8:

None

Range: See format below

Default: None

CHANNEL 9:

None

Range: See format below

Default: None

CHANNEL 10:

None

Range: See format below

Default: None

CHANNEL 11:

None

Range: See format below

Default: None

CHANNEL 12:

None

Range: See format below

Default: None

CHANNEL 13:

None

Range: See format below

Default: None

CHANNEL 14:

None

Range: See format below

Default: None

CHANNEL 15:

None

Range: See format below

Default: None

CHANNEL 16:

None

START/STOP DATA LOG: It is possible to manually start or stop the data logger from the

369 front panel using this setpoint, or by writing to its associated Modbus address

(0x1E20). The value, once stored, will be acted upon and the displayed text will revert back

to “Select Command”. A new Log is started either using this command setpoint (manual), or

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CHAPTER 5: SETPOINTS

by a Motor Start (automatic). A Log will be stopped either using this command setpoint or

by a Motor Stop. If, however, the Log was started by command it will not be stopped by a

Motor Stop, only by a stop command.

LOG INTERVAL: This is the interval at which the data log will store entries. When the Data

Logger is started the first record will be immediately recorded. The following records will be

stored in increments of the interval time value.

RECORDING TYPE: If “Run To Fill” is selected, the Data Logger will stop logging records

once the Data Logger data memory area has been filled. If “Circulate” is selected, the Data

Logger will continue to log records until stopped, and will overwrite the oldest data stored

in the Data Log memory area once 100% has been utilized. In such a case, the Log will act

as a rolling window of data in time, going back as far as the maximum number of records

that will fit into the total Data Log memory.

CHANNEL x: There are up to 16 channels available to capture any of 101 different data

parameters available in the 369 relay with each Record. These parameters are described in

Modbus format code F189. (Refer to Format Code table in the 369 Communications Guide).

Please refer to Data Logger section in the 369 Communications Guide for more information

on the Data Logger feature.

5.2.7 Event Records

PATH: S1 369 SETUP ØØØØØØ EVENT RECORDS

Range: On, Off

EVENT RECORDS

MOTOR STARTING

EVENTS: Off

MOTOR RUNNING

EVENTS: Off

MOTOR STOPPED

EVENTS: Off

See 6.6.1 Event Records on page 6–219 for details on viewing the event recorder.

5.2.8 Message Scratchpad

PATH: S1 369 SETUP ØØØØØØØ MESSAGE SCRATCHPAD

Range: 2 x 20 alphanumeric characters

MESSAGE SCRATCHPAD

Text 1

Text 2

Text 3

Text 4

Text 5

Range: 2 x 20 alphanumeric characters

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Five 40-character message screens can be programmed. These messages may be notes

that pertain to the 369 installation. This can be useful for reminding operators of certain

tasks.

5.2.9 Default Messages

PATH: S1 369 SETUP ØØØØØØØØ DEFAULT MESSAGES

Range: Yes, No

DEFAULT MESSAGES

DEFAULT TO CURRENT

METERING: No

DEFAULT TO MOTOR

LOAD: No

DEFAULT TO DELTA

Only shown if option M installed

VOLTAGE METERING: No

Range: Yes, No

Only shown if option M installed

DEFAULT TO POWER

FACTOR: No

Range: Yes, No

Only shown if option M installed

DEFAULT TO POSITIVE

WATTHOURS: No

Range: Yes, No

Only shown if option M installed

DEFAULT TO REAL

POWER: No

Range: Yes, No

Only shown if option M installed

DEFAULT TO REACTIVE

POWER: No

Range: Yes, No. Only shown if option R is installed.

Indicates stator no. local to 369 only.

DEFAULT TO HOTTEST

STATOR RTD: No

Range: Yes, No

DEFAULT TO TEXT

MESSAGE 1: No

DEFAULT TO TEXT

MESSAGE 2: No

DEFAULT TO TEXT

MESSAGE 3: No

DEFAULT TO TEXT

MESSAGE 4: No

DEFAULT TO TEXT

MESSAGE 5: No

Range: Yes, No

Only shown if option R is installed

DEFAULT TO HOTTEST

STATOR RTD TEMP: No

Range: Yes, No. Shown only if unbalance biasing is

enabled in the Thermal Model.

DEFAULT TO UNBALANCE

BIASED MTR LOAD: No

The 369 displays a series of default messages. These default messages appear after the

value for the DEFAULT MESSAGE CYCLE TIME expires and there are no active trips,

alarms or start inhibits. See Section 5.2.2: Display Preferences on page –111 for details on

setting time delays and message durations. The default messages can be selected from

the list above including the five user definable messages from the message scratchpad.

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5.2.10 Clear/Preset Data

PATH: S1 369 SETUP ØØØØØØØØØ CLEAR/PRESET DATA

Range: No, Yes

CLEAR/PRESET DATA

CLEAR ALL DATA:

CLEAR LAST TRIP

DATA: No

CLEAR TRIP

COUNTERS: No

CLEAR EVENT

RECORD: No

Clears all 512 events

Range: No, Yes

CLEAR RTD

MAXIMUMS: No

CLEAR PEAK DEMAND

DATA: No

Range: No, Yes. Clears learned motor data, last

starting current, last starting thermal capacity, last

acceleration time, motor statistics, motor start data

logger, and data logger

CLEAR MOTOR

DATA: No

Range: No, Yes

Only shown if option M or B are installed.

CLEAR ENERGY DATA:

Range: 0 to 65535 MWh in steps of 1

Can be preset or cleared by storing 0

Only shown if option M or B are installed.

PRESET MWh:

Range: 0 to 65535 Mvarh in steps of 1

Can be preset or cleared by storing 0

Only shown if option M or B are installed

PRESET POSITIVE

Mvarh: 0

Range: 0 to 65535 Mvarh in steps of 1

Can be preset or cleared by storing 0

Only shown if option M or B are installed

PRESET NEGATIVE

Mvarh: 0

Range: 0 to 65535 in steps of 1

PRESET DIGITAL

COUNTER: 0

Can be preset or cleared by storing 0

Range: 0 to 50000 in steps of 1

Range: 0 to 65535 in steps of 1

Range: 0 to 50000 in steps of 1

PRESET NUMBER OF

MOTOR STARTS: 0

PRESET NUM OF EMERG.

RESTARTS: 0

PRESET NUM OF MOTOR

RUNNING HOURS: 0

PRESET NUM OF AUTO-

RESTRT ATMPTS: 0

These commands may be used to clear various historical data. This is useful on new

installations or to preset information on existing installations where new equipment has

been installed. The PRESET DIGITAL COUNTER setpoint appears only if one of the

digital inputs has been configured as a digital input counter.

Presetting the energy data is only available for “Mega” units. When these are preset, the

corresponding “Kilo” data will be preset to zero.

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5.2.11 Modify Options

PATH: S1 369 SETUP ØØØØØØØØØØ MODIFY OPTIONS

Range: No, Yes

MODIFY OPTIONS

ENABLE LOCAL RTD?

Yes

Range: No, Metering, Backspin

Range: No, Yes

METERING/BACKSPIN:

Metering

ENABLE FIBER OPTIC?

Range: No, Yes

ENABLE ETHERNET?

Range: No, Yes

ENABLE PROFIBUS-DP?

Range: No, Yes

ENABLE PROFIBUS-

DPV1?

Range: No, Yes

ENABLE DEVICENET?

ENABLE HARSH ENV.?

Range: Press the [ENTER] key to begin text editing

Range: No, Yes

ENTER PASSCODE:

MODIFY OPTIONS?

This page allows the user to modify relay options directly from the front keypad.

5.2.12 Factory Service

PATH: S1 369 SETUP ØØØØØØØØØØØ FACTORY SERVICE

Range: 0 to 65535

FACTORY SERVICE

PASSCODE: 0

This page is for use by GE Multilin personnel for testing and calibration purposes

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5.3 S2 System Setup

5.3.1 Description

The system setup setpoints are critical to the operation of the 369 protective and metering

features and elements. Most protective elements are based on the information input for

the CT/VT Setup and Output Relay Setup. Additional monitoring alarms and control

functions of the relay are also set here.

5.3.2 CT/VT Setup

PATH: S2 SYSTEM SETUP Ø CT/VT SETUP

Range: 1 to 5000 in steps of 1

CT/VT SETUP

PHASE CT PRIMARY:

500

Range: 1 to 5000 in steps of 1

MOTOR FLA:

Range: None, 5A secondary, 1A secondary, 50:0.025

GROUND CT TYPE:

Range: 1 to 5000 in steps of 1

GROUND CT PRIMARY:

100

Only shown for 5A and 1A secondary CT

Range: Yes, No

ENABLE 2-SPEED MOTOR

PROTECTION: No

Range: 1 to 5000 A in steps of 1

SPEED2 PHASE CT:

PRIMARY :500 A

SPEED2 MOTOR FLA :

10 A

Range: None, Open Delta, Wye

VT CONNECTION TYPE:

None

Only shown if option M or B installed

Range: 1.00:1 to 240.00:1

VT RATIO:

35:1

Not shown if VT Connection Type set to None

Range: 100 to 20000 in steps of 1

MOTOR RATED VOLTAGE:

4160

Not shown if VT Connection Type set to None

Range: 50 Hz, 60 Hz, Variable

Range: ABC, ACB

NOMINAL FREQUENCY:

60 Hz

SYSTEM PHASE

SEQUENCE: ABC

Range: ABC, ACB

SPEED2 SYSTEM PHASE

SEQUENCE : ABC

1.Only shown when “ENABLE 2-SPEED MOTOR PROTECTION” is set to “Yes”

•

PHASE CT PRIMARY: Enter the phase CT primary here. The phase CT secondary (1 A or

5A) is determined by terminal connection to the 369. The phase CT should be chosen

such that the motor FLA is between 50% and 100% of the phase CT primary. Ideally

the motor FLA should be as close to 100% of phase CT primary as possible, never

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more. The phase CT class or type should also be chosen such that the CT can handle

the maximum potential fault current with the attached burden without having its

output saturate. Information on how to determine this if required is available in

Section 7.4: CT Specification and Selection on page –230.

•

MOTOR FLA: The motor FLA (full load amps or full load current) must be entered. This

value may be taken from the motor nameplate or motor data sheets.

GROUND CT TYPE and GROUND CT PRIMARY: The GROUND CT TYPE and GROUND

CT PRIMARY (if 5 A or 1 A secondary) must be entered here. For high resistance

grounded systems, sensitive ground detection is possible with the 50:0.025 CT. On

solidly or low resistance grounded systems where fault current can be quite high, a

1 A or 5 A CT should be used for either zero-sequence (core balance) or residual

ground sensing. If a residual connection is used with the phase CTs, the phase CT

primary must also be entered for the ground CT primary. As with the phase CTs the

type of ground CT should be chosen to handle all potential fault levels without

saturating.

•

ENABLE 2-SPEED MOTOR: If set to Yes, the following new settings are shown:

1. S2 SYSTEM SETUP/ CT/VT SETUP:

SPEED2 PHASE CT

SPEED2 MOTOR FLA

SPEED2 PHASE SEQUENCE

2. S12 TWO SPEED MOTOR:

SPEED2 O/L CURVES

SPEED2 UNDERCURRENT

SPEED2 ACCELERATION

3. S9 DIGITAL INPUTS/ SPEED SWITCH displays the message TWO SPEED

MONITOR. The Speed Switch option is added to setting range for:

S9 DIGITAL INPUTS/ EMERGENCY RESTART

S9 DIGITAL INPUTS/DIFFERENTIAL SWITCH

S9 DIGITAL INPUTS/REMOTE RESET.

•

SPEED2 PHASE CT: This setting specifies the CT primary of the CT used under Speed 2.

When in Speed 1, the existing CT primary found under S2 SYSTEM SETUP/ CT/VT

SETUP/PHASE CT PRIMARY is in effect.

SPEED2 MOTOR FLA: This setting specifies the FLA of the motor running at Speed 2.

When in Speed 1, the existing FLA found under S2 SYSTEM SETUP/ CT/VT SETUP/

MOTOR FLA is in effect.

VT CONNECTION TYPE, VT RATIO, and MOTOR RATED VOLTAGE: These voltage

related setpoints are visible only if the 369 has metering installed.

The manner in which the voltage transformers are connected must be entered here or

none if VTs are not used. The VT turns ratio must be chosen such that the secondary

voltage of the VTs is between 1 and 240 V when the primary is at motor nameplate

voltage. All voltage protection features are programmed as a percent of motor

nameplate or rated voltage which represents the rated motor design voltage line to

line.

For example: If the motor nameplate voltage is 4160 V and the VTs are 4160/120

open-delta, program VT CONNECTION TYPE to “Open Delta”, VT RATIO to “34.67:1”,

and MOTOR RATED VOLTAGE to “4160 V”.

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•

NOMINAL FREQUENCY: Enter the nominal system frequency here.

The 369 has variable frequency functionality when the NOMINAL FREQUENCY is

set to “Variable”. All of the elements function in the same manner with the exception of

the voltage and power elements, which work properly if the voltage waveform is

approximately sinusoidal. When using a pulse width modulate drive, and an unfiltered

voltage waveform is present, the unit will not be able to accurately measure voltage,

but an approximately sinusoidal current waveform can be measured accurately. If the

NOMINAL FREQUENCY is set to “Variable”, the filtering algorithm could increase the

trip and alarm times for the undervoltage and underfrequency elements by up to 270

ms. If the level exceeds the threshold by a significant amount, trip and alarm times will

decrease until they match the programmed delay. The exceptions to this increased

time are the short circuit and ground fault elements, which will trip as per

specification.

Note that when the NOMINAL FREQUENCY setting is “Variable”, the element pickup

levels and timing are based on the measured values of the 369.

Frequency is normally determined from the Va voltage input. If however this voltage

drops below the minimum voltage threshold the Ia current input will be used.

•

SYSTEM PHASE SEQUENCE: If the phase sequence for a given system is ACB rather

than the standard ABC the phase sequence may be changed. This setpoint allows the

369 to properly calculate phase reversal and power quantities.

Note

In motor Forward/Reverse applications, for proper power metering and phase reversal trip

protection, the system phase sequence must be set the same as the phase sequence for

the forward rotation of the motor.

•

SPEED2 PHASE SEQUENCE: This setting specifies the phase rotation when running in

Speed 2. When in Speed 1, the phase rotation set under S2 SYSTEM SETUP/ CT/VT

SETUP/SYSTEM PHASE SEQUENCE is in effect.

The FLA rating defines the nominal loading of the motor, and differs depending on

motor speed. If ENABLE 2-SPEED MOTOR is set to “Yes”, and Speed Switch (TWO

SPEED MONITOR) digital input is detected “closed”, the relay automatically applies

the SPEED2 CT PRIMARY and SPEED2 FLA settings to all motor features that

previously were configured to utilize the Speed 1 settings: Thermal Model

OVERLOAD PICKUP LEVEL, OVERLOAD ALARM, SHORT CIRCUIT,

MECHANICAL JAM, CURRENT UNBALANCE, and SPEED2 UNDERCURRENT.

The 369 relay uses one Thermal Model for both speeds, and keeps the accumulated

thermal capacity during speed switching. Upon detection of Speed 2, the phase

sequence setting under SYSTEM SETUP/CT/VT SETUP/SPEED2 SYSTEM PHASE

SEQUENCE is used for power metering calculations.

For 2-speed motors rotating in the same direction (typically low/high-speed

applications) when in Speed 1 and Speed 2, the settings under SYSTEM SETUP/CT/

VT SETUP/SYSTEM PHASE SEQUENCE and under SYSTEM SETUP/CT/VT

SETUP/SPEED2 PHASE SEQUENCE are set the same.

For 2-speed motors changing the rotating direction (motor Forward/Reverse

applications), the setting ABC (ACB) under SYSTEM SETUP/CT/VT SETUP/SPEED2

PHASE SEQUENCE is set to be different than the setting ACB (ACB) under SYSTEM

SETUP/CT/VT SETUP/SYSTEM PHASE SEQUENCE. For these applications, the

motor is rotating with the same speed, but is designed and controlled to rotate in both

Forward and Reverse directions.

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5.3.3 Monitoring Setup

Main Menu

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP

MONITORING SETUP

TRIP COUNTER

See below.

STARTER FAILURE

LEARNED DATA

See page 5–126

See page 5–127

See page 5–129

CURRENT DEMAND

kW DEMAND

kvar DEMAND

kVA DEMAND

SELF TEST MODE

1.Only shown if option M or B are installed

Trip Counter

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP Ø TRIP COUNTER

Range: Off, Latched, Unlatched

TRIP COUNTER

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM

RELAYS: Alarm

Range: 1 to 50000 in steps of 1

ALARM PICKUP LEVEL:

25 Trips

Range: On, Off

TRIP COUNTER ALARM

EVENTS: Off

When the Trip Counter is enabled and the alarm pickup level is reached, an alarm will

occur. To reset the alarm the trip counter must be cleared (see Section 5.2.10: Clear/Preset

Data on page –120 for details) or the pickup level increased and the reset key pressed (if a

latched alarm).

The trip counter alarm can be used to monitor and alarm when a predefined number of

trips occur. This would then prompt the operator or supervisor to investigate the causes of

the trips that have occurred. Details of individual trip counters can be found in the Motor

Statistics section of Actual Values page 4 (see Section 6.5.2: Motor Statistics on page –217).

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Starter Failure

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP ØØ STARTER FAILURE

Range: Off, Latched, Unlatched

Range: Breaker, Contactor

STARTER FAILURE

ALARM: Off

STARTER TYPE:

Breaker

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM RELAYS:

Alarm

Range: 10 to 1000 ms in steps of 10

STARTER FAILURE

DELAY: 100 ms

Range: On, Off

STARTER FAILURE

ALARM EVENTS: Off

If the Starter Failure alarm feature is enabled, any time the 369 initiates a trip, the 369 will

monitor the Starter Status input (if assigned to “Spare Switch” in S9 DIGITAL INPUTS) and

the motor current. If the starter status contacts do not change state or motor current does

not drop to zero after the programmed time delay, an alarm will occur. The time delay

should be slightly longer than the breaker or contactor operating time. In the event that an

alarm does occur, and Breaker was chosen as the starter type, the alarm will be Breaker

Failure. If on the other hand, Contactor was chosen for starter type, the alarm will be

Welded Contactor.

Learned Data

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP ØØØ CURRENT DEMAND

Range: 1 to 5 in steps of 1

LEARNED DATA

NUMBER OF STARTS TO

AVERAGE: 5

The "Number of Starts to Average" determines how many starts occur before an "average"

record-set of data is stored to E²PROM.

The "Access Learned Data Record Number" Modbus address is used to determine what

data populates the Actual Values display and Modbus addresses from 0x03C0 to 0x03C4,

and 0x03C8 to 0x03CA. If the value in this Setpoint is zero, the data reflects the most

recent motor start. If the value is anything else, one of the 250 averaged records populates

these Actual Values.

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Demand

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP ØØØ CURRENT DEMAND

Range: 5 to 90 min in steps of 1

Range: Off, Latched, Unlatched

CURRENT DEMAND

PERIOD: 15 min

CURRENT DEMAND

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM RELAYS:

Alarm

Range: 0 to 65000 A in steps of 1

CURRENT DEMAND ALARM

LIMIT: 100 A

Range: On, Off

CURRENT DEMAND ALARM

EVENTS: Off

Range: 5 to 90 min in steps of 1

Range: Off, Latched, Unlatched

kW DEMAND

PERIOD: 15 min

kW DEMAND

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM RELAYS:

Alarm

Range: 1 to 50000 kW in steps of 1

kW DEMAND ALARM

LIMIT: 100 kW

Range: On, Off

kW DEMAND ALARM

EVENTS: Off

Range: 5 to 90 min. in steps of 1

Range: Off, Latched, Unlatched

kvar DEMAND

PERIOD: 15 min

kvar DEMAND

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM RELAYS:

Alarm

Range: 1 to 50000 kvar in steps of 1

kvar DEMAND ALARM

LIMIT: 100 kvar

Range: On, Off

kvar DEMAND ALARM

EVENTS: Off

Range: 5 to 90 min in steps of 1

Range: Off, Latched, Unlatched

kVA DEMAND

PERIOD: 15 min

kVA DEMAND

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN ALARM RELAYS:

Alarm

Range: 1 to 50000 kVA in steps of 1

kVA DEMAND ALARM

LIMIT: 100 kVA

Range: On, Off

kVA DEMAND ALARM

EVENTS: Off

1.Only shown if option M or B are installed

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The 369 can measure the demand of the motor for several parameters (current, kW, kvar,

kVA). The demand values may be of interest for energy management programs where

processes may be altered or scheduled to reduce overall demand on a feeder. An alarm

will occur if the limit of any of the enabled demand elements is reached.

Demand is calculated in the following manner. Every minute, an average magnitude is

calculated for current, +kW, +kvar, and kVA based on samples taken every 5 seconds.

These values are stored in a FIFO (First In, First Out buffer). The size of the buffer is

determined by the period selected for the setpoint. The average value of the buffer

contents is calculated and stored as the new demand value every minute. Demand for real

and reactive power is only positive quantities (+kW and +kvar).

---

DEMAND =

Average(n)

(EQ 0.1)

∑

N_{n = 1}

where: N = programmed demand period in minutes and n = time in minutes.

FIGURE 5–1: Rolling demand (15 minute window)

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Self-Test Relay Assignment

PATH: S2 SYSTEM SETUP ØØ MONITORING SETUP ØØØØØØØ SELF TEST MODE

Range: None, Alarm, Aux1, Aux2, or combinations of

these

SELF TEST MODE

ASSIGN SERVICE

RELAY:

The 369 performs self-diagnostics of the circuitry. The relay programmed as the Self-Test

relay activates upon a failure of any self-diagnostic tests.

5.3.4 Block Functions

PATH: S2 SYSTEM SETUP ØØØ BLOCK FUNCTIONS

Range: Enabled, Disabled

BLOCK FUNCTIONS

LOG BLOCKING EVENTS:

Disabled

Block Undercurrent and Underpower

Range: Blocked, Not Blocked

BLOCK UC/UPWR (37)

Not Blocked

Block Current Unbalance

Range: Blocked, Not Blocked

BLOCK CURR UNBAL

(46)

Block Incomplete Sequence

Range: Blocked, Not Blocked

BLOCK INC SEQ (48)

Not Blocked

Block Thermal Model

Range: Blocked, Not Blocked

BLOCK THERM MOD (49)

Not Blocked

Block Short Circuit and Backup

Range: Blocked, Not Blocked

BLOCK SHORT CCT (50)

Not Blocked

Block Overload Alarm

Range: Blocked, Not Blocked

BLOCK O/L ALARM (51)

Not Blocked

Block Ground Fault

Range: Blocked, Not Blocked

BLOCK GND FLT (51G)

Not Blocked

Block Starts Per Hour and Time Between Starts

Range: Blocked, Not Blocked

BLOCK STARTS/HR (66)

Not Blocked

The block functions feature allows the user to block any of the protection functions

through the following methods:

1. Modbus command 20.

2. Profibus-DPV1 acyclical communication (refer to Chapter 9 for additional details).

3. Modbus setpoints.

4. The front panel interface.

The protection functions that can be blocked are indicated by ANSI/IEEE device number in

the table below.

DEVICE

DESCRIPTION

Undercurrent/underpower

Current unbalance

Incomplete sequence

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DEVICE

DESCRIPTION

Thermal model

Short circuit and backup

Overload alarm

51G

Ground fault

Starts per hour / time between starts

Blocking a protection function is essentially the same as disabling it. If the protection

function is blocked and a situation occurs where it would have been activated (if enabled),

no indication will be given and no events are recorded. If the protection function has picked

up and/or is timing out, the internal timers will be reset to zero.

If the LOG BLOCKING EVENTS setpoint is enabled, an event will be stored indicating

when a function changes from being blocked to unblocked, or vice versa.

5.3.5 Output Relay Setup

PATH: S2 SYSTEM SETUP ØØØØ OUTPUT RELAY SETUP

Range: All Resets, Remote Only, Local Only

OUTPUT RELAY SETUP

TRIP RELAY RESET

MODE: All Resets

Range: FS (=failsafe), NFS (=non-failsafe)

TRIP RELAY

OPERATION: FS

Range: None, Starters Status Input

TRIP RELAY

SEAL-IN: None

Only seen if setpoint SPARE SW FUNCTION is

"Starter Status"

Range: All Resets, Remote Only, Local Only

AUX1 RELAY RESET

MODE: All Resets

Range: FS (=failsafe), NFS (=non-failsafe)

Range: All Resets, Remote Only, Local Only

Range: FS (=failsafe), NFS (=non-failsafe)

Range: All Resets, Remote Only, Local Only

Range: FS (failsafe), NFS (=non-failsafe)

AUX1 RELAY

OPERATION: NFS

AUX2 RELAY RESET

MODE: All Resets

AUX2 RELAY

OPERATION: NFS

ALARM RELAY RESET

MODE: All Resets

ALARM RELAY

OPERATION: NFS

A latched relay (caused by a protective elements alarm or trip) may be reset at any time,

providing that the condition that caused the relay operation is no longer present.

Unlatched elements will automatically reset when the condition that caused them has

cleared. Reset location is defined in the following table.

RESET MODE

All Resets

RESET PERFORMED VIA

keypad, digital input, communications

digital input, communications

keypad

Remote Only

Local Only

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The TRIP OPERATION, AUX1 OPERATION, AUX2 OPERATION, and ALARM

OPERATION setpoints allow the choice of relay output operation to fail-safe or non-

failsafe. Relay latchcode however, is defined individually for each protective element.

Failsafe operation causes the output relay to be energized in its normal state and de-

energized when activated by a protection element. A failsafe relay will also change state (if

not already activated by a protection element) when control power is removed from the

369. Conversely a non-failsafe relay is de-energized in its normal non-activated state and

will not change state when control power is removed from the 369 (if not already activated

by a protection element).

The choice of failsafe or non-failsafe operation is usually determined by the motor’s

application. In situations where the process is more critical than the motor, non-failsafe

operation is typically programmed. In situations where the motor is more critical than the

process, failsafe operation is programmed.

TRIP RELAY SEAL-IN: If the setpoint is set to “Starter Status”, the trip contact will remain

at the trip state (The fail-safe NO contact opens; the non-fail-safe NO contact closes)

unless the starter status is open and the trip initiating condition has reset, or the 369 is

manually reset. The feature can protect damage to trip relay contact in a breaker failure

condition. The starter status is derived from the digital input SPARE SWITCH, and the

setpoint SPARE SW FUNCTION in S9 DIGITAL INPUTS must be set to “Starter Status”

before enabling the feature.

Note

Emergency Restart will ALWAYS reset the 369 regardless of the reset mode setting.

Note

Latched trips and alarms are not retained after control power is removed from the 369.

5.3.6 Control Functions

Main Menu

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS

CONTROL FUNCTIONS

SERIAL COMMUNICATION See below.

CONTROL

REDUCED VOLTAGE

See page 5–132

See page 5–134

See page 5–137

AUTORESTART

UNDERVOLTAGE

AUTORESTART

FORCE OUTPUT RELAYS

See page 5–139

1.Only shown if option M or B are installed.

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Serial Communication Control

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS Ø SERIAL

COMMUNICATION CONTROL

Range: On, Off

SERIAL COMMUNICATION

CONTROL

SERIAL COM CONTROL

CONTROL - Off

Range: None, Alarm, Aux1, Aux2 or combinations of

them

ASSIGN START

CONTROL RELAYS: Aux1

If enabled, the motor can be remotely started and stopped via Modbus® communications.

Refer to the Modbus Protocol Reference Guide (available from the Modbus website at http:/

/www.modbus.org) for details on sending commands (Function Code 5). When a Stop

command is sent the Trip relay will activate for 1 second to complete the trip coil circuit for

a breaker application or break the coil circuit for a contactor application. When a Start

command is issued the relay assigned for starting control will activate for 1 second to

complete the close coil circuit for a breaker application or complete the coil circuit for a

contactor application.

The Serial Communication Control functions can also be used to reset the relay and

activate a waveform capture. Refer to the Modbus Protocol Reference Guide (available

from the Modbus website at http://www.modbus.org) for more information.

Reduced Voltage Start Timer

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS ØØ REDUCED VOLTAGE

Range: On, Off

REDUCED VOLTAGE

CONTROL: Off

Range: None, Alarm, Aux1, Aux2, Alarm & Aux1, Alarm

& Aux2, Aux1 & Aux2, Alarm & Aux1 & Aux2

ASSIGN START CONTROL

RELAYS: None

Range: 1.0 to 10.0 s in steps of 0.5

START CONTROL RELAY

TIMER: 1.0 s

Range: Current Only, Current or Timer, Current and

Timer

TRANSITION ON:

Current Only

Range: 25 to 300% FLA in steps of 1

REDUCED VOLTAGE

START LEVEL: 100%FLA

Range: 1 to 500 s in steps of 1

REDUCED VOLTAGE

START TIMER: 200 s

Range: None, Trip, Aux1, Aux2, Trip & Aux1, Trip &

Aux2, Aux1 & Aux2, Trip & Aux1&Aux2

ASSIGN TRIP RELAYS:

Trip

The 369 is capable of controlling the transition of a reduced voltage starter from reduced

to full voltage. That transition may be based on “Current Only”, “Current and Timer”, or “Current or

Timer” (whichever comes first). When the 369 measures the transition of no motor current

to some value of motor current, a 'Start' is assumed to be occurring (typically current will

rise quickly to a value in excess of FLA, e.g. 3 x FLA). At this point, the REDUCED

VOLTAGE START TIMER will be initialized with the programmed value in seconds.

•

If "Current Only" is selected, when the motor current falls below the programmed

Transition Level, transition will be initiated by activating the assigned output relay for

the time programmed in the START CONTROL RELAY TIMER setpoint. If the timer

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expires before that transition is initiated, an Incomplete Sequence Trip will occur

activating the assigned trip relay(s).

•

If "Current or Timer" is selected, when the motor current falls below the programmed

Transition Level, transition will be initiated by activating the assigned output relay for

the time programmed in the START CONTROL RELAY TIMER setpoint. If the timer

expires before that transition is initiated, the transition will be initiated regardless.

If “Current and Timer” is selected, when the motor current falls below the programmed

Transition Level and the timer expires, transition will be initiated by activating the

assigned output relay for the time programmed in the START CONTROL RELAY

TIMER setpoint. If the timer expires before current falls below the Transition Level, an

Incomplete Sequence Trip will occur activating the assigned trip relay(s).

FIGURE 5–2: Reduced Voltage Start Contactor Control Circuit

FIGURE 5–3: Reduced Voltage Starting Current Characteristic

Note

If this feature is used, the Starter Status Switch input must be either from a common

control contact or a parallel combination of Auxiliary ‘a’ contacts or a series combination

of Auxiliary ‘b’ contacts from the reduced voltage contactor and the full voltage contactor.

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Once transition is initiated, the 369 will assume the motor is still running for at least 2

seconds. This will prevent the 369 from recognizing an additional start if motor current

goes to zero during an open transition.

FIGURE 5–4: Reduced Voltage Starter Auxiliary A/B Status Inputs

Autorestart

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS ØØØ AUTORESTART

Range: Yes, No

AUTORESTART

AUTORESTART ENABLED:

Range: 0 to 65000 in steps of 1

Range: 0 to 20000 s in steps of 1

Range: Yes, No

TOTAL RESTARTS:

RESTART

DELAY: 0 s

PROGRESSIVE

DELAY: 0 s

HOLD

DELAY: 0 s

BUS VALID ENABLED :

Range: 15 to 100% of Motor Rated Voltage in steps of

BUS VALID LEVEL :

100%

Range: On, Off

AUTORESTART ATTEMPT

EVENTS: Off

AUTORESTART SUCCESS

EVENTS: Off

AUTORESTART ABORTED

EVENTS: Off

1.Only shown if option M or B are installed

The 369 can be configured to automatically restart the motor after it tripped on system or

process related disturbances, such as an undervoltage or an overload. This feature is

useful in remote unmanned pumping applications. Before using autorestart, the feature

must be enabled, the required restart time after a trip programmed, and an output contact

configured to initiate the autorestart by closing the circuit breaker or contactor. This output

contact can also be wired with OR logic in the start circuit of the motor.

To prevent the possibility of closing onto a fault upon autorestarting, this feature is not

allowed for all trips. The 369 never attempts an autorestart after Short Circuit or Ground

Fault trips. Furthermore, only one autorestart is attempted after an Overload trip, provided

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that Single Shot Restart is enabled, which allows a single restart attempt. The thermal

capacity is cleared to prevent another overload trip during this start and if the 369 trips

again (second time) on Overload the autorestarting is aborted. Any normal manual starting

will probably be inhibited, (lockout time) allowing the motor to cool (thermal capacity to

decay) before permitting another start.

The trip relay should reset before closing the auto-restart contact to allow the breaker or

contactor to close. This is done by programming S2 SYSTEM SETUP ÖØ OUPUT RELAY

SETUP ÖØ TRIP RESET MODE to “Remote Only” or “All Resets”. The close contact

selection is enabled by setting the S2 SYSTEM SETUP ÖØ CONTROL FUNCTIONS ÖØ

SERIAL COMMUNICATION CONTROL ÖØ SERIAL COMMUNICATION CONTROL

setpoint to “On” and selecting the desired output contact.

The 369 follows the logic shown in FIGURE 5–5: AUTORESTART LOGIC on page 5–136 to

determine restart conditions. The total autorestart delay comprises the sum of three

delays: Restart Delay, Progressive Delay, and Hold Delay. If any of these are not required,

the autorestart delay can be set to zero.

Total Delay = Restart Delay + (auto-restarts number x Progressive Delay) + Hold Delay

The Restart Delay controls the basic auto-restart time and the timer start when the motor

tripped. The Progressive Delay increases each consecutive auto-restart delay with its set

amount. For example, assume that Restart Delay, Progressive Delay, and Hold Delay are 1,

3, and 0 seconds respectively. Therefore the fifth autorestart waiting time is:

1 sec. + 5th auto-restart × 3 sec. + 0 sec. = 1 sec. + 5 x 3 sec. = 16 sec.

The number of autorestarts is limited by the TOTAL RESTARTS setting to a maximum of

65000. Once this is exceeded, the 369 blocks further autorestarts until it is reset, either

manually or remotely. This limit does not affect normal starting. Please note that 65000

autorestarts implies the motor has been tripped that many times and inspection or

maintenance is probably due. The vendor's suggested number of circuit breaker or

contactor operations before maintenance can affect this setting.

The Hold Delay sequentially staggers auto-restarts for multiple motors on a bus. For

example, if four motors on a bus have settings of 60, 120, 180, and 240 seconds,

respectively, it is advantageous, after a common fault that trips all four motors, to

autorestart at 60 second intervals to minimize voltage sag and overloading

The presence of healthy bus voltage prior to the auto-restart can be verified by enabling

the Bus Valid feature. The BUS VALID LEVEL setting is the voltage level below which

autorestart is not to be attempted. The 369 checks the BUS VALID LEVEL just before the

autorestart to allow the bus voltage to recover. This setpoint is only available if the

Metering Option (M) or Backspin Option (B) is enabled.

Five different types of “Autorestart Aborted” events have been provided to help in

troubleshooting. The following flowchart shows the logic flow of the Autorestart algorithm.

Each type of Autorestart Aborted event and where it occurs within the logic flow is

indicated in this diagram. For example, if an “Autorestart Aborted1” event is recorded in the

event recorder, the logic diagram immediately indicates that the abort cause was the

number of restart attempts being more than the MAXIMUM NUMBER OF RESTARTS

setpoint.

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FIGURE 5–5: AUTORESTART LOGIC

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Undervoltage Autorestart

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS ØØØ UNDERVOLTAGE

AUTORESTART

Range: Off, On (Default: Off)

UNDERVOLTAGE

AUTORESTART

ENABLE UVR:

Range: 0.5 to 1.0 x RATED in steps of 0.01

(Default 0.65 X RATED)

Note: Must be set lower than the UVR Restoration Level

UVR PICKUP LEVEL:

0.65 x Rated

Range: None, Trip, Aux1, Aux2 or combinations

(Default: None)

UVR ASSIGN TRIP

RELAYS: None

Range: 0 to 255 s in steps of 0.1 s (Default: 0)

UVR TRIP DELAY:

0.0 seconds

Range: 0.5 to 1.0 x RATED in steps of 0.01

(Default: 0.90 X RATED)

Note: Must be set higher than the UVR Pickup Level

UVR RESTORATION

LEVEL: 0.90 x Rated

Range: 100 to 500 ms or Off in steps of 100 ms

(Default: Off)

IMMED RESTART POWER

LOSS TIME: 200 ms

Range: 0.1 to 10 s or Off in steps of 0.1 s

DELAY1 RESTART POWER

LOSS TIME: 2.0 s

(Default: Off)

0 = Off

Range: 1 to 3600 s or Unlimited, Off in steps of 1 s

(Default: Off)

DELAY2 RESTART POWER

LOSS TIME: Off

0 = Off, 3601 = Unlimited

Range: 0 to 1200 s in steps of 0.2 s

(Default: 2.0 s)

DELAY1 RESTART

TIME DELAY: 2.0 s

Range: 0 to 1200 s in steps of 0.2 s

(Default: 10.0 s)

DELAY2 RESTART

TIME DELAY: 10.0 s

Range: 0 to 1200 s in steps of 0.2 s

(Default: 10.0 s)

UVR SETUP TIME:

10.0 seconds

1.Only shown if option M or B are installed

This feature is only available if the Metering option (M) or Backspin option (B) is present, and

the setpoint VT CONNECTION TYPE is set to something other than “None”.

ENABLE UNDERVOLTAGE AUTORESTART It is possible to restart the motor after a

momentary power loss (dip) if this feature is enabled. When the magnitude of either of Vab,

Vbc, or Vca drops below the setpoint UVR PICKUP LEVEL, the motor contactor(s) are de-

energized. The duration of the power loss is classified as Immediate restart power loss,

delay 1 restart power loss and delay 2 restart power loss based on settable time

thresholds. The motor contactor or breaker can be tripped by the 369 if the setpoint UVR

ASSIGN TRIP RELAYS is set a contact output other than “None”, and the assigned

contact output is wired to the trip circuit.

If the power is restored as indicated by the magnitudes of Vab, Vbc, or Vca all recover

above the setpoint UVR RESTORATION LEVEL within the IMMED. RESTART POWER

LOSS TIME, the motor will be restarted immediately. If the power is restored after the

IMMED. RESTART POWER LOSS TIME but before the DELAY 1 RESTART POWER

LOSS TIME or DELAY 2 RESTART POWER LOSS TIME, the motor will be restarted after

the DELAY 1 RESTART TIME DELAY or DELAY 2 RESTART TIME DELAY. If a delayed

restart is always required, set the DELAY 2 RESTART POWER LOSS TIME to

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S2 SYSTEM SETUP

CHAPTER 5: SETPOINTS

UNLIMITED. If another power loss occurs during the DELAY 1 RESTART TIME DELAY

or DELAY 2 RESTART TIME DELAY, all the autorestart timers will be reset and the

autorestart element will be re-initiated based on the latest power loss.

If this feature is used, the Spare Switch must be used as a Starter Status Switch input

reflecting the state of the main contactor or breaker.

The trip relay should reset before closing the autorestart contact to allow the breaker or

contactor to close. This is done by programming S2 SYSTEM SETUP - OUPUT RELAY

SETUP - TRIP RESET MODE to “Remote Only” or “All Resets”. The element uses an output

contact to initiate the autorestart by closing the circuit breaker or contactor. This output

contact can be wired with OR logic in the start circuit of the motor. The close contact

selection is enabled by setting the setpoint S2 SYSTEM SETUP - CONTROL FUNCTIONS

- SERIAL COMMUNICATION CONTROL - SERIAL COMMUNICATION CONTROL to

“On” and selecting the desired output contact for the setpoint ASSIGN START CONTROL

RELAYS.

The difference between the undervoltage autorestart with the SYSTEM SETUP –

CONTROL FUNCTIONS – AUTORESTART element: The undervoltage restart is blocked

by any trip issued by 369 except undervoltage element, and if the undervoltage restart is

enabled, the SYSTEM SETUP – CONTROL FUNCTIONS – AUTORESTART can't be

activated by undervoltage element. It means that if the undervoltage autorestart is

enabled, the undervoltage autorestart element covers no trip condition and under voltage

trip condition, the SYSTEM SETUP – CONTROL FUNCTIONS – AUTORESTART covers

all the trip condition except undervoltage condition.

UVR PICKUP LEVEL sets the motor voltage level below which the undervoltage

autorestart element is triggered. Must be set lower than UVR RESTORATION LEVEL.

UVR ASSIGN TRIP RELAYS assign the trip relay to open the contactor or breaker when a

power loss is detected and the duration is longer than the setpoint UVR TRIP DELAY.

None disables the UVR trip output.

UVR TRIP DELAY sets the time delay to trip the breaker or contactor.

UVR RESTORATION LEVEL sets the motor voltage level above which the undervoltage

autorestart element restarts. Must be set higher than UVR PICKUP LEVEL.

IMMED. RESTART POWER LOSS TIME sets the immediate autorestart power loss

duration, which result in immediate restart. Off disables immediate restart.

DELAY 1 RESTART POWER LOSS TIME Off disables the delay 1 undervoltage

autorestart.

DELAY 2 RESTART POWER LOSS TIME sets to UNLIMITED if a delayed restart is

always required. Off disables the delay 2 undervoltage autorestart.

UVR SETUP TIME sets the amount of time the voltages must be healthy before a another

immediate restart is to be attempted.

Note

The Undervoltage Autorestart feature is intended for use in applications where the 369 is

powered from an uninterruptible power supply, separate from the AC mains powering the

motor. For applications where the 369 is supplied from the same AC mains as the motor,

the timing specification for restarting the motor is ±9 seconds. Care must be taken when

coordinating process start-up.

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CHAPTER 5: SETPOINTS

S2 SYSTEM SETUP

Force Output Relays

PATH: S2 SYSTEM SETUP ØØØØØ CONTROL FUNCTIONS ØØØØ FORCE OUTPUT

RELAYS

Range: None, Trip, Alarm, Aux1, Aux2, or combinations

of these.

FORCE OUTPUT RELAYS

ASSIGN COMMS FORCE

RELAYS: None

Range: Latched, Pulsed

TRIP COM FORCE O/P

TYPE: Latched

Range: 0.5 to 5000.0 s in steps of 0.1. Only seen if the

TRIP PULSED OP DWELL

TIME: 0.5 s

TRIP COM FORCE O/P TYPE is “Pulsed”.

Range: Latched, Pulsed

ALARM COM FORCE O/P

TYPE: Latched

Range: 0.5 to 5000.0 s in steps of 0.1. Only seen if the

ALARM PULSED OP

DWELL

ALARM COM FORCE O/P TYPE is

Range: Latched, Pulsed

AUX1 COM FORCE O/P

TYPE: Latched

Range: 0.5 to 5000.0 s in steps of 0.1. Only seen if the

AUX1 PULSED OP DWELL

TIME: 0.5 s

AUX1 COM FORCE O/P TYPE is “Pulsed”.

Range: Latched, Pulsed

AUX2 COM FORCE O/P

TYPE: Latched

Range: 0.5 to 5000.0 s in steps of 0.1. Only seen if the

AUX2 PULSED OP DWELL

TIME: 0.5 s

AUX2 COM FORCE O/P TYPE is “Pulsed”.

The force output relays function allows the user to energize and de-energize output relays

via remote communications (Modbus or Profibus-DVP1).

To allow the forcing of relay states, the ASSIGN COMMS FORCE RELAY setting must be

programmed. Only relays assigned under this setpoint can be forced through Modbus or

Profibus-DPV1 communications.

Commands can be sent to energize or de-energize any of the four output relays. A bit value

of “1” for the corresponding relay will energize that relay; a bit value of “0” will de-energize

that relay.

The COM FORCE O/P TYPE setting for each relay determines whether it remains latched

in the state sent through the command, or whether it operates for a duration programmed

in the associated PULSED OP DWELL TIME setting. If COM FORCE O/P TYPE is

“Latched”, the relay remains energized until a value of “0” for the relay has been sent

through the command. If COM FORCE O/P TYPE is “Pulsed” and a command is sent to

energize the output relay while a pulse dwell timer from a previous command has not yet

timed to zero, then the timer will reset back to the value of the corresponding PULSED OP

DWELL TIME setpoint and start counting down from this value.

If a relay state is programmed as “Latched” and forced through the force output relays

function, the only way to de-energize it is through another serial command or by cycling

power to the 369.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S2 SYSTEM SETUP

CHAPTER 5: SETPOINTS

Note

For safety reasons, if any of the relays in the S11 TESTING Ø TEST OUTPUT RELAYS

section are programmed to any value other than “Disabled” (i.e. energized or de-

energized), then the force relays functionality through Modbus and Profibus-DPV1 will be

disabled.

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CHAPTER 5: SETPOINTS

S3 OVERLOAD PROTECTION

5.4 S3 Overload Protection

5.4.1 Description

Heat is one of the principle enemies of motor life. When a motor is specified, the purchaser

communicates to the manufacturer what the loading conditions, duty cycle, environment

and pertinent information about the driven load such as starting torque. The manufacturer

then provides a stock motor or builds a motor that should have a reasonable life under

those conditions. The purchaser should request all safe stall, acceleration and running

thermal limits for all motors they receive in order to effectively program the 369.

Motor thermal limits are dictated by the design of the stator and the rotor. Motors have

three modes of operation: locked rotor or stall (rotor is not turning), acceleration (rotor is

coming up to speed), and running (rotor turns at near synchronous speed). Heating occurs

in the motor during each of these conditions in very distinct ways. Typically, during motor

starting, locked rotor, and acceleration conditions, the motor is rotor limited. That is, the

rotor approaches its thermal limit before the stator. Under locked rotor conditions, voltage

is induced in the rotor at line frequency, 50 or 60 Hz. This voltage causes a current to flow

in the rotor, also at line frequency, and the heat generated (I²R) is a function of the effective

rotor resistance. At 50/60 Hz, the rotor cage reactance causes the current to flow at the

outer edges of the rotor bars. The effective resistance of the rotor is therefore at a

maximum during a locked rotor condition as is rotor heating. When the motor is running at

rated speed, the voltage induced in the rotor is at a low frequency (approximately 1 Hz)

and therefore, the effective resistance of the rotor is reduced quite dramatically. During

running overloads, the motor thermal limit is typically dictated by stator parameters. Some

special motors might be all stator or all rotor limited. During acceleration, the dynamic

nature of the motor slip dictates that rotor impedance is also dynamic, and a third

overload thermal limit characteristic is necessary.

Typical thermal limit curves are shown below. The motor starting characteristic is shown

for a high inertia load at 80% voltage. If the motor started quicker, the distinct

characteristics of the thermal limit curves would not be required and the running overload

curve would be joined with locked rotor safe stall times to produce a single overload curve.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S3 OVERLOAD PROTECTION

CHAPTER 5: SETPOINTS

FIGURE 5–6: Typical Time-current and Thermal Limit Curves (ANSI/IEEE C37.96)

5.4.2 Thermal Model

PATH: S3 OVERLOAD PROTECTION Ø THERMAL MODEL

Range: 1.01 to 1.25 in steps of 0.01

THERMAL MODEL

OVERLOAD PICKUP

LEVEL: 1.01 x FLA

Range: Off, Latched, Unlatched

THERMAL CAPACITY

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN TC ALARM

RELAYS: Alarm

Range: 1 to 100% in steps of 1

TC ALARM LEVEL:

75 % Used

Range: No, Yes

THERMAL CAPACITY

ALARM EVENTS: No

Range: None, Trip, Aux1, Aux2 or combinations of

them (TC trip always on and latched)

ASSIGN TC TRIP

RELAYS: Trip

Range: On, Off

ENABLE UNBALANCE

BIAS OF TC: Off

Range: Learned, 1 to 29 in steps of 1

UNBALANCE BIAS

K FACTOR: Learned

Only shown if UNBALANCE BIAS is enabled

Range: 0.01 to 1.00 in steps of 0.01

HOT/COLD SAFE STALL

RATIO: 1.00

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 5: SETPOINTS

S3 OVERLOAD PROTECTION

Range: No, Yes

ENABLE LEARNED COOL

TIME: No

Range: 1 to 500 min. in steps of 1

RUNNING COOL TIME

CONSTANT: 15 min.

Not shown if LEARNED COOL TIME is enabled

Range: 1 to 500 min. in steps of 1

STOPPED COOL TIME

CONSTANT: 30 min.

Not shown if Learned Cool time is enabled

Range: No, Yes

ENABLE RTD BIASING:

Range: 1 to RTD BIAS MID POINT

RTD BIAS MINIMUM:

40 °C

Only shown if RTD BIASING is enabled

Range: RTD BIAS MINIMUM to MAXIMUM

Only shown if RTD BIASING is enabled

RTD BIAS MID POINT:

120 °C

Range: RTD BIAS MID POINT to 200

Only shown if RTD BIASING is enabled

RTD BIAS MAXIMUM:

155 °C

Range: 3 to 60 cycles in steps of 3

MOTOR LOAD AVERAGING

INTERVAL: 3 cycles

The primary protective function of the 369 is the thermal model. It consists of five key

elements: the overload curve and pickup level, unbalance biasing, motor cooling time

constants, and temperature biasing based on Hot/Cold motor information and measured

stator RTD temperature.

The 369 integrates both stator and rotor heating into one model. Motor heating is reflected

in the THERMAL CAPACITY USED actual value. If stopped for a long period of time, the motor

will be at ambient temperature and THERMAL CAPACITY USED should be zero. If the motor is in

overload, a trip will occur once the thermal capacity used reaches 100%. Insulation does

not immediately melt when a motor’s thermal limit is exceeded. Rather, the rate of

insulation degradation reaches a point where the motor life will be significantly reduced if

the condition persists. The thermal capacity used alarm may be used as a warning of an

impending overload trip.

The 369 thermal model can be modified to allow compensation for motors used to drive

cyclic loads, such as a reciprocating compressor. The MOTOR LOAD AVERAGING

INTERVAL setting allows the user to dampen the effects of these loads as they relate to

the overall interpretation of the motor thermal characteristics. The load cycle can be

determined using the 369 waveform capture feature or through external equipment. The

size of the load cycle is then entered into the MOTOR LOAD AVERAGING INTERVAL

setpoint. The 369 uses this value to average the motor load, as applied to the thermal

model, over the duration of the load cycle. The result is a damping effect applied to the

thermal model. The setting is entered in steps of 3 to correspond with the run rate of the

369 thermal model. For load cycles not evenly divisible by 3, enter a value equal to the next

multiple of 3 for the MOTOR LOAD AVERAGING INTERVAL.

Motor load averaging may increase trip/alarm times by 16.7 ms for every additional

cycle averaged greater than 3.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S3 OVERLOAD PROTECTION

CHAPTER 5: SETPOINTS

5.4.3 Overload Curves

Settings

PATH: S3 OVERLOAD PROTECTION ØØ OVERLOAD CURVE

Range: Standard, Custom

OVERLOAD CURVE

SELECT CURVE STYLE:

Standard

Range: 1 to 15 in steps of 1

Only seen if CURVE STYLE is Standard

STANDARD OVERLOAD

CURVE NUMBER: 4

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.01xFLA: 17415s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.05xFLA: 3415 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.10xFLA: 1667 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.20xFLA: 795 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.30xFLA: 507 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.40xFLA: 365 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.50xFLA: 280 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

1.75xFLA: 170 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

2.00xFLA: 117 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

2.25xFLA: 86 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

2.50xFLA: 67 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

2.75xFLA: 53 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

3.00xFLA: 44 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

3.25xFLA: 37 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

3.50xFLA: 31 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

3.75xFLA: 27 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

4.00xFLA: 23 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

4.25xFLA: 21 s

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 5: SETPOINTS

S3 OVERLOAD PROTECTION

Range: 0 to 65534 s in steps of 1

TIME TO TRIP AT

4.50xFLA: 18 s

Only seen if CURVE STYLE is Custom

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

4.75xFLA: 16 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

5.00xFLA: 15 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

5.50xFLA: 12 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

6.00xFLA: 10 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

6.50xFLA: 9 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

7.00xFLA: 7 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

7.50xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

8.00xFLA: 6 S

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

10.0xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

15.0xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

TIME TO TRIP AT

20.0xFLA: 6 s

Standard Overload Curve:

The overload curve accounts for motor heating during stall, acceleration, and running in

both the stator and the rotor. The OVERLOAD PICKUP setpoint dictates where the

running overload curve begins as the motor enters an overload condition. This is useful for

service factor motors as it allows the pickup level to be defined. The curve is effectively cut

off at current values below this pickup.

Motor thermal limits consist of three distinct parts based on the three conditions of

operation, locked rotor or stall, acceleration, and running overload. Each of these curves

may be provided for both a hot motor and a cold motor. A hot motor is defined as one that

has been running for a period of time at full load such that the stator and rotor

temperatures have settled at their rated temperature. A cold motor is defined as a motor

that has been stopped for a period of time such that the stator and rotor temperatures

have settled at ambient temperature. For most motors, the distinct characteristics of the

motor thermal limits are formed into one smooth homogeneous curve. Sometimes only a

safe stall time is provided. This is acceptable if the motor has been designed conservatively

and can easily perform its required duty without infringing on the thermal limit. In this

case, the protection can be conservative and process integrity is not compromised. If a

motor has been designed very close to its thermal limits when operated as required, then

the distinct characteristics of the thermal limits become important.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S3 OVERLOAD PROTECTION

CHAPTER 5: SETPOINTS

The 369 overload curve can take one of two formats: Standard or Custom Curve.

Regardless of which curve style is selected, the 369 will retain thermal memory in the form

of a register called THERMAL CAPACITY USED. This register is updated every 100 ms

using the following equation:

100 ms

time_to_trip

------------------------------

TCused_t= TCused_{t – 100 ms}

× 100%

(EQ 5.2)

where: time_to_trip = time taken from the overload curve at I_eqas a function of FLA.

The overload protection curve should always be set slightly lower than the thermal limits

provided by the manufacturer. This will ensure that the motor is tripped before the thermal

limit is reached.

If the motor starting times are well within the safe stall times, it is recommended that the

369 Standard Overload Curves be used. The standard overload curves are a series of 15

curves with a common curve shape based on typical motor thermal limit curves (see

FIGURE 5–7: 369 Standard Overload Curves on page 5–146 and FIGURE 5–7: 369 Standard

Overload Curves on page 5–146).

FIGURE 5–7: 369 Standard Overload Curves

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 5: SETPOINTS

S3 OVERLOAD PROTECTION

Table 5–1: 369 STANDARD OVERLOAD CURVES

PICKU

STANDARD CURVE MULTIPLIERS

LEVEL

(× FLA)

× 1

× 2

× 3

× 4

× 5

× 6

× 7

× 8

× 9

× 10 × 11 × 12 × 13 × 14 × 15

1.01

4353.6 8707.2 13061 17414 21768 26122 30475 34829 39183 43536

47890

52243

56597

11098

60951

11952

65304

12806

1.05

1.10

1.20

1.30

1.40

1.50

1.75

2.00

2.25

2.50

2.75

3.00

3.25

3.50

3.75

4.00

4.25

4.50

4.75

5.00

5.50

6.00

6.50

7.00

7.50

8.00

10.00

15.00

20.00

853.71 1707.4 2561.1 3414.9 4268.6 5122.3 5976.0 6829.7 7683.4 8537.1 9390.8 10245

416.68 833.36 1250.0 1666.7 2083.4 2500.1 2916.8 3333.5 3750.1 4166.8 4583.5 5000.2 5416.9 5833.6 6250.2

198.86 397.72 596.58 795.44 994.30 1193.2 1392.0 1590.9 1789.7 1988.6 2187.5 2386.3 2585.2 2784.1 2982.9

126.80 253.61 380.41 507.22 634.02 760.82 887.63 1014.4 1141.2 1268.0 1394.8 1521.6 1648.5 1775.3 1902.1

91.14

69.99

42.41

29.16

21.53

16.66

13.33

10.93

9.15

7.77

6.69

5.83

5.12

4.54

4.06

3.64

2.99

2.50

2.12

1.82

1.58

1.39

182.27 273.41 364.55 455.68 546.82 637.96 729.09 820.23 911.37 1002.5 1093.6 1184.8 1275.9 1367.0

139.98 209.97 279.96 349.95 419.94 489.93 559.92 629.91 699.90 769.89 839.88 909.87 979.86 1049.9

84.83

58.32

43.06

33.32

26.65

21.86

18.29

15.55

13.39

11.66

10.25

9.08

127.24 169.66 212.07 254.49 296.90 339.32 381.73 392.15 466.56 508.98 551.39 593.81 636.22

116.63 145.79 174.95 204.11 233.26 262.42 291.58 320.74 349.90 379.05 408.21 437.37

107.65 129.18 150.72 172.25 193.78 215.31 236.84 258.37 279.90 301.43 322.96

116.62 133.28 149.94 166.60 183.26 199.92 216.58 233.24 249.90

106.62 119.95 133.27 146.60 159.93 173.25 186.58 199.91

109.32 120.25 131.19 142.12 153.05 163.98

100.60 109.75 118.89 128.04 137.18

101.05 108.83 116.60

87.47

64.59

49.98

39.98

32.80

27.44

23.32

20.08

17.49

15.37

13.63

12.17

10.93

8.97

86.12

66.64

53.31

43.73

36.58

31.09

26.78

23.32

20.50

18.17

16.22

14.57

11.96

9.99

83.30

66.64

54.66

45.73

38.87

33.47

29.15

25.62

22.71

20.28

18.22

14.95

12.49

10.60

9.11

99.96

79.96

65.59

54.87

46.64

40.17

34.98

30.75

27.25

24.33

21.86

17.94

14.99

12.72

10.93

9.49

93.29

76.52

64.02

54.41

46.86

40.81

35.87

31.80

28.39

25.50

20.93

17.49

14.84

12.75

11.08

9.71

87.46

73.16

62.19

53.56

46.64

41.00

36.34

32.44

29.15

23.91

19.99

16.96

14.57

12.66

11.10

98.39

82.31

69.96

60.25

52.47

46.12

40.88

36.50

32.79

26.90

22.48

19.08

16.39

14.24

12.49

91.46

77.73

66.95

58.30

51.25

45.42

40.55

36.43

29.89

24.98

21.20

18.21

15.82

13.88

85.51

73.64

64.13

56.37

49.97

44.61

40.08

32.88

27.48

23.32

20.04

17.41

15.27

93.28

80.34

69.96

61.50

54.51

48.66

43.72

35.87

29.98

25.44

21.86

18.99

16.65

87.03

75.79

66.62

59.05

52.72

47.36

38.86

32.48

27.55

23.68

20.57

18.04

93.73

81.62

71.75

63.59

56.77

51.01

41.85

34.97

29.67

25.50

22.15

19.43

100.42

87.45

76.87

68.14

60.83

54.65

44.84

37.47

31.79

27.32

23.74

20.82

8.11

7.29

5.98

5.00

7.49

4.24

6.36

8.48

3.64

5.46

7.29

3.16

4.75

6.33

7.91

2.78

4.16

5.55

6.94

8.33

2.78

4.16

5.55

6.94

8.33

9.71

2.78

4.16

5.55

6.94

8.33

9.71

2.78

4.16

5.55

6.94

8.33

9.71

Note

Above 8.0 x Pickup, the trip time for 8.0 is used. This prevents the overload curve from

acting as an instantaneous element.

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The Standard Overload Curves equation is:

curve_multiplier × 2.2116623

(EQ 5.3)

time_to_trip = -----------------------------------------------------------------------------------------------------------------------------------------------

0.02530337 × (pickup – 1) + 0.05054758 × (pickup – 1)

Custom Overload Curve:

If the motor starting current begins to infringe on the thermal damage curves, it may be

necessary to use a custom curve to ensure successful starting without compromising

motor protection. Furthermore, the characteristics of the starting thermal damage curve

(locked rotor and acceleration) and the running thermal damage curves may not fit

together very smoothly. In this instance, it may be necessary to use a custom curve to

tailor protection to the motor thermal limits so the motor may be started successfully and

used to its full potential without compromising protection. The distinct parts of the thermal

limit curves now become more critical. For these conditions, it is recommended that the

369 custom curve thermal model be used. The custom overload curve of the 369 allows

the user to program their own curve by entering trip times for 30 pre-determined current

levels. The 369 smooths the areas between these points to make the protection curve.

It can be seen below that if the running overload thermal limit curve were smoothed into

one curve with the locked rotor overload curve, the motor could not start at 80% line

voltage. A custom curve is required.

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FIGURE 5–8: Custom Curve Example

Note

During the interval of discontinuity, the longer of the two trip times is used to reduce

the chance of nuisance tripping during motor starts.

Unbalance Bias

Unbalanced phase currents cause additional rotor heating not accounted for by

electromechanical relays and may not be accounted for in some electronic protective

relays. When the motor is running, the rotor rotates in the direction of the positive-

sequence current at near synchronous speed. Negative-sequence current, having a phase

rotation opposite to the positive sequence current, and hence, opposite to the rotor

rotation, generates a rotor voltage that produces a substantial rotor current. This induced

current has a frequency approximately twice the line frequency: 100 Hz for a 50 Hz system,

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120 Hz for a 60 Hz system. Skin effect in the rotor bars at this frequency causes a

significant increase in rotor resistance, and therefore a significant increase in rotor

heating. This extra heating is not accounted for in the motor manufacturer thermal limit

curves, since these curves assume positive-sequence currents only from a perfectly

balanced supply and motor design.

The 369 measures the percentage unbalance for the phase currents. The thermal model

may be biased to reflect the additional heating caused by negative-sequence current,

present during an unbalance when the motor is running. This is done by creating an

equivalent motor heating current that takes into account the unbalanced current effect

along with the average phase current. This current is calculated as follows:

1 + k × (UB%)

avg

= ------------------------------------------------------

(EQ 5.4)

FLA

where: I_eq= equivalent unbalance biased heating current

_avg= average RMS phase current measured

UB% = unbalance percentage measured (100% = 1, 50% = 0.5, etc.)

k = unbalance bias k factor

The figure on the left shows motor derating as a function of voltage unbalance as

recommended by the American organization NEMA (National Electrical Manufacturers

Association). Assuming a typical induction motor with an inrush of 6 × FLA and a negative

sequence impedance of 0.167, voltage unbalances of 1, 2, 3, 4, and 5% equal current

unbalances of 6, 12, 18, 24, and 30% respectively. Based on this assumption, the figure on

the right below illustrates the amount of motor derating for different values of k entered

for the setpoint UNBALANCE BIAS K FACTOR. Note that the curve for k = 8 is almost

identical to the NEMA derating curve.

NEMA

GE MULTILIN

FIGURE 5–9: Medium Motor Derating Factor due to Unbalanced Voltage

If a k value of 0 is entered, the unbalance biasing is defeated and the overload curve will

time out against the measured per unit motor current. The k value may be calculated as:

(EQ 5.5)

175

230

k = -------- (typical estimate); k = -------- (conservative estimate), where I is the per unit locked rotor current

The 369 can also learn the unbalance bias k factor. It is recommended that the learned k

factor not be enabled until the motor has had at least five successful starts. The

calculation of the learned k factor is as follows:

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(EQ 5.6)

175

k = -------------------------------- where I

= learned start current, FLA = Full Load Amps setpoint

LSC

⁄ FLA)

LSC

Motor Cooling

The thermal capacity used quantity is reduced in an exponential manner when the motor

is stopped or current is below the overload pickup setpoint. This reduction simulates motor

cooling. The motor cooling time constants should be entered for both the stopped and

running cases. A stopped motor will normally cool significantly slower than a running

motor. Note that the cool time constant is one fifth the total cool time from 100% thermal

capacity used down to 0% thermal capacity used.

The 369 can learn and estimate the stopped and running cool time constants for a motor.

Calculation of a cool time constant is performed whenever the motor state transitions

from starting to running or from running to stopped. The learned cool times are based on

the cooling rate of the hottest stator RTD, the hot/cold ratio, the ambient temperature (40 if

no ambient RTD), the measured motor load and the programmed service factor or

overload pickup. Learned values should only be enabled for motors that have been started,

stopped and run at least five times.

Note that any learned cool time constants are mainly based on stator RTD information.

Cool time, for starting, is typically a rotor limit. The use of stator RTDs can only render an

approximation. The learned values should only be used if the real values are not available

from the motor manufacturer. Motor cooling is calculated using the following formulas:

–t ⁄ τ

TCused = (TCused_start – TCused_end) ⋅ (e

) + TCused_end

(EQ 5.7)

(EQ 5.8)

hot

⎛

⎞

TCused_end = I × 1 – ---------- × 100%

⎝

⎠

cold

where: TCused = thermal capacity used

TCused_start = TC used value caused by overload condition

TCused_end = TC used value set by the hot/cold curve ratio when motor is

running = '0' when motor is stopped.

t = time in minutes

τ = cool time constant (running or stopped)

_eq= equivalent motor heating current

overload_pickup = overload pickup setpoint as a multiple of FLA

hot/cold = hot/cold curve ratio

Hot/Cold Curve Ratio

The motor manufacturer will sometimes provide thermal limit information for a hot/cold

motor. The 369 thermal model will adapt for these conditions if the Hot/Cold Curve Ratio is

programmed. The value entered for this setpoint dictates the level of thermal capacity

used that the relay will settle at for levels of current that are below the Overload Pickup

Level. When the motor is running at a level that is below the Overload Pickup Level, the

thermal capacity used will rise or fall to a value based on the average phase current and

the entered Hot/Cold Curve Ratio. Thermal capacity used will either rise at a fixed rate of

5% per minute or fall as dictated by the running cool time constant.

hot

cold

⎛

⎞

TCused_end = I × 1 – ---------- × 100%

(EQ 5.9)

⎝

⎠

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where: TCused_end = Thermal Capacity Used if I_{per_unit}remains steady state

_eq= equivalent motor heating current

hot/cold = HOT/COLD CURVE RATIO setpoint

The hot/cold curve ratio may be determined from the thermal limit curves if provided or

the hot and cold safe stall times. Simply divide the hot safe stall time by the cold safe stall

time. If hot and cold times are not provided, there can be no differentiation and the hot/

cold curve ratio should be entered as 1.00.

FIGURE 5–10: Thermal Model Cooling

RTD Bias

The 369 thermal replica operates as a complete and independent model. The thermal

overload curves however, are based solely on measured current, assuming a normal 40°C

ambient and normal motor cooling. If there is an unusually high ambient temperature, or if

motor cooling is blocked, motor temperature will increase. If the motor stator has

embedded RTDs, the 369 RTD bias feature should be used to correct the thermal model.

The RTD bias feature is a two part curve constructed using three points. If the maximum

stator RTD temperature is below the RTD Bias Minimum setpoint (typically 40°C), no biasing

occurs. If the maximum stator RTD temperature is above the RTD Bias Maximum setpoint

(typically at the stator insulation rating or slightly higher), then the thermal memory is fully

biased and thermal capacity is forced to 100% used. At values in between, the present

thermal capacity used created by the overload curve and other elements of the thermal

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model is compared to the RTD Bias thermal capacity used from the RTD Bias curve. If the

RTD Bias thermal capacity used value is higher, then that value is used from that point

onward. The RTD Bias Center point should be set at the rated running temperature of the

motor. The 369 will automatically determine the thermal capacity used value for the center

point using the HOT/COLD SAFE STALL RATIO setpoint.

hot

⎛

⎞

TCused@RTD_Bias_Center = 1 – ---------- × 100%

(EQ 5.10)

⎝

⎠

cold

At temperatures less than the RTD_Bias_Center temperature,

– T

actual

min

---------------------------------------

RTD_Bias_TCused =

× TCused@RTD_Bias_Center

(EQ 5.11)

– T

center

min

At temperatures greater than the RTD_Bias_Center temperature,

– T

actual

center

----------------------------------------------

RTD_Bias_TCused =

× (100 – TCused@RTD_Bias_Center) + TCused@RTD_Bias_Center

– T

(EQ 5.12)

max

center

where: RTD_Bias_TCused = TC used due to hottest stator RTD

T_actual= Actual present temperature of hottest stator RTD

_min= RTD Bias minimum setpoint (ambient temperature)

_center= RTD Bias center setpoint (motor running temperature)

T_max= RTD Bias max setpoint (winding insulation rating temperature)

TCused@RTD_Bias_Center = TC used defined by HOT/COLD SAFE STALL

RATIO setpoint

In simple terms, the RTD bias feature is real feedback of measured stator temperature. This

feedback acts as correction of the thermal model for unforeseen situations. Since RTDs are

relatively slow to respond, RTD biasing is good for correction and slow motor heating. The

rest of the thermal model is required during starting and heavy overload conditions when

motor heating is relatively fast.

It should be noted that the RTD bias feature alone cannot create a trip. If the RTD bias

feature forces the thermal capacity used to 100%, the motor current must be above the

overload pickup before an overload trip occurs. Presumably, the motor would trip on

programmed stator RTD temperature setpoint at that time.

FIGURE 5–11: RTD Bias Curve

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5.4.4 Overload Alarm

PATH: S3 OVERLOAD PROTECTION ØØØ OVERLOAD ALARM

Range: Off, Latched, Unlatched

Range: 1.01 to 1.50 in steps of 0.01

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 0 to 60.0 s in steps of 0.1

Range: On, Off

OVERLOAD ALARM

OVERLOAD

ALARM: Off

OVERLOAD ALARM

LEVEL: 1.01 x FLA

ASSIGN O/L ALARM

RELAYS: Alarm

OVERLOAD ALARM

DELAY: 1 s

OVERLOAD ALARM

EVENTS: Off

An overload alarm will occur only when the motor is running and the current rises above

the programmed OVERLOAD ALARM LEVEL. The overload alarm is disabled during a

start. An application of an unlatched overload alarm is to signal a PLC that controls the

load on the motor, whenever the motor is too heavily loaded.

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S4 CURRENT ELEMENTS

5.5 S4 Current Elements

5.5.1 Description

These elements deal with functions that are based on the current readings of the 369 from

the external phase and/or ground CTs. All models of the 369 include these features.

5.5.2 Short Circuit

PATH: S4 CURRENT ELEMENTS Ø SHORT CIRCUIT

Range: 50/60 Hz Nominal: Off, Latched, Unlatched

SHORT CIRCUIT

TRIP: Off

Variable: Off, Latched

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN S/C TRIP

RELAYS: Trip

Range: 2.0 to 20.0 x CT in steps of 0.1

SHORT CIRCUIT TRIP

LEVEL: 10.0 x CT

Range: 0 to 255.00 s in steps of 0.01

0 = Instantaneous

ADD S/C TRIP

DELAY: 0.00 s

Range: 50/60 Hz Nominal: Off, Latched, Unlatched

Variable: Off, Latched

SHORT CIRCUIT TRIP

BACKUP: Off

Range: None, Aux1, Aux2, or combinations of them

ASSIGN S/C BACKUP

RELAYS: Aux1

Range: 0 to 255.00 s in steps of 0.01

0 = Instantaneous

ADD S/C BACKUP TRIP

DELAY: 0.20 s

Note

Care must be taken when turning on this feature. If the interrupting device (contactor

or circuit breaker) is not rated to break the fault current, this feature should be

disabled. Alternatively, this feature may be assigned to an auxiliary relay and

connected such that it trips an upstream device that is capable of breaking the fault

current.

Once the magnitude of either phase A, B, or C exceeds the Pickup Level × Phase CT Primary

for a period of time specified by the delay, a trip will occur. Note the delay is in addition to

the 45 ms instantaneous operate time.

There is also a backup trip feature that can be enabled. The backup delay should be

greater than the short circuit delay plus the breaker clearing time. If a short circuit trip

occurs with the backup on, and the phase current to the motor persists for a period of time

that exceeds the backup delay, a second backup trip will occur. It is intended that this

second trip be assigned to Aux1 or Aux2 which would be dedicated as an upstream

breaker trip relay.

Various situations (e.g. charging a long line to the motor or power factor correction

capacitors) may cause transient inrush currents during motor starting that may exceed

the Short Circuit Pickup level for a very short period of time. The Short Circuit time delay is

adjustable in 10 ms increments. The delay can be fine tuned to an application such that it

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still responds very fast, but rides through normal operational disturbances. Normally, the

Phase Short Circuit time delay will be set as quick as possible, 0 ms. Time may have to be

increased if nuisance tripping occurs.

When a motor starts, the starting current (typically 6 × FLA for an induction motor) has an

asymmetrical component. This asymmetrical current may cause one phase to see as

much as 1.6 times the normal RMS starting current. If the short circuit level was set at 1.25

times the symmetrical starting current, it is probable that there would be nuisance trips

during motor starting. As a rule of thumb the short circuit protection is typically set to at

least 1.6 times the symmetrical starting current value. This allows the motor to start

without nuisance tripping.

Note

Both the main Short Circuit delay and the backup delay start timing when the current

exceeds the Short Circuit Pickup level.

5.5.3 Mechanical Jam

PATH: S4 CURRENT ELEMENTS ØØ MECHANICAL JAM

Range: Off, Latched, Unlatched

MECHANICAL JAM

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 1.01 to 6.00 x FLA in steps of 0.01

Range: 0.5 to 125.0 s in steps of 0.5

Range: On, Off

ASSIGN ALARM RELAYS:

Alarm

MECHANICAL JAM ALARM

LEVEL: 1.50 x FLA

MECHANICAL JAM ALARM

DELAY: 1.0 s

MECHANICAL JAM ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

MECHANICAL JAM

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN TRIP RELAYS:

Trip

Range: 1.01 to 6.00 x FLA in steps of 0.01

MECHANICAL JAM TRIP

LEVEL: 1.50 x FLA

Range: 0.5 to 125.0 s in steps of 0.5

MECHANICAL JAM TRIP

DELAY: 1.0 s

After a motor start, once the magnitude of any one of either phase A, B, or C exceeds the

Trip/Alarm Pickup Level × FLA for a period of time specified by the Delay, a Trip/Alarm will

occur. This feature may be used to indicate a stall condition when running. Not only does it

protect the motor by taking it off-line quicker than the thermal model (overload curve), it

may also prevent or limit damage to the driven equipment that may occur if motor starting

torque persists on jammed or broken equipment.

The level for the Mechanical Jam Trip should be set higher than motor loading during

normal operations, but lower than the motor stall level. Normally the delay would be set to

the minimum time delay, or set such that no nuisance trips occur due to momentary load

fluctuations.

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S4 CURRENT ELEMENTS

5.5.4 Undercurrent

PATH: S4 CURRENT ELEMENTS ØØØ UNDERCURRENT

Range: 0 to 15000 s in steps of 1

UNDERCURRENT

BLOCK UNDERCURRENT

FROM START: 0 s

Range: Off, Latched, Unlatched

UNDERCURRENT

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN U/C ALARM

RELAYS: Alarm

Range: 0.10 to 0.99 x FLA in steps of 0.01

Range: 1 to 255 s in steps of 1

Range: On, Off

UNDERCURRENT ALARM

LEVEL: 0.70 x FLA

UNDERCURRENT ALARM

DELAY: 1 s

UNDERCURRENT ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

UNDERCURRENT

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN U/C TRIP

RELAYS: Trip

Range: 0.10 to 0.99 x FLA in steps of 0.01

UNDERCURRENT TRIP

LEVEL: 0.70 x FLA

Range: 1 to 255 s in steps of 1

UNDERCURRENT TRIP

DELAY: 1 s

If enabled, once the magnitude of either phase A, B or C falls below the pickup level × FLA

for a period of time specified by the Delay, a trip or alarm will occur. The undercurrent

element is an indication of loss of load to the motor. Thus, the pickup level should be set

lower than motor loading levels during normal operations. The undercurrent element is

active when the motor is starting or running.

The undercurrent element can be blocked upon the initiation of a motor start for a period

of time specified by the U/C Block From Start setpoint (e.g. this block may be used to allow

pumps to build up head before the undercurrent element trips). A value of 0 means

undercurrent protection is immediately enabled upon motor starting (no block). If a value

other than 0 is entered, the feature will be disabled from the time a start is detected until

the time entered expires.

Application Example:

If a pump is cooled by the liquid it pumps, loss of load may cause the pump to overheat.

Undercurrent protection should thus be enabled. If the motor loading should never fall

below 0.75 × FLA, even for short durations, the Undercurrent Trip pickup could be set to

0.70 and the Undercurrent Alarm to 0.75. If the pump is always started loaded, the block

from start feature should be disabled (programmed as 0).

Time delay is typically set as quick as possible, 1 second.

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5.5.5 Current Unbalance

PATH: S4 CURRENT ELEMENTS ØØØØ CURRENT UNBALANCE

Range: 0 to 5000 s in steps of 1

Range: Off, Latched, Unlatched

CURRENT UNBALANCE

BLOCK UNBALANCE FROM

START: 0 s

CURRENT UNBALANCE

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN U/B ALARM

RELAYS: Alarm

Range: 4 to 30% in steps of 1

Range: 1 to 255 s in steps of 1

Range: On, Off

UNBALANCE ALARM

LEVEL: 15 %

UNBALANCE ALARM

DELAY: 1 s

UNBALANCE ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

CURRENT UNBALANCE

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN U/B TRIP

RELAYS: Trip

Range: 4 to 30% in steps of 1

UNBALANCE TRIP

LEVEL: 20 %

Range: 1 to 255 s in steps of 1

UNBALANCE TRIP

DELAY: 1 s

Unbalanced three phase supply voltages are a major cause of induction motor thermal

damage. Causes of unbalance can include: increased resistance in one phase due to a

pitted or faulty contactor, loose connections, unequal tap settings in a transformer, non-

uniformly distributed three phase loads, or varying single phase loads within a plant. The

most serious case of unbalance is single phasing – that is, the complete loss of one phase.

This can be caused by a utility supply problem or a blown fuse in one phase and can

seriously damage a three phase motor. A single phase trip will occur in 2 seconds if the

Unbalance trip is on and the level exceeds 30%. A single phase trip will also activate in 2

seconds if the Motor Load is above 30% and at least one of the phase currents is zero.

Single phasing protection is disabled if the Unbalance Trip is turned Off.

During balanced conditions in the stator, current in each motor phase is equal, and the

rotor current is just sufficient to provide the turning torque. When the stator currents are

unbalanced, a much higher current is induced into the rotor due to its lower impedance to

the negative sequence current component present. This current is at twice the power

supply frequency and produces a torque in the opposite direction to the desired motor

output. Usually the increase in stator current is small and timed overcurrent protection

takes a long time to trip. However, the much higher induced rotor current can cause

extensive rotor damage in a short period of time. Motors can tolerate different levels of

current unbalance depending on the rotor design and heat dissipation characteristics.

To prevent nuisance trips/alarms on lightly loaded motors when a much larger unbalance

level will not damage the rotor, the unbalance protection will automatically be defeated if

the average motor current is less than 30% of the full load current (IFLA) setting. Unbalance

is calculated as follows:

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_max– I_avg

-----------------------------

If I_avg≥ I_FLA, Unbalance =

× 100

I_avg

_max– I_avg

-----------------------------

If I_avg< I_FLA, Unbalance =

× 100

(EQ 5.13)

I_FLA

where: I_avg= average phase current,

I_max= current in a phase with maximum deviation from I_avg

_FLA= motor full load amps setting

Unbalance protection is recommended at all times. When setting the unbalance pickup

level, it should be noted that a 1% voltage unbalance typically translates into a 6% current

unbalance. Therefore, in order to prevent nuisance trips or alarms, the pickup level should

not be set too low. Also, since short term unbalances are common, a reasonable delay

should be set to avoid nuisance trips or alarms. It is recommended that the unbalance

thermal bias feature be used to bias the Thermal Model to account for rotor heating that

may be caused by cyclic short term unbalances.

5.5.6 Ground Fault

PATH: S4 CURRENT ELEMENTS ØØØØØ GROUND FAULT

Range: 50/60 Hz Nominal: Off, Latched, Unlatched

GROUND FAULT

ALARM: Off

Variable: Off, Latched

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN G/F ALARM

RELAYS: Alarm

Range: 0.10 to 1.00 x CT in steps of 0.01

Only shown if G/F CT is 1A or 5A

GROUND FAULT ALARM

LEVEL: 0.10 x CT

Range: 0.25 to 25.00 A in steps of 0.01

Only shown if G/F CT is 50:0.025

GROUND FAULT ALARM

LEVEL: 0.25 A

Range: 0.00 to 255.00 s in steps of 0.01s

GROUND FAULT ALARM

DELAY: 0.00 s

Range: On, Off

GROUND FAULT ALARM

EVENTS: Off

Range: 50/60 Hz Nominal: Off, Latched, Unlatched

Variable: Off, Latched

GROUND FAULT

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN GF TRIP

RELAYS: Trip

Range: 0.10 to 1.00 x CT in steps of 0.01

Only shown if Ground Fault CT is 1A or 5A

GROUND FAULT TRIP

LEVEL: 0.20 x CT

Range: 0.25 to 25.00 A in steps of 0.01

Only shown if Ground Fault CT is 50:0.025

GROUND FAULT TRIP

LEVEL: 0.25 A

Range: 0 to 255.00 s in steps of 0.01

GROUND FAULT TRIP

DELAY: 0.00 s

Range: 50/60 Hz Nominal: Off, Latched, Unlatched

Variable: Off, Latched

GROUND FAULT TRIP

BACKUP: Off

Range: None, Aux1, Aux2, or combinations of them

ASSIGN G/F BACKUP

RELAYS: Aux2

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Range: 0.00 to 255.00 s in steps of 0.01

G/F TRIP BACKUP

DELAY: 0.20 s

Once the magnitude of ground current exceeds the Pickup Level for a period of time

specified by the Delay, a trip and/or alarm will occur. There is also a backup trip feature

that can be enabled. If the backup is On, and a Ground Fault trip has initiated, and the

ground current persists for a period of time that exceeds the backup delay, a second

‘backup’ trip will occur. It is intended that this second trip be assigned to Aux1 or Aux2

which would be dedicated as an upstream breaker trip relay. The Ground Fault Trip Backup

delay must be set to a time longer than the breaker clearing time.

Note

Care must be taken when turning On this feature. If the interrupting device (contactor

or circuit breaker) is not rated to break ground fault current (low resistance or solidly

grounded systems), the feature should be disabled. Alternately, the feature may be

assigned to an auxiliary relay and connected such that it trips an upstream device that

is capable of breaking the fault current.

Various situations (e.g. contactor bounce) may cause transient ground currents during

motor starting that may exceed the Ground Fault Pickup levels for a very short period of

time. The delay can be fine tuned to an application such that it still responds very fast, but

rides through normal operational disturbances. Normally, the Ground Fault time delays will

be set as quick as possible, 0 ms. Time may have to be increased if nuisance tripping

occurs.

Special care must be taken when the ground input is wired to the phase CTs in a residual

connection. When a motor starts, the starting current (typically 6 × FLA for an induction

motor) has an asymmetrical component. This asymmetrical current may cause one phase

to see as much as 1.6 times the normal RMS starting current. This momentary DC

component will cause each of the phase CTs to react differently and the net current into

the ground input of the 369 will not be negligible. A 20 ms block of the ground fault

elements when the motor starts enables the 369 to ride through this momentary ground

current signal.

Note

Both the main Ground Fault delay and the backup delay start timing when the Ground

Fault current exceeds the pickup level.

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S5 MOTOR START/INHIBITS

5.6 S5 Motor Start/Inhibits

5.6.1 Description

These setpoints deal with those functions that prevent the motor from restarting once

stopped until a set condition clears and/or a set time expires. None of these functions will

trip a motor that is already running.

5.6.2 Acceleration Trip

PATH: S5 MOTOR START/INHIBITS Ø ACCELERATION TRIP

Range: Off, Latched, Unlatched

ACCELERATION TRIP

ACCELERATION

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN TRIP RELAYS:

Trip

Range: 1.0 to 250.0 s in steps of 0.1

ACCELERATION TIME

FROM START: 10.0 s

The 369 Thermal Model is designed to protect the motor under both starting and overload

conditions. The Acceleration Timer trip feature may be used in addition to that protection.

If for example, the motor should always start in 2 seconds, but the safe stall time is 8

seconds, there is no point letting the motor remain in a stall condition for 7 or 8 seconds

when the thermal model would take it off line. Furthermore, the starting torque applied to

the driven equipment for that period of time could cause severe damage.

If enabled, the Acceleration Timer trip element will function as follows: A motor start is

assumed to be occurring when the 369 measures the transition of no motor current to

some value of motor current. Typically current will rise quickly to a value in excess of FLA

(e.g. 6 x FLA). At this point, the Acceleration Timer will be initialized with the entered value in

seconds. If the current does not fall below the overload curve pickup level before the timer

expires, an acceleration trip will occur. If the acceleration time of the motor is variable, this

feature should be set just beyond the longest acceleration time.

Note

Some motor soft starters may allow current to ramp up slowly while others may limit

current to less than Full Load Amps throughout the start. In these cases, as a generic

relay that must protect all motors, the 369 cannot differentiate between a motor that

has a slow ramp up time and one that has completed a start and gone into an overload

condition. Therefore, if the motor current does not rise to greater than full load within 1

second on start, the acceleration timer feature is ignored. In any case, the motor is still

protected by the overload curve.

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S5 MOTOR START/INHIBITS

CHAPTER 5: SETPOINTS

5.6.3 Start Inhibits

PATH: S5 MOTOR START/INHIBITS ØØ START INHIBITS

Range: No, Yes

START INHIBITS

ENABLE SINGLE SHOT

RESTART: No

ENABLE

START INHIBIT: No

Range: 1 to 5 in steps of 1, Off (0)

MAX STARTS/HOUR

PERMISSIBLE: Off

Range: 1 to 500 min. in steps of 1, Off (0)

Range: 1 to 50000 s in steps of 1, Off (0)

Range: None, Trip, Aux1, Aux2, or combinations

TIME BETWEEN STARTS

PERMISSIBLE: Off

RESTART BLOCK:

Off

ASSIGN BLOCK RELAY:

Trip & Aux2

The start inhibit setpoints are individually described below.

•

ENABLE SINGLE SHOT RESTART: Enabling this feature will allow the motor to be

restarted immediately after an overload trip has occurred. To accomplish this, a reset

will cause the 369 to decrease the accumulated thermal capacity to zero. However, if

a second overload trip occurs within one hour of the first, another immediate restart

will not be permitted. The displayed lockout time must then be allowed to expire

before the motor can be started.

•

ENABLE START INHIBIT: The Start Inhibit feature is intended to help prevent tripping of

the motor during a start if there is insufficient thermal capacity for a start. The

average value of thermal capacity used from the last five successful starts is

multiplied by 1.25 and stored as thermal capacity used on start. This 25% margin is

used to ensure that a motor start will be successful. If the number is greater than

100%, 100% is stored as thermal capacity used on start. A successful motor start is

one in which phase current rises from 0 to greater than overload pickup and then,

after acceleration, falls below the overload curve pickup level. If the Start Inhibit

feature is enabled, each time the motor is stopped, the amount of thermal capacity

available (100% – Thermal Capacity Used) is compared to the THERMAL CAPACITY

USED ON START. If the thermal capacity available does not exceed the THERMAL

CAPACITY USED ON START, or is not equal to 100%, the Start Inhibit will become

active until there is sufficient thermal capacity. When an inhibit occurs, the lockout

time will be equal to the time required for the motor to cool to an acceptable

temperature for a start. This time will be a function of the COOL TIME CONSTANT

STOPPED programmed. If this feature is turned Off, thermal capacity used must

reduce to 15% before an overload lockout resets. This feature should be turned off if

the load varies for different starts.

•

MAX STARTS/HOUR PERMISSIBLE: A motor start is assumed to be occurring when the

369 measures the transition of no motor current to some value of motor current. At

this point, one of the Starts/Hour timers is loaded with 60 minutes. Even unsuccessful

start attempts will be logged as starts for this feature. Once the motor is stopped, the

number of starts within the past hour is compared to the number of starts allowable. If

the two are the same, an inhibit will occur. If an inhibit occurs, the lockout time will be

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S5 MOTOR START/INHIBITS

equal to one hour less the longest time elapsed since a start within the past hour. An

Emergency restart will clear the oldest start time remaining.

•

TIME BETWEEN STARTS PERMISSIBLE: A motor start is assumed to be occurring when

the 369 measures the transition of no motor current to some value of motor current.

At this point, the Time Between Starts timer is loaded with the entered time. Even

unsuccessful start attempts will be logged as starts for this feature. Once the motor is

stopped, if the time elapsed since the most recent start is less than the TIME

BETWEEN STARTS PERMISSIBLE setpoint, an inhibit will occur. If an inhibit occurs,

the lockout time will be equal to the time elapsed since the most recent start

subtracted from the TIME BETWEEN STARTS PERMISSIBLE setpoint.

•

RESTART BLOCK: Restart Block may be used to ensure that a certain amount of time

passes between stopping a motor and restarting that motor. This timer feature may

be very useful for some process applications or motor considerations. If a motor is on

a down-hole pump, after the motor stops, the liquid may fall back down the pipe and

spin the rotor backwards. It would be very undesirable to start the motor at this time.

In another scenario, a motor may be driving a very high inertia load. Once the supply

to the motor is disconnected, the rotor may continue to turn for a long period of time

as it decelerates. The motor has now become a generator and applying supply

voltage out of phase may result in catastrophic failure.

•

ASSIGN BLOCK RELAY: The relay(s) assigned here will be used for all blocking/inhibit

elements in this section. The assigned relay will activate only when the motor is

stopped. When a block/inhibit condition times out or is cleared, the assigned relay will

automatically reset itself.

Notes For All Inhibits And Blocks:

1. In the event of control power loss, all lockout times will be saved. Elapsed time

will be recorded and decremented from the inhibit times whether control

power is applied or not. Upon control power being re-established to the 369,

all remaining inhibits (have not time out) will be re-activated.

2. If the motor is started while an inhibit is active an event titled ‘Start while

Blocked’ will be recorded.

5.6.4 Backspin Detection

PATH: S5 MOTOR START/INHIBITS ØØØ BACKSPIN DETECTION

Range: No, Yes

Only shown if B option installed

BACKSPIN DETECTION

ENABLE BACKSPIN

START INHIBIT: No

Range: 0 to 9.99 Hz in steps of 0.01

MINIMUM PERMISSIBLE

FREQUENCY: 0.00 Hz

Shown only if backspin start inhibit is enabled

Range: Disabled, Enabled

PREDICTION ALGORITHM

Enabled

Shown only if backspin start inhibit is enabled

Range: None, Trip, Aux1, Aux2, or combinations

Seen only if backspin start inhibit is enabled

ASSIGN BSD RELAY:

Aux2

Range: 2 to 16 in steps of 2

NUM OF MOTOR POLES:

Shown only if backspin start inhibit is enabled

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CHAPTER 5: SETPOINTS

Immediately after the motor is stopped, backspin detection commences and a backspin

start inhibit is activated to prevent the motor from being restarted. The backspin frequency

is sensed through the BSD voltage input. If the measured frequency is below the

programmed MINIMUM PERMISSIBLE FREQUENCY, the backspin start inhibit will be

removed. The time for the motor to reach the MINIMUM PERMISSIBLE FREQUENCY is

calculated throughout the backspin state. If the BSD frequency signal is lost prior to

reaching the Minimum Permissible Frequency, the inhibit remains active until the

prediction time has expired. The calculated Prediction Time and the Backspin State can be

viewed in Section 6.3.4 Backspin Metering on page 6–208.

Application:

Backspin protection is typically used on down hole pump motors which can be located

several kilometers underground. Check valves are often used to prevent flow reversal

when the pump stops. Very often however, the flow reverses due to faulty or non existent

check valves, causing the pump impeller to rotate the motor in the reverse direction.

Starting the motor during this period of reverse rotation (back-spinning) may result in

motor damage. Backspin detection ensures that the motor can only be started when the

motor has slowed to within acceptable limits. Without backspin detection a long time

delay had to be used as a start permissive to ensure the motor had slowed to a safe speed.

Note

These setpoints are only visible when option B has been installed.

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S6 RTD TEMPERATURE

5.7 S6 RTD Temperature

5.7.1 Description

These setpoints deal with the RTD overtemperature elements of the 369. The Local RTD

Protection setpoints will only be seen if the 369 has option R installed. The Remote RTD

Protection setpoints will only be seen if the 369 has the RRTD accessory enabled. Both can

be enabled and used at the same time and have the same functionality.

5.7.2 Local RTD Protection

PATH: S6 RTD TEMPERATURE Ø LOCAL RTD PROTECTION Ø LOCAL RTD 1(12)

Range: None, Stator, Bearing, Ambient, Other

LOCAL RTD 1

RTD 1 APPLICATION:

None

Range 10 Ohm Copper, 100 Ohm Nickel, 120 Ohm

Nickel, 100 Ohm Platinum.

RTD 1 TYPE:

100 Ohm Platinum

Range: 8 alphanumeric characters

RTD 1 NAME:

RTD 1

Range: Off, Latched, Unlatched

RTD 1 ALARM:

Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 1 to 200°C or 34 to 392°F in steps of 1

Range: Off, Latched, Unlatched

RTD 1 ALARM RELAYS:

Alarm

RTD 1 ALARM

LEVEL: 130°C

RTD 1 HI ALARM:

Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 1 to 200°C or 34 to 392°F in steps of 1

Range: No, Yes

RTD 1 HI ALARM

RELAYS: Aux1

RTD 1 HI ALARM

LEVEL: 130°C

RECORD RTD 1 ALARMS

AS EVENTS: No

Range: Off, Latched, Unlatched

RTD 1 TRIP:

Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 1 to 200°C or 34 to 392°F in steps of 1

Range: Off, RTD 1 to RTD12, All Stator

RTD 1 TRIP RELAYS:

Trip

RTD 1 TRIP

LEVEL: 130°C

ENABLE RTD 1 TRIP

VOTING: Off

Note

The above setpoints will only be shown if the RTD 1(12) APPLICATION setpoint is other

than “None”

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Note

RTD NAME can not be edited using front panel. EnerVista 369 Setup software should be

used to set the RTD NAME.

5.7.3 Remote RTD Protection

Main Menu

PATH: S6 RTD TEMPERATURE ØØ REMOTE RTD PROTECTN Ø REMOTE RTD

MODULE 1(4)

REMOTE RTD MODULE 1

RRTD 1 RTD1

RRTD 1 RTD2

See page 5–166

RRTD 1 RTD12

See page 5–166

Range: Off, On

RRTD 1 OPEN RTD

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: No, Yes

ASSIGN ALARM RELAYS:

Alarm

RRTD 1 OPEN RTD

EVENTS: No

Range: Off, On

RRTD 1 SHORT/LOW RTD

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: No, Yes

ASSIGN ALARM RELAYS:

Alarm

RRTD 1 SHORT/LOW RTD

EVENTS: No

These setpoints are applicable for units with a GE Multilin Remote RTD module.

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S6 RTD TEMPERATURE

Remote RTD 1(12)

PATH: S6 RTD TEMPERATURE ØØ REMOTE RTD PROTECTN Ø REMOTE RTD

MODULE 1(4) ØØ RRTD 1 RTD 1(12)

Range: None, Stator, Bearing, Ambient, Other

RRTD 1 RTD # 1

RTD 1 APPLICATION:

None

Range: 10 Ohm Copper, 100 Ohm Nickel, 120 Ohm

Nickel, 100 Ohm Platinum

RRTD 1 RTD1 TYPE:

100 Ohm Platinum

Range: 8 character alphanumeric. Seen only if RRTD 1

APPLICATION is other than “None”

RRTD 1 RTD1 NAME:

RRTD1

Range: Off, Latched, Unlatched. Seen only if RRTD 1

APPLICATION is other than “None”

RRTD 1 RTD1 ALARM:

Off

Range: None, Alarm, Aux1, Aux2, or combinations.

Seen only if RRTD 1 APPLICATION is not “None”

RRTD 1 RTD1 ALARM

RELAYS: Alarm

Range: 1 to 200°C or 34 to 392°F in steps of 1. Seen

only if RRTD 1 APPLICATION is other than

RRTD 1 RTD1 ALARM

LEVEL: 130 °C

Range: Off, Latched, Unlatched. Seen only if RRTD 1

APPLICATION is other than “None”.

RRTD 1 RTD1 HI

ALARM:

Range: None, Alarm, Aux1, Aux2, or combinations.

Seen only if RRTD 1 APPLICATION is not “None”.

RRTD1 RTD1 HI ALARM

RELAY: Aux1

Range: 1 to 200°C or 34 to 392°F in steps of 1. Seen

only if RRTD 1 APPLICATION is other than

RRTD 1 RTD1 HI ALARM

LEVEL: 130 °C

Range: No, Yes. Seen only if RRTD 1 APPLICATION is

other than “None”.

RRTD 1 RTD1 ALARMS

AS EVENTS: No

Range: Off, Latched, Unlatched. Seen only if RRTD 1

APPLICATION is other than “None”.

RRTD 1 RTD1 TRIP:

Off

Range: None, Trip, Aux1, Aux2, or combinations. Seen

only if RRTD 1 APPLICATION is not “None”.

RRTD 1 RTD1 TRIP

RELAYS: Trip

Range: 1 to 200°C or 34 to 392°F in steps of 1. Seen

only if RRTD 1 APPLICATION is other than

RRTD 1 RTD1 TRIP

LEVEL: 130 °C

Range: Off, RRTD 1 to 12, All Stator. Seen only if RRTD 1

APPLICATION is other than “None”

RRTD 1 RTD1 TRIP

VOTING: Off

•

RTD 1(12) APPLICATION: Each individual RTD may be assigned an application. A

setting of “None” turns an individual RTD off. Only RTDs with the application set to

“Stator” are used for RTD biasing of the thermal model. If an RTD application is set to

“Ambient”, then its is used in calculating the learned cool time of the motor.

•

RTD 1(12) TYPE: Each RTD is individually assigned the RTD type it is connected to.

Multiple types may be used with a single 369.

RTD 1(12) NAME: Each RTD may have 8 character name assigned to it. This name is

used in alarm and trip messages.

RTD NAME can not be edited using front panel. EnerVista 369 Setup software should

be used to set the RTD NAME.

•

RTD 1(12) ALARM, RTD 1(12) HI ALARM, and RTD 1(12) TRIP: Each RTD can be

programmed for separate Alarm, Hi Alarm and Trip levels and relays. Trips are

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automatically stored as events. Alarms and Hi Alarms are stored as events only if the

Record Alarms as Events setpoint for that RTD is set to Yes.

•

RTD 1(12) TRIP VOTING: This feature provides added RTD trip reliability in situations

where malfunction and nuisance tripping is common. If enabled, the RTD trips only if

the RTD (or RTDs) to be voted with are also above their trip level. For example, if RTD 1

is set to vote with All Stator RTDs, the 369 will only trip if RTD 1 is above its trip level and

any one of the other stator RTDs is also above its own trip level. RTD voting is typically

only used on Stator RTDs and typically done between adjacent RTDs to detect hot

spots.

Stator RTDs can detect heating due to non overload (current) conditions such as blocked or

inadequate cooling and ventilation or high ambient temperature as well as heating due to

overload conditions. Bearing or other RTDs can detect overheating of bearings or auxiliary

equipment.

Table 5–2: Rtd Resistance to Temperature

TEMPERATU

RTD RESISTANCE (IN OHMS)

120 Ohm Ni 100 Ohm Ni

92.76 79.13

°C

°F

100 Ohm Pt

DIN 43760

10 Ohm Cu

7.49

–40

–30

–20

–10

–40

–22

–4

84.27

88.22

99.41

84.15

89.23

94.58

100.0

105.6

111.2

117.1

123.0

129.1

135.3

141.7

148.3

154.9

161.8

168.8

176.0

183.3

190.9

198.7

206.6

214.8

223.2

231.6

240.0

7.88

92.16

106.15

113.00

120.00

127.17

134.52

142.06

149.79

157.74

165.90

174.25

182.84

191.64

200.64

209.85

219.29

228.96

238.85

248.95

259.30

269.91

280.77

291.96

303.46

8.26

96.09

8.65

100.00

103.90

107.79

111.67

115.54

119.39

123.24

127.07

130.89

134.70

138.50

142.29

146.06

149.82

153.58

157.32

161.04

164.76

168.47

172.46

175.84

9.04

9.42

9.81

10.19

10.58

10.97

11.35

11.74

12.12

12.51

12.90

13.28

13.67

14.06

14.44

14.83

15.22

15.61

16.00

16.39

16.78

104

122

140

158

176

194

212

230

248

266

284

302

320

338

356

374

392

100

110

120

130

140

150

160

170

180

190

200

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S6 RTD TEMPERATURE

5.7.4 Open RTD Alarm

PATH: S6 RTD TEMPERATURE ØØØ OPEN LOCAL RTD ALARM

Range: Off, Latched, Unlatched

Range: None, Alarm, Aux1, Aux2, or combinations

Range: No, Yes

OPEN LOCAL RTD ALARM

OPEN LOCAL RTD

ALARM: Off

ASSIGN ALARM RELAYS:

Alarm

OPEN RTD ALARM

EVENTS: No

The 369 has an Open RTD Sensor Alarm. This alarm will look at all RTDs that have been

assigned an application other than “None” and determine if an RTD connection has been

broken. When a broken sensor is detected, the assigned output relay will operate and a

message will appear on the display identifying the RTD that is broken. It is recommended

that if this feature is used, the alarm be programmed as latched so that intermittent RTDs

are detected and corrective action may be taken.

5.7.5 Short/Low Temp RTD Alarm

PATH: S6 RTD TEMPERATURE ØØØØ SHORT/LOW RTD ALARM

Range: Off, Latched, Unlatched

Range: None, Alarm, Aux1, Aux2, or combinations

Range: No, Yes

SHORT/LOW RTD ALARM

SHORT/LOW TEMP RTD

ALARM: Off

ASSIGN ALARM RELAYS:

Alarm

SHORT/LOW TEMP ALARM

EVENTS: No

The 369 has an RTD Short/Low Temperature alarm. This function tracks all RTDs that have

an application other than “None” to determine if an RTD has either a short or a very low

temperature (less than –40°C). When a short/low temperature is detected, the assigned

output relay will operate and a message will appear on the display identifying the RTD that

caused the alarm. It is recommended that if this feature is used, the alarm be programmed

as latched so that intermittent RTDs are detected and corrective action may be taken.

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5.7.6 Loss of RRTD Comms Alarm

PATH: S6 RTD TEMPERATURE ØØØØØ LOSS OF RRTD COMMS

Range: Off, Latched, Unlatched

Range: None, Alarm, Aux1, Aux2, or combinations

Range: No, Yes

LOSS OF RRTD COMMS

ALARM: OFF

ASSIGN ALARM RELAYS:

Alarm

LOSS OF RRTD COMMS

EVENTS: No

The 369, if connected to a RRTD module, will monitor communications between them. If for

some reason communications is lost or interrupted the 369 can issue an alarm indicating

the failure. This feature is useful to ensure that the remote RTDs are continuously being

monitored.

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S7 VOLTAGE ELEMENTS

5.8 S7 Voltage Elements

5.8.1 Description

These elements are not used by the 369 unless the M or B option is installed and the VT

CONNECTION TYPE setpoint (see Section 5.3.2: CT/VT Setup on page –122) is set to

something other than “None”.

5.8.2 Undervoltage

PATH: S7 VOLTAGE ELEMENTS Ø UNDERVOLTAGE

Range: No, Yes

UNDERVOLTAGE

U/V ACTIVE IF MOTOR

STOPPED: No

Range: Off, Latched, Unlatched

UNDERVOLTAGE

ALARM: Off

Range: None, Alarm, Aux1, Aux2 or combinations

Range: 0.50 to 0.99 x RATED in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

STARTING U/V ALARM

PICKUP: 0.85xRATED

RUNNING U/V ALARM

PICKUP: 0.85xRATED

UNDERVOLTAGE ALARM

DELAY: 3.0 S

UNDERVOLTAGE ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

UNDERVOLTAGE

TRIP: Off

Range: None, Trip, Aux1, Aux2 or combinations

Range: 0.50 to 0.99 x RATED in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

STARTING U/V TRIP

PICKUP: 0.80xRATED

RUNNING U/V TRIP

PICKUP: 0.80xRATED

UNDERVOLTAGE TRIP

DELAY: 1.0s

If enabled, an undervoltage trip or alarm occurs once the magnitude of either Vab, Vbc, or

Vca falls below the running pickup level while running or the starting pickup level while

starting, for a period of time specified by the alarm or trip delay (pickup levels are multiples

of motor nameplate voltage).

An undervoltage on a running motor with a constant load results in increased current. The

relay thermal model typically picks up this condition and provides adequate protection.

However, this setpoint may be used in conjunction with time delay to provide additional

protection that may be programmed for advance warning by tripping.

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The U/V ACTIVE IF MOTOR STOPPED setpoint may be used to prevent nuisance alarms

or trips when the motor is stopped. If "No" is programmed the undervoltage element will be

blocked from operating whenever the motor is stopped (no phase current and starter

status indicates breaker or contactor open). If the load is high inertia, it may be desirable to

ensure that the motor is tripped off line or prevented from starting in the event of a total

loss or decrease in line voltage. Programming "Yes" for the block setpoint will ensure that

the motor is tripped and may be restarted only after the bus is re-energized.

A typical application of this feature is with an undervoltage of significant proportion that

persists while starting a synchronous motor which may prevent it from coming up to rated

speed within the rated time. This undervoltage may be an indication of a system fault. To

protect a synchronous motor from being restarted while out of step it may be necessary to

use undervoltage to take the motor offline before a reclose is attempted.

5.8.3 Overvoltage

PATH: S7 VOLTAGE ELEMENTS ØØ OVERVOLTAGE

Range: Off, Latched, Unlatched

OVERVOLTAGE

ALARM: Off

Range: None, Alarm, Aux1, Aux2 or combinations

Range: 1.01 to 1.25 x RATED in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

OVERVOLTAGE ALARM

PICKUP: 1.05xRATED

OVERVOLTAGE ALARM

DELAY: 3.0s

OVERVOLTAGE ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

OVERVOLTAGE

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 1.01 to 1.25 x RATED in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

OVERVOLTAGE TRIP

PICKUP: 1.10xRATED

OVERVOLTAGE TRIP

DELAY: 1.0s

If enabled, once the magnitude of either Vab, Vbc, or Vca rises above the Pickup Level for a

period of time specified by the Delay, a trip or alarm will occur (pickup levels are multiples

of motor nameplate voltage).

An overvoltage on running motor with a constant load will result in decreased current.

However, iron and copper losses increase, causing an increase in motor temperature. The

current overload relay will not pickup this condition and provide adequate protection.

Therefore, the overvoltage element may be useful for protecting the motor in the event of

a sustained overvoltage condition.

Note

The Undervoltage and Overvoltage alarms and trips are activated based upon the

phase to phase voltage regardless of the VT connection type.

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S7 VOLTAGE ELEMENTS

5.8.4 Phase Reversal

PATH: S7 VOLTAGE ELEMENTS ØØØ PHASE REVERSAL

Range: Off, Latched, Unlatched

PHASE REVERSAL

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

ASSIGN TRIP RELAYS:

Trip

The 369 Relay can detect reversed phases on the motor. When enabled, this element

detects the phase sequence of both the three-phase voltages and the three-phase

currents as measured by the relay. If the measured three-phase voltages are greater than

50% of the motor rated voltage the Phase Reversal element will ignore the currents and

perform only voltage phase reversal detection.

If the three-phase voltages are not greater than 50% of the motor rated voltage, or

voltages are not available on relay terminals, the Phase reversal element will be activated

after the measured currents are above 5% of the motor FLA. When the Two-speed Motor

feature is enabled, and Speed 1 is active, the Phase Reversal element will be activated

when currents are greater than 5% FLA of the Speed 1 FLA setpoint. When Speed 2 is

active, the Phase Reversal element will be activated after the currents become greater

than 5% FLA of the Speed 2 FLA setpoint.

The element detects the phase reversal condition within 500-700ms and will issue a trip

and block the motor start.

The setting of the phase sequence under S2 SYSTEM SETUP/ CT/VT SETUP/SYSTEM

PHASE SEQUENCE should match the phase sequence of the three-phase voltages

measured on the relay terminals. For Two-Speed Motor applications, the setting under S2

SYSTEM SETUP/ CT/VT SETUP/SYSTEM PHASE SEQUENCE should match the phase

sequence of the currents measured by the relay terminals when in Speed 1.

If the Two-Speed Motor feature is used for Forward and Reverse motor applications, the

setting of the phase sequence under S2 SYSTEM SETUP/CT/VT SETUP/SPEED2

SYSTEM PHASE SEQUENCE will be opposite to the setting of the phase sequence under

S2 SYSTEM SETUP/ CT/VT SETUP/SYSTEM PHASE SEQUENCE.

When the voltage phase reversal detection is active, the phase rotation of the measured

voltages is compared only to S2 SYSTEM SETUP/ CT/VT SETUP/SYSTEM PHASE

SEQUENCE setting, whether the Two-Speed Motor feature is enabled or not.

Note

If the two-speed feature is used for Forward/Reverse motor applications, the phase

sequence of VT input to the 369 and the SYSTEM PHASE SEQUENCE setpoint in the 369

relay must match the phase sequence required for Forward rotation of the motor. For

correct operation of Phase Reversal trip, the phase sequence of the VT input connections

should not be altered in reverse rotation of the motor.

When the phase reversal detection based on currents is active, the phase rotation of the

measured currents is compared to S2 SYSTEM SETUP/ CT/VT SETUP/SYSTEM PHASE

SEQUENCE setting when in Speed 1, and to S2 SYSTEM SETUP/CT/VT SETUP/SPEED2

SYSTEM PHASE SEQUENCE, when in Speed 2.

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START

Phase reversal protection

enabled?

Yes

Vab > 50% rated &

Vbc>50% rated &

Vca> 50% rated

Two speed protection

enabled?

Yes

Speed 1

Speed 2

Speed S/W

status?

Is measured voltage phase

sequence =Set SYSTEM

PHASE SEQUENCE?

Ia > 5% FLA &

Ib> 5% FLA &

Ic> 5% FLA

Ia > 5% FLA2&

Ib> 5% FLA2 &

Ic> 5% FLA2

Yes

Is measured current phase

sequence =Set SYSTEM

PHASE SEQUENCE?

Is measured current phase

sequence =Set SPEED2

PHASE SEQUENCE?

Yes

Issue Phase Reversal Trip

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5.8.5 Underfrequency

PATH: S7 VOLTAGE ELEMENTS ØØØØ UNDERFREQUENCY

Range: 0 to 5000 s in steps of 1

UNDERFREQUENCY

BLOCK UNDERFREQUENCY

FROM START:

Range: Off, Latched, Unlatched

UNDERFREQUENCY

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 20.00 to 70.00 Hz in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

UNDERFREQUENCY ALARM

LEVEL: 59.50 Hz

UNDERFREQUENCY ALARM

DELAY: 1.0s

UNDERFREQUENCY ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

UNDERFREQUENCY

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 20.00 to 70.00 Hz in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

UNDERFREQUENCY TRIP

LEVEL: 59.50 Hz

UNDERFREQUENCY TRIP

DELAY: 1.0s

Once the frequency of the phase AN or AB voltage (depending on wye or delta connection)

falls below the underfrequency pickup level, a trip or alarm will occur.

This feature may be useful for load shedding applications on large motors. It could also be

used to load shed an entire feeder if the trip was assigned to an upstream breaker.

Underfrequency can also be used to detect loss of power to a synchronous motor. Due to

motor generation, sustained voltage may prevent quick detection of power loss. Therefore,

to quickly detect the loss of system power, the decaying frequency of the generated

voltage as the motor slows can be used.

The Underfrequency element is not active when the motor is stopped.

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5.8.6 Overfrequency

PATH: S7 VOLTAGE ELEMENTS ØØØØØ OVERFREQUENCY

Range: 0 to 5000 s in steps of 1

OVERFREQUENCY

BLOCK OVERFREQUENCY

FROM START: 1 s

Range: Off, Latched, Unlatched

OVERFREQUENCY

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 20.00 to 70.00 Hz in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

OVERFREQUENCY ALARM

LEVEL: 60.50 Hz

OVERFREQUENCY ALARM

DELAY: 1.0s

OVERFREQUENCY ALARM

EVENTS: Off

Range: Off, Latched, Unlatched

OVERFREQUENCY

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 20.00 to 70.00 Hz in steps of 0.01

Range: 0.0 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

OVERFREQUENCY TRIP

LEVEL: 60.50 Hz

OVERFREQUENCY TRIP

DELAY: 1.0s

Once the frequency of the phase AN or AB voltage (depending on wye or delta connection)

rises above the overfrequency pickup level, a trip or alarm will occur.

This feature may be useful for load shedding applications on large motors. It could also be

used to load shed an entire feeder if the trip was assigned to an upstream breaker.

The Overfrequency element is not active when the motor is stopped.

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5.9 S8 Power Elements

5.9.1 Description

These protective elements rely on CTs and VTs being installed and setpoints programmed.

The power elements are only used if the 369 has option M or B installed. By convention, an

induction motor consumes Watts and vars. This condition is displayed on the 369 as

+Watts and +vars. A synchronous motor can consume Watts and vars or consume Watts

and generate vars. These conditions are displayed on the 369 as +Watts, +vars, and

+Watts, –vars respectively.

FIGURE 5–12: Power Measurement Conventions

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In Two-Speed Motor protection involving Forward/Reverse motor application, in motor

reverse direction the phase sequence of the three-phase voltage input is corrected

internally for the purpose of power metering. The following power elements may not

perform correctly if the phase sequence of the three-phase voltages measured by the relay

is different than the SYSTEM PHASE SEQUENCE setting:

•

LAG POWER FACTOR

POSITIVE REACTIVE POWER

NEGATIVE REACTIVE POWER

UNDERPOWER

REVERSE POWER

5.9.2 Lead Power Factor

PATH: S8 POWER ELEMENTS Ø LEAD POWER FACTOR

Range: 0 to 5000 s in steps of 1

LEAD POWER FACTOR

BLOCK LEAD PF

FROM START: 1 s

Range: Off, Latched, Unlatched

LEAD POWER FACTOR

ALARM: Off

Range: None, Alarm, Aux1, Aux2 or combinations

Range: 0.05 to 0.99 in steps of 0.01

Range: 0.1 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

LEAD POWER FACTOR

ALARM LEVEL: 0.30

LEAD POWER FACTOR

ALARM DELAY: 1.0s

LEAD POWER FACTOR

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

LEAD POWER FACTOR

TRIP: Off

Range: None, Trip, Aux1, Aux2 or combinations

Range: 0.05 to 0.99 in steps of 0.01

Range: 0.1 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

LEAD POWER FACTOR

TRIP LEVEL: 0.30

LEAD POWER FACTOR

TRIP DELAY: 1.0s

If the 369 is applied on a synchronous motor, it is desirable not to trip or alarm on power

factor until the field has been applied. Therefore, this feature can be blocked until the

motor comes up to speed and the field is applied. From that point forward, the power

factor trip and alarm elements will be active. Once the power factor is less than the lead

level, for the specified delay, a trip or alarm will occur indicating a lead condition.

The lead power factor alarm can be used to detect over-excitation or loss of load.

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5.9.3 Lag Power Factor

PATH: S8 POWER ELEMENTS ØØ LAG POWER FACTOR

Range: 0 to 5000 s in steps of 1

LAG POWER FACTOR

BLOCK LAG PF

FROM START: 1 s

Range: Off, Latched, Unlatched

LAG POWER FACTOR

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 0.05 to 0.99 in steps of 0.01

Range: 0.1 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

LAG POWER FACTOR

ALARM LEVEL: 0.85

LAG POWER FACTOR

ALARM DELAY: 1.0s

LAG POWER FACTOR

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

LAG POWER FACTOR

TRIP: Off

Range: None, Trip, Aux1, Aux2 or combinations

Range: 0.05 to 0.99 in steps of 0.01

Range: 0.1 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

LAG POWER FACTOR

TRIP LEVEL: 0.80

LAG POWER FACTOR

TRIP DELAY: 1.0s

If the 369 is applied on a synchronous motor, it is desirable not to trip or alarm on power

factor until the field has been applied. Therefore, this feature can be blocked until the

motor comes up to speed and the field is applied. From that point forward, the power

factor trip and alarm elements will be active. Once the power factor is less than the lag

level, for the specified delay, a trip or alarm will occur indicating lag condition.

The power factor alarm can be used to detect loss of excitation and out of step for a

synchronous motor.

5.9.4 Positive Reactive Power

PATH: S8 POWER ELEMENTS ØØØ POSITIVE REACTIVE POWER

Range: 0 to 5000 s in steps of 1

POSITIVE REACTIVE

POWER (kvar)

BLOCK +kvar ELEMENT

FROM START: 1 s

Range: Off, Latched, Unlatched

POSITIVE kvar

ALARM: Off

Range: None, Alarm, Aux1, Aux2 or combinations

Range: 1 to 25000 kvar in steps of 1

Range: 0.1 to 255.0 s in steps of 0.1

ASSIGN ALARM RELAYS:

Alarm

POSITIVE kvar ALARM

LEVEL: 10 kvar

POSITIVE kvar

ALARM DELAY: 1.0 s

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Range: Off, On

POSITIVE kvar

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

POSITIVE kvar

TRIP:

Range: None, Trip, Aux1, Aux2 or combinations

Range: 1 to 25000 kvar in steps of 1

Range: 0.1 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

POSITIVE kvar TRIP

LEVEL: 25 kvar

POSITIVE kvar

TRIP DELAY: 1.0 s

If the 369 is applied on a synchronous motor, it is desirable not to trip or alarm on kvar until

the field has been applied. Therefore, this feature can be blocked until the motor comes up

to speed and the field is applied. From that point forward, the kvar trip and alarm elements

will be active. Once the kvar level exceeds the positive level, for the specified delay, a trip or

alarm will occur indicating a positive kvar condition. The reactive power alarm can be used

to detect loss of excitation and out of step.

5.9.5 Negative Reactive Power

PATH: S8 POWER ELEMENTS ØØØØ NEGATIVE REACTIVE POWER

Range: 0 to 5000 s in steps of 1

NEGATIVE REACTIVE

POWER (kvar)

BLOCK -kvar ELEMENT

FROM START: 1 s

Range: Off, Latched, Unlatched

NEGATIVE kvar

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations

Range: 1 to 25000 kvar in steps of 1

Range: 0.1 to 255.0 s in steps of 0.1

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

NEGATIVE kvar ALARM

LEVEL: 10 kvar

NEGATIVE kvar

ALARM DELAY: 1.0 s

NEGATIVE kvar

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

NEGATIVE kvar

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 1 to 25000 kvar in steps of 1

Range: 0.1 to 255.0 s in steps of 0.1

ASSIGN TRIP RELAYS:

Trip

NEGATIVE kvar TRIP

LEVEL: 25 kvar

NEGATIVE kvar

TRIP DELAY: 1.0s

When using the 369 on a synchronous motor, it is desirable not to trip or alarm on kvar

until the field has been applied. As such, this feature can be blocked until the motor comes

up to speed and the field is applied. From that point forward, the kvar trip and alarm

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elements will be active. Once the kvar level exceeds the negative level for the specified

delay, a trip or alarm occurs, indicating a negative kvar condition. The reactive power

alarm can be used to detect overexcitation or loss of load.

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5.9.6 Underpower

PATH: S8 POWER ELEMENTS ØØØØØ UNDERPOWER

Range: 0 to 15000 s in steps of 1

UNDERPOWER

BLOCK UNDERPOWER

FROM START: 1 s

Range: Off, Latched, Unlatched

UNDERPOWER

ALARM: Off

Range: None, Alarm, Aux1, Aux2 or combinations

Range: 1 to 25000 kW in steps of 1

Range: 0.5 to 255.0 s in steps of 0.5

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

UNDERPOWER ALARM

LEVEL: 2 kW

UNDERPOWER

ALARM DELAY: 1 s

UNDERPOWER

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

UNDERPOWER

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 1 to 25000 kW in steps of 1

Range: 0.5 to 255.0 s in steps of 0.5

ASSIGN TRIP RELAYS:

Trip

UNDERPOWER TRIP

LEVEL: 1 kW

UNDERPOWER

TRIP DELAY: 1 s

If enabled, a trip or alarm occurs when the magnitude of three-phase total real power falls

below the pickup level for a period of time specified by the delay. The underpower element

is active only when the motor is running and will be blocked upon the initiation of a motor

start for a period of time defined by the BLOCK UNDERPOWER FROM START setpoint

(e.g. this block may be used to allow pumps to build up head before the underpower

element trips or alarms). A value of 0 means the feature is not blocked from start;

otherwise the feature is disabled when the motor is stopped and also from the time a start

is detected until the time entered expires. The pickup level should be set lower than motor

loading during normal operations.

Underpower may be used to detect loss of load conditions. Loss of load conditions will not

always cause a significant loss of current. Power is a more accurate representation of

loading and may be used for more sensitive detection of load loss or pump cavitation. This

may be especially useful for detecting process related problems.

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5.9.7 Reverse Power

PATH: S8 POWER ELEMENTS ØØØØØØ REVERSE POWER

Range: 0 to 50000 s in steps of 1

REVERSE POWER

BLOCK REVERSE POWER

FROM START: 1 s

Range: Off, Latched, Unlatched

REVERSE POWER

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combination

Range: 1 to 25000 kW in steps of 1

Range: 0.5 to 30.0 s in steps of 0.5

Range: Off, On

ASSIGN ALARM RELAYS:

Alarm

REVERSE POWER ALARM

LEVEL: 1 kW

REVERSE POWER

ALARM DELAY: 1.0 s

REVERSE POWER

ALARM EVENTS: Off

Range: Off, Latched, Unlatched

REVERSE POWER

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations

Range: 1 to 25000 kW in steps of 1

Range: 0.5 to 30 s in steps of 0.5

ASSIGN TRIP RELAYS:

Trip

REVERSE POWER TRIP

LEVEL: 1 kW

REVERSE POWER

TRIP DELAY: 1.0 s

If enabled, once the magnitude of three-phase total real power exceeds the pickup level in

the reverse direction (negative kW) for a period of time specified by the delay, a trip or

alarm will occur.

Note

The minimum power measurement magnitude is determined by the phase CT

minimum of 5% rated CT primary. If the reverse power level is set below this, a trip or

alarm will only occur once the phase current exceeds the 5% cutoff.

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5.10 S9 Digital Inputs

5.10.1 Digital Input Functions

Description

Any of the digital inputs may be selected and programmed as a separate General Switch,

Digital Counter, or Waveform Capture Input. The xxxxx term in the following menus refers

to the configurable switch input function – either the Spare Switch, Emergency Restart,

Differential Switch, Speed Switch, or Remote Reset inputs described in the following

sections.

General

Range: 12 character alphanumeric

xxxxx SW FUNCTION:

General

GENERAL SWITCH

NAME: General

Only seen if function is selected as General

Range: NO (normally open), NC (normally closed)

Only seen if function is selected as General

GENERAL SWITCH

TYPE: NO

MESSAGE

Range: 0 to 5000 s in steps of 1

BLOCK INPUT FROM

START: 0 s

Only seen if function is selected as General

Range: Off, Latched, Unlatched

GENERAL SWITCH

ALARM: Off

Only seen if function is selected as General

Range: None, Alarm, Aux1, Aux2, or combinations

Only seen if function is selected as General

ASSIGN ALARM RELAYS:

Alarm

Range: 0.1 to 5000.0 s in steps of 0.1

GENERAL SWITCH

ALARM DELAY: 5.0 s

Only seen if function is selected as General

Range: No, Yes

RECORD ALARMS AS

EVENTS: No

Only seen if function is selected as General

Range: Off, Latched, Unlatched

GENERAL SWITCH

TRIP: Off

Only seen if function is selected as General

Range: None, Trip, Aux1, Aux2, or combinations

Only seen if function is selected as General

ASSIGN TRIP RELAYS:

Trip

Range: 0.1 to 5000.0 s in steps of 0.1

GENERAL SWITCH

TRIP DELAY: 5.0 s

Only seen if function is selected as General

Note

GENERAL SWITCH NAME can not be edited using front panel. EnerVista 369 Setup software

should be used to set the GENERAL SWITCH NAME.

The above selections will be shown if the in the corresponding menu if SPARE SW

FUNCTION, EMERGENCY FUNCTION, DIFF SW FUNCTION, or SPEED SW

FUNCTION setpoints are set to “General”. Refer to the individual sections for Spare Switch,

Emergency Restart, Differential Switch, Speed Switch, or Remote Reset below for

additional function-specific setpoints.

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Digital Counter

Range: 8 character alphanumeric

xxxxx SW FUNCTION:

Digital Counter

COUNTER

NAME: Counter

Only seen if function is Digital Counter

Range: 6 character alphanumeric

COUNTER

UNITS: Units

MESSAGE

Only seen if function is Digital Counter

Range: Increment, Decrement

COUNTER

TYPE: Increment

MESSAGE

Only seen if function is Digital Counter

Range: Off, Latched, Unlatched

DIGITAL COUNTER

ALARM: Off

Only seen if function is Digital Counter

Range: None, Alarm, Aux1, Aux2, or combinations.

Only seen if function is Digital Counter

ASSIGN ALARM RELAYS:

Alarm

Range: 0 to 65535 in steps of 1

COUNTER ALARM LEVEL:

100

Only seen if function is Digital Counter

Range: No, Yes

RECORD ALARMS AS

EVENTS: No

Only seen if function is Digital Counter

The above selections will be shown if the SPARE SW FUNCTION, EMERGENCY

FUNCTION, DIFF SW FUNCTION, or SPEED SW FUNCTION setpoints are set to “Digital

Counter”. Refer to the individual sections for Spare Switch, Emergency Restart, Differential

Switch, Speed Switch, or Remote Reset below for additional function-specific setpoints.

Only one digital input may be selected as a digital counter at a time. User defined units

and counter name may be defined and these will appear on all counter related actual

value and alarm messages. To clear a digital counter alarm, the alarm level must be

increased or the counter must be cleared or preset to a lower value.

Waveform Capture

The Waveform Capture setting for the digital inputs allows the 369 to capture a waveform

upon command (contact closure). The captured waveforms can then be displayed via the

EnerVista 369 Setup program.

DeviceNet Control

This function is available for the DeviceNet option only. The digital input set with the

DeviceNet control function and the switch status closed allows motor start, motor stop,

and fault reset commands through DeviceNet communications.

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5.10.2 Spare Switch

PATH: S9 DIGITAL INPUTS Ø SPARE SWITCH

Range: Off, Starter Status, General, Digital Counter,

Waveform Capture, DeviceNet Control

SPARE SWITCH

SPARE SW FUNCTION:

Off

Range: 52a, 52b

STARTER AUX CONTACT

TYPE: 52a

MESSAGE

Only seen if FUNCTION is "Starter Status"

Range: OFF, 0 to 60 s in steps of 1

STARTER OPERATION

MONITOR DELAY: 3 s

Only seen if FUNCTION is “Starter Status”

Range: Off, Latched, Unlatched. Only seen if SPARE

STARTER OPERATION

TYPE: Off

SW FUNCTION is “Starter Status” and

STARTER OPERATION MONITOR

Range: None, Trip, Alarm, Aux1, Aux2, or combinations.

ASSIGN RELAYS:

None

Only seen if SPARE SW FUNCTION is

“Starter Status” and STARTER

OPERATION MONITOR DELAY is not

“Off”.

See Section 5.10.1: Digital Input Functions for an explanation of the spare switch functions.

It is recommended that the auxiliary contact from the main breaker for starter status

monitoring is wired to the Spare Switch digital input terminals 51 and 52 for the following

reasons:

•

To avoid undesired operation of START/INHIBIT elements during speed switching.

To ensure applying the SPEED2 ACCEL. TIMER FROM 1-2, when switched from

Speed 1 to Speed 2. If the breaker status is not monitored , the 369 relay may detect

MOTOR STOPPED status, and apply ACCEL. TIMER FROM START, when

switching to Speed 2.

•

To ensure Learned values such as Learned Starting Thermal Capacity, Learned

Starting Current, and Learned Acceleration Time, are correctly calculated irrespective

of speed switching.

In addition to regular selections, the Spare Switch may be used as a starter status contact

input. An auxiliary ‘52a’ type contact follows the state of the main contactor or breaker

and an auxiliary ‘52b’ type contact is in the opposite state. This feature is recommended

for use on all motors. It is essential for proper operation of start inhibits (i.e., starts/hour,

time between starts, start inhibit, restart block, backspin start inhibit), especially when the

motor may be run lightly or unloaded.

A motor stop condition is detected when the current falls below 5% of CT. When SPARE

SWITCH is programmed as “Starter Status”, motor stop conditions are detected when the

current falls below 5% of CT and the breaker is open. Enabling the Starter Status and

wiring the breaker contactor to the Spare Switch eliminates nuisance lockouts initiated by

the 369 if the motor (synchronous or induction) is running unloaded or idling, and if the

STARTS/HOUR, TIME BETWEEN STARTS, START INHIBIT, RESTART BLOCK, and

BACKSPIN START INHIBIT are programmed.

In addition, there may be applications where current is briefly present after the breaker is

opened on a motor stop (for example, discharge from power factor correction capacitors).

In such a case, the 369 will detect this current as an additional start. To prevent this from

occurring, the STARTER OPERATION MONITOR DELAY setpoint is used. If this setpoint

is programmed to any value other than “OFF”, a motor start is logged only if current above

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5% of the CT is present and the breaker is closed (for an “52a” type contact). If the breaker

is open (for an “52a” type contact) and the current above 5% of CT is present for longer

than the STARTER OPERATION MONITOR DELAY time, then a trip or alarm will occur

(according to the relay settings). If the trip relay is assigned under the ASSIGN RELAYS

setpoint, then a trip will occur and a trip event will be recorded; otherwise, an alarm will

occur and an alarm event recorded. If the STARTER OPERATION MONITOR DELAY is

“OFF”, this functionality will be disabled.

Note

The Access switch is predefined and is non programmable.

5.10.3 Emergency Restart

PATH: S9 DIGITAL INPUTS ØØ EMERGENCY RESTART

Range: Off, Emergency Restart, General, Digital

EMERGENCY RESTART

EMERGENCY FUNCTION:

Emergency Restart

Counter, Waveform Capture, DeviceNet

Control, Speed Switch

1.Shown only if two-speed motor protection is enabled

See Section 5.10.1: Digital Input Functions on page –184 for an explanation of the

emergency restart functions. In addition to the normal selections, the Emergency Restart

Switch may be used as a emergency restart input to the 369 to override protection for the

motor.

When the emergency restart switch is closed all trip and alarm functions are reset.

Thermal capacity used is set to zero and all protective elements are disabled until the

switch is opened. Starts per hour are also reduced by one each time the switch is closed.

Range: 0.5 to 100.0 seconds in steps of 0.5 s

Only seen if FUNCTION is "Speed Switch"

SPEED SWITCH TIME

DELAY: 2.0 s

Range: None, Trip, Aux1, Aux 2, or combinations

Only seen if FUNCTION is "Speed Switch"

SPEED SW TRIP RELAY:

Trip

Refer to 5.10.5: Speed Switch for setting details. The Speed switch function uses the input

from terminals 55-56, but applies different Speed Switch Time Delays for Speed 1 and

Speed 2. Refer to section 5.13.4: Speed 2 Acceleration for the Speed 2 Speed Switch time

delay setting

5.10.4 Differential Switch

PATH: S9 DIGITAL INPUTS ØØØ DIFFERENTIAL SWITCH

Range: Off, Differential Switch, General, Digital

DIFFERENTIAL SWITCH

DIFF SW FUNCTION:

Differential Switch

Counter, Waveform Capture, DeviceNet

Control, Speed Switch .

Range: None, Trip, Aux1, Aux2 or combinations

DIFF SW TRIP RELAY:

Trip

Only seen if FUNCTION is "Differential Switch".

1.Shown only if two-speed motor protection is enabled

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See Section 5.10.1: Digital Input Functions on page –184 for an explanation of differential

switch functions. In addition to the normal selections, the Differential Switch may be used

as a contact input for a separate external 86 (differential trip) relay. Contact closure will

cause the 369 relay to issue a differential trip.

Range: 0.5 to 100.0 seconds in steps of 0.5 s

Only seen if FUCTION is "Speed Switch"

SPEED SWITCH TIME

DELAY: 2.0 s

Range: None, Trip, Aux1, Aux 2, or combinations

Only seen if FUNCTION is "Speed Switch"

SPEED SW TRIP RELAY:

Trip

Refer to 5.10.5: Speed Switch for setting details. The Speed switch function uses the input

from terminals 55-56, but applies different Speed Switch Time Delays for Speed 1 and

Speed 2. Refer to section 5.13.4: Speed 2 Acceleration for the Speed 2 Speed Switch time

delay setting

5.10.5 Speed Switch

PATH: S9 DIGITAL INPUTS ØØØØ SPEED SWITCH

Range: Off, Speed Switch, General, Digital Counter,

SPEED SWITCH

SPEED SW FUNCTION:

Speed Switch

Waveform Capture, DeviceNet Control

Range: 0.5 to 100.0s in steps of 0.5

SPEED SWITCH TIME

DELAY: 2.0s

Only seen if FUNCTION is "Speed Switch"

Range: None, Trip, Aux1, Aux2 or combinations

Only seen if FUNCTION is "Speed Switch"

SPEED SW TRIP RELAY:

Trip

See Section 5.10.1: Digital Input Functions for an explanation of Speed Switch functions. In

addition to the normal selections, the Speed Switch may be used as an input for an

external Speed Switch. This allows the 369 to utilize a speed device for locked rotor

protection. During a motor start, if no contact closure occurs within the programmed time

delay, a trip will occur. The speed input must be opened for a Speed Switch trip to be reset

SPEED SWITCH

SPEED SW FUNCTION:

Two Speed Monitor

Upon enabling the 2-speed motor application (ENABLE TWO-SPEED MOTOR = Yes), this

input is no longer programmable but signifies the motor speed at any given time. “Open” is

recognized as Speed 1, and “closed” is recognized as Speed 2. The Speed Switch (terminals

55-56) is automatically designated for two-speed motor protection and will display

message “Two Speed Monitor”. Under this application, the switch cannot be assigned to

perform any other function.

The 369 relay monitors the following five stages of the motor: “Stopped”, “Starting”,

“Running”, “Overload”, and “Tripped”. Flow chart on status detection for single speed motor

application is found under APPLICATIONS/MOTOR STATUS DETECTION chapter of

this manual.

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S9 DIGITAL INPUTS

To determine the status of the two-speed motor when switching in Speed 1, Speed 2,

Speed 1-2, or from Speed 2-1, the relay uses the following information: Breaker status –

auxiliary contact wired to relay’s Spare Switch terminals 51-52, output from motor’s

Speed 2 contactor wired to Speed Switch terminals 55-56, and motor phase currents.

For motor status detection when switching from start in Speed 2, refer to chapter 7.6.1

Motor Status Detection which outlines the motor status, when switching from start in

Speed 1.

By maintaining breaker “closed”, and motor status RUNNING in Speed 1, switching from

Speed 1 to Speed 2 will not change the status of the motor. The relay will still show status

RUNNING, even when during speed switching, both Speed 1 and Speed 2 contactors are

open, and the motor current is below 5% of the CT primary set for Speed 1. Upon detection

of Speed Switch contact input “closed”, the relay applies the Speed 2 settings for CT

primary and FLA. The SPEED2 ACCEL TIMER FROM START and ACCEL TIMER FROM

SPEED 1-2 start upon detection of Speed Switch status “closed”.

5.10.6 Remote Reset

PATH: S9 DIGITAL INPUTS ØØØØØ REMOTE RESET

Range: Off, Remote Reset, General, Digital Counter,

REMOTE RESET

REMOTE SW FUNCTION:

Remote Reset

Waveform Capture, DeviceNet Control, Speed

Switch

1.Shown only if two-speed motor protection is enabled.

See the following section for an explanation of remote reset functions. In addition to the

normal selections, the Remote Reset may be used as a contact input to reset the relay.

Range: 0.5 to 100.0 seconds in steps of 0.5 s

Only seen if FUNCTION is "Speed Switch"

SPEED SWITCH TIME

DELAY: 2.0 s

Range: None, Trip, Aux1, Aux 2, or combinations

Only seen if FUNCTION is "Speed Switch"

SPEED SW TRIP RELAY:

Trip

Refer to 5.10.5: Speed Switch for setting details. The Speed switch function uses the input

from terminals 55-56, but applies different Speed Switch Time Delays for Speed 1 and

Speed 2. Refer to section 5.13.4: Speed 2 Acceleration for the Speed 2 Speed Switch time

delay setting

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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S10 ANALOG OUTPUTS

CHAPTER 5: SETPOINTS

5.11 S10 Analog Outputs

5.11.1 Analog Outputs

PATH: S10 ANALOG OUTPUTS Ø ANALOG OUTPUT 1(4)

Range: Disabled, Enabled

ANALOG OUTPUT 1

ANALOG OUTPUT 1:

DISABLED

Range: 0–1mA, 0–20 mA, 4–20 mA

ANALOG OUTPUT 1

RANGE: 0-1 mA

Range: See Analog Output selection table

ANALOG OUTPUT 1:

Phase A Current

ANALOG OUTPUT 1

MIN: 0 A

ANALOG OUTPUT 1

MAX: 100 A

The analog output parameters are indicated in the following table:

Table 5–3: Analog Output Parameters

PARAMETER

NAME

RANGE /UNITS

STE

DEFAULT

MINIMU

MAXIMU

Phase A Current

Phase B Current

Phase C Current

Avg. Phase Current

AB Line Voltage

BC Line Voltage

CA Line Voltage

Avg. Line Voltage

Phase AN Voltage

Phase BN Voltage

Phase CN Voltage

Avg. Phase Voltage

0 to 65535 A

100

0 to 65535 A

0 to 65000 V

100

3200

1900

4500

2500

–40 to +200°C or

–40 to +392°F

Hottest Stator RTD

200

–40 to +200°C or

RTD #1 to 12

Power Factor

–40

200

–40 to +392°F

–0.99 to 1.00

0.01

0.80

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S10 ANALOG OUTPUTS

Table 5–3: Analog Output Parameters

PARAMETER

NAME

RANGE /UNITS

STE

DEFAULT

MINIMU

MAXIMU

Reactive Power

Real Power

–32000 to 32000 kvar

–32000 to 32000 kW

0 to 65000 kVA

750

1000

1250

Apparent Power

Thermal Capacity

Used

0 to 100%

100

Relay Lockout Time

Motor Load

0 to 999 minutes

0.00 to 20.00 x FLA

0 to 65535 MWhrs

150

0.01

0.00

1.25

MWhrs

65535

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S11 369 TESTING

CHAPTER 5: SETPOINTS

5.12 S11 369 Testing

5.12.1 Test Output Relays

PATH: S11 369 TESTING Ø TEST OUTPUT RELAYS

Range: Disabled, Energized, De-energized

TEST OUTPUT RELAYS

FORCE TRIP RELAY:

Disabled

Range: Static, 1 to 300 s in steps of 1

Range: Disabled, Energized, De-energized

Range: Static, 1 to 300 s in steps of 1

Range: Disabled, Energized, De-energized

Range: Static, 1 to 300 s in steps of 1

Range: Disabled, Energized, De-energized

Range: Static, 1 to 300 s in steps of 1

FORCE TRIP RELAY

DURATION: Static

FORCE AUX1 RELAY:

Disabled

FORCE AUX1 RELAY

DURATION: Static

FORCE AUX2 RELAY:

Disabled

FORCE AUX2 RELAY:

DURATION: Static

FORCE ALARM RELAY:

Disabled

FORCE ALARM RELAY

DURATION: Static

The Test Output Relay feature provides a method of performing checks on all relay contact

outputs. This feature is not meant for control purposes during operation of the motor. For

control purposes, the force output relays functionality (refer to Force Output Relays on

page 5–139) is used.

The forced state, if enabled (energized or de-energized), forces the selected relay into the

programmed state for as long as the programmed duration. After the programmed

duration expires, the forced relay will return to it's non-forced physical state. The 369 will

continue to remain in Test Mode until the "Force Relay" setpoint has been set back to

"Disabled" for any relays being tested. If the duration is programmed as Static, the forced

state will remain in effect until changed or disabled. If control power to the 369 is

interrupted, any forced relay condition will be removed.

When the relays in this feature are programmed to any value other than “Disabled”, the In

Service LED on the front panel will turn on. The provides notification that the relay is not

currently operating in a normal condition.

Note

The OUTPUT STATUS LED on the front display panel of the 369 is lit when the respective

output relay is in an energized state.

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CHAPTER 5: SETPOINTS

S11 369 TESTING

5.12.2 Test Analog Outputs

PATH: S11 369 TESTING ØØ TEST ANALOG OUTPUTS

Range: Off, 1 to 100% in steps of 1

TEST ANALOG OUTPUTS

FORCE ANALOG

OUTPUT 1: Off

Range: Off, 1 to 100% in steps of 1

FORCE ANALOG

OUTPUT 2: Off

Range: Off, 1 to 100% in steps of 1

FORCE ANALOG

OUTPUT 3: Off

FORCE ANALOG

OUTPUT 4: Off

The Test Analog Output setpoints may be used during startup or testing to verify that the

analog outputs are functioning correctly. It may also be used when the motor is running to

give manual or communication control of an analog output. Forcing an analog output

overrides its normal functionality.

When the Force Analog Outputs Function is enabled, the output will reflect the forced value

as a percentage of the range 4 to 20 mA, 0 to 20 mA, or 0 to 1 mA. Selecting Off will place

the analog output channels back in service, reflecting the parameters programmed to

each.

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S12 TWO-SPEED MOTOR

CHAPTER 5: SETPOINTS

5.13 S12 Two-speed Motor

5.13.1 Description

The two-speed motor feature provides adequate protection for a two-speed motor. This

assumes the following values can differ between the two speeds: SPEED SWITCH status,

CT primary, motor FLA, and the phase sequence. The relay accommodates these

differences in the following protection functions: THERMAL MODEL, OVERLOAD

CURVES, OVERLOAD ALARM, SHORT CIRCUIT, MECHANICAL JAM,

UNDERCURRENT, CURRENT UNBALANCE, and ACCELERATION TRIP.

In order to utilize this feature the digital inputs signifying motor energization (breaker) and

speed are wired as explained under SETPOINTS/S9 DIGITAL INPUT FUNCTIONS

chapter of this manual. Also, the enable setpoint for this function under SYSTEM SETUP /

CT/VT SETUP/ENABLE 2-SPEED MOTOR is set to “Yes’, and the fundamental motor

parameters as referring to Speeds 1 and 2 are programmed under SYSTEM SETUP / CT/

VT SETUP.

The Speed 2 settings are provided under the following extra menu and share the same

function settings, that is under Speed 2. A given function will respond the same way as

under Speed 1.

See page 5–194

S12 SETPOINTS

SPEED2 O/L CURVES

TWO-SPEED MOTOR

See page 5–196

See page 5–197

SPEED2 UNDERCURRENT

SPEED2 ACCELERATION

The relay allows for separate settings of the three listed features independently for Speed 1

and Speed 2. Note that the Speed 1 settings are provided under:

S3 OVERLOAD PROTECTION/THERMAL MODEL with setting of overload pickup level

corresponding to the FLA of Speed 1.

S3 OVERLOAD PROTECTION/OVERLOAD CURVE with selection of curve type

corresponding to Speed 1 thermal overload,

S4 CURRENT ELEMENTS/UNDERCURRENT with settings for undercurrent alarm and

trip expressed in times FLA of Speed 1, and

S5 MOTOR START/INHIBIT/ACCELERATION TRIP setting of the acceleration timer

from start referring to start in Speed 1.

5.13.2 Speed 2 Overload Curves

PATH: S12 TWO-SPEED MOTOR ØSPEED2 O/L CURVES

Range: 1 to 15 in steps of 1

SPEED2 O/L CURVES

SPEED2 STANDARD

CURVE NUMBER: 1

Only seen if CURVE STYLE is Standard

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.01xFLA: 17415s

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S12 TWO-SPEED MOTOR

Range: 0 to 65534 s in steps of 1

SPEED2 TIME TRIP AT

1.05xFLA: 3415 s

Only seen if CURVE STYLE is Custom

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.10xFLA: 1667 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.20xFLA: 795 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.30xFLA: 507 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.40xFLA: 365 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.50xFLA: 280 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

1.75xFLA: 170 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

2.00xFLA: 117 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

2.25xFLA: 86 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

2.50xFLA: 67 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

2.75xFLA: 53 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

3.00xFLA: 44 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

3.25xFLA: 37 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

3.50xFLA: 31 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

3.75xFLA: 27 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

4.00xFLA: 23 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

4.25xFLA: 21 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

4.50xFLA: 18 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

4.75xFLA: 16 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

5.00xFLA: 15 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

5.50xFLA: 12 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

6.00xFLA: 10 s

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S12 TWO-SPEED MOTOR

CHAPTER 5: SETPOINTS

Range: 0 to 65534 s in steps of 1

SPEED2 TIME TRIP AT

6.50xFLA: 9 s

Only seen if CURVE STYLE is Custom

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

7.00xFLA: 7 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

7.50xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

8.00xFLA: 6 S

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

10.0xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

15.0xFLA: 6 s

Range: 0 to 65534 s in steps of 1

Only seen if CURVE STYLE is Custom

SPEED2 TIME TRIP AT

20.0xFLA: 6 s

The overload curve selection for Speed 2 is done identically to the selection for Speed 1 or

regular single-speed applications as described under S3 OVERLOAD PROTECTION

chapter of the manual. The function setting for Speed 1 found under S3 OVERLOAD

PROTECTION controls the response of the thermal protection under Speed 2 as well.

Note that the relay will apply individual CT primary setting, individual FLA and potentially

different curve for Speeds 1 and 2. This creates enough flexibility (degrees of freedom) to

accommodate the 2-speed applications in a natural way without an awkward

workarounds. Note that the thermal model integrates the thermal capacity continuously

when switching between the speeds and thus potentially different CT primaries, FLAs and

curves.

Note

When two speed motor protection is selected and used for Forward/Reverse motor

rotation, it is required that switching between the speeds goes through a stage of no

current (motor slows down or stops). Then it is followed by a start in the opposite direction.

Switching in opposite direction, while motor is running is not recommended.

5.13.3 Speed 2 Undercurrent

PATH: S12 TWO-SPEED MOTOR ØSPEED2 UNDERCURRENT

Range: 0 to 15000 seconds in steps of 1

SPEED2 UNDERCURRENT

BLOCK SPEED2 U/C

FROM START: 0 S

Range: Off, Latched, Unlatched

SPEED2 U/C

ALARM: Off

Range: None, Alarm, Aux1, Aux2, or combinations of

them

ASSIGN SPEED2 U/C

RELAYS: Alarm

Range: 0.10 to 0.99 x FLA in steps of 1

Range: 1 to 255 seconds in steps of 1

Range: On, Off

SPEED2 U/C ALARM:

LEVEL: 0.70 x FLA

SPEED2 U/C ALARM:

DELAY: 1 s

SPEED2 U/C ALARM

EVENTS: Off

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S12 TWO-SPEED MOTOR

Range: Off, Latched, Unlatched

SPEED2 U/C

TRIP: Off

Range: None, Trip, Aux1, Aux2, or combinations of

them

ASSIGN SPEED2 U/C

RELAYS: Trip

Range: 0.10 to 0.99 x FLA in steps of 1

Range: 1 to 255 seconds in steps of 1

SPEED2 U/C TRIP

LEVEL: 0.70 X FLA

SPEED2 U/C TRIP

DELAY: 1 s

The SPEED2 UNDERCURRENT protection is a separate protection for Speed 2, and has

the same menu structure as the undercurrent protection for Speed 1 under S4 CURRENT

ELEMENTS/ UNDERCURRENT. This protection is enabled when the setting under S2

SYSTEM SETUP /CT/VT SETUP/ENABLE 2-SPEED MOTOR PROTECTION is

programmed as “Yes,” and the physical DIGITAL INPUTS/SPEED SWITCH =1(closed).

When in Speed 2, the 369 will detect undercurrent conditions and initiate an alarm if any

phase current drops below the SPEED2 U/C ALARM LEVEL setting for the time delay

selected under SPEED2 U/C ALARM DELAY.

A trip will be initiated if the level of any phase current drops below the SPEED2 U/C TRIP

LEVEL for the time delay selected under SPEED2 U/C TRIP DELAY time delay.

Additionally, SPEED2 UNDERCURRENT protection can be blocked during start in Speed

2, when selecting a time delay under BLOCK SPEED2 U/C FROM START. The timer starts

timing out when the motor status as detected by the 369 changes from "Stopped" to

"Starting."

Note that a motor status of “Stopped” will also be detected by the 369 during the switching

from Speed 1 to Speed 2 if the status of the breaker is detected as “open” and the motor

current drops below 5% of SPEED2 CT primary setting.

When switching from Speed 2 to Speed 1 (Speed Switch status detected as “open”), the

SPEED2 UNDERCURRENT protection becomes inactive and the Speed 1 undercurrent

protection found under S4 CURRENT ELEMENTS / UNDERCURRENT is then used by

the 369.

5.13.4 Speed 2 Acceleration

PATH: S12 TWO-SPEED MOTOR ØSPEED2 ACCELERATION

Range: 2.0 to 250.0 seconds in steps of 0.1 s

SPEED2 ACCELERATION

SPEED2 ACCEL. TIMER

FROM START: 10 S

Range: 2.0 to 250.0 seconds in steps of 0. 1 s

Range: 0.5 to 100.0 seconds in steps of 0.5 s

ACCEL. TIMER FROM

SPEED1 - 2: 10 s

SPEED SW SPEED2 TIME

DELAY: 2.0 s

The timer SPEED2 ACCEL. TIMER FROM START will start timing out, when the previous

status of the motor was detected “STOPPED," the status of the Speed Switch contact is

detected close (Speed 2), or the starting current is above 5%CT setting for Speed 2.

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S12 TWO-SPEED MOTOR

CHAPTER 5: SETPOINTS

The timer ACCEL. TIMER FROM SPEED1-2 will start timing out, when the previous

status of the motor was detected “RUNNING”, or “OVERLOAD”, and the Speed Switch

contact is detected closed (Speed 2),

The 369 relay will ignore any Mechanical Jam during the transition from Speed 1 to Speed

2, until the motor current drops below Speed 2 Overload PKP setting, or during the time of

Speed1-2 acceleration timer. At that point the Mechanical Jam feature will be enabled with

Speed 2 FLA.

When using the Two Speed Motor feature in a Forward/Reverse motor rotation application,

switching between speeds will result in a state with no current (motor slows down to a

stop) followed by a start in the opposite direction. In this application, the ACCEL. TIMER

FROM SPEED1-2 could be programmed with the same value as SPEED2 ACCEL. TIMER

FROM START.

The SPEED SW SPEED2 TIME DELAY setting is available only if the “SPEED SWITCH”

function is assigned to one of the DIGITAL INPUTS under setpoints S9 DIGITAL INPUTS.

SPEED2 ACCEL. TIMER FROM START and ACCEL. TIMER FROM SPEED1-2 become

functional only if the acceleration time at Speed 1 (see S5 section 5.6.2: Acceleration Trip) is

enabled.

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Digital Energy

Multilin

369 Motor Management Relay

Chapter 6: Actual Values

Actual Values

6.1 Overview

6.1.1 Actual Values Main Menu

A1 ACTUAL VALUES

STATUS

MOTOR STATUS

LAST TRIP DATA

DATA LOGGER

DIAGNOSTIC MESSAGES

START BLOCK STATUS

DIGITAL INPUT STATUS

OUTPUT RELAY STATUS

REAL TIME CLOCK

FIELDBUS SPEC STATUS

A2 ACTUAL VALUES

METERING DATA

CURRENT METERING

See page 6–207

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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OVERVIEW

CHAPTER 6: ACTUAL VALUES

VOLTAGE METERING

POWER METERING

BACKSPIN METERING

LOCAL RTD

REMOTE RTD

OVERALL STATOR RTD

DEMAND METERING

PHASORS

A3 ACTUAL VALUES

LEARNED DATA

MOTOR DATA

See page 6–213

See page 6–214

See page 6–215

LOCAL RTD MAXIMUMS

REMOTE RTD MAXIMUMS

A4 ACTUAL VALUES

STATISTICAL DATA

TRIP COUNTERS

See page 6–216

See page 6–217

MOTOR STATISTICS

A5 ACTUAL VALUES

EVENT RECORD

EVENT: 512

EVENT: 511

See page 6–219

EVENT: 2

EVENT: 1

A6 ACTUAL VALUES

RELAY INFORMATION

MODEL INFORMATION

See page 6–220

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CHAPTER 6: ACTUAL VALUES

OVERVIEW

FIRMWARE VERSION

See page 6–220

1.Only shown if option M or B is installed

2.Only shown if option R is installed

3.Only shown if Channel 3 Application is programmmed as RRTD

4.Only shown if option R is installed or Channel 3 Application is programmmed as RRTD

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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A1 STATUS

CHAPTER 6: ACTUAL VALUES

6.2 A1 Status

6.2.1 Motor Status

PATH: A1 STATUS Ø MOTOR STATUS

Range: Stopped, Starting, Running, Overload, Tripped

Range: 0 to 100% in steps of 1

MOTOR STATUS

MOTOR STATUS:

Stopped

MOTOR THERMAL

CAPACITY USED: 0%

Range: Never, 0 to 65500 s in steps of 1

ESTIMATED TRIP TIME

ON OVERLOAD: Never

Range: Low Speed, High Speed

Only shown if "Enable 2-Speed Motor Protection" is

enabled.

MOTOR SPEED:

Low Speed

These messages describe the status of the motor at the current point in time. The Motor

Status message indicates the current state of the motor.

MOTOR STATE

Stopped

DEFINITION

phase current = 0 A and starter status input = breaker/contactor

open

motor previously stopped and phase current has gone from 0 to >

FLA

Starting

Running

FLA > phase current > 0 or starter status input = breaker/

contactor closed and motor was previously running

Overload

Tripped

motor previously running and phase current now > FLA

a trip has been issued and not cleared

The Motor Thermal Capacity Used message indicates the current level which is used by the

overload and cooling algorithms. The Estimated Trip Time On Overload is only active for

the Overload motor status.

Note

In Forward/Reverse motor applications, MOTOR SPEED is indicated as "Low Speed" for

Forward rotation, and "High Speed" for Reverse rotation of motor.

6.2.2 Last Trip Data

PATH: A1 STATUS ØØ LAST TRIP DATA

Range: No Trip to Date, cause of trip

Range: hour: min: seconds

Range: month day year

LAST TRIP DATA

CAUSE OF LAST TRIP:

No Trip to date

LAST TRIP

TIME: 00:00:00

LAST TRIP

DATE: Feb 28 2007

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CHAPTER 6: ACTUAL VALUES

A1 STATUS

Range: Not Programmed, Low Speed, High Speed

Range: 0 to 100000 A in steps of 1

SPEED OF LAST TRIP:

Low Speed

A: 0

C: 0

B: 0

A Pretrip

Range: 0.00 to 20.00 in steps of 0.01

Range: 0 to 100% in steps of 1

MOTOR LOAD

Pretrip 0.00 x FLA

CURRENT UNBALANCE

Pretrip: 0%

Range: 0.0 to 5000.0 Amps in steps of 0.1

GROUND CURRENT

Pretrip: 0.0 Amps

Range: Local, RRTD1, RRTD2, RRTD3, RRTD4

No RTD = open, Shorted = shorted RTD

–40 to 200°C or –40 to 392°F

HOTTEST STATOR RTD:

Local RTD: 12 76°C

Range: 0 to 20000 in steps of 1

Vab: 0 Vbc: 0

Vca: 0 V Pretrip

Only shown if VT CONNECTION is programmed

Range: 0 to 20000 in steps of 1

Van: 0 Vbn: 0

Vcn: 0 V Pretrip

Only shown if VT CONNECTION is "Wye"

Range: 0.00, 15.00 to 120.00 in steps of 0.01

Only shown if VT CONNECTION is programmed

SYSTEM FREQUENCY

Pretrip: 0.00 Hz

Range: –50000 to +50000 in steps of 1

0 kW 0 kVA

0 kvar Pretrip

Only shown if VT CONNECTION is programmed

Range: 0.00 lag to 1 to 0.00 lead

POWER FACTOR

Pretrip: 1.00

Only shown if VT CONNECTION is programmed

Immediately prior to a trip, the 369 takes a snapshot of the metered parameters along

with the cause of trip and the date and time and stores this as pre-trip values. This allows

for ease of troubleshooting when a trip occurs. Instantaneous trips on starting (< 50 ms)

may not allow all values to be captured. These values are overwritten when the next trip

occurs. The event record shows details of the last 40 events including trips.

6.2.3 Data Logger

PATH: ACTUAL VALUE Ø A1 ACTUAL VALUES STATUS ØØ DATA LOGGER

Line 1 Range: Stopped, Running

Line 2 Range: 0 to 100%

Log Status: Running

Memory Used: 100%

DATA LOGGER

6.2.4 Diagnostic Messages

PATH: A1 STATUS ØØØ DIAGNOSTIC MESSAGES

Range: No Trips or Alarms are Active, active

alarm name and level, active trip name

DIAGNOSTIC MESSAGES

No Trips or Alarms

are Active

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A1 STATUS

CHAPTER 6: ACTUAL VALUES

Any active trips or alarms may be viewed here. If there is more than one active trip or

alarm, using the Line Up and Down keys will cycle through all the active alarm messages. If

the Line Up and Down keys are not pressed, the active messages will automatically cycle.

The current level causing the alarm is displayed along with the alarm name.

6.2.5 Start Block Status

PATH: A1 STATUS ØØØØ START BLOCK STATUS

Range: 1 to 9999 min. in steps of 1

START BLOCK STATUS

OVERLOAD LOCKOUT

TIMER: None

Range: 1 to 500 min. in steps of 1

Range: 1 to 60 min. in steps of 1

Range: 1 to 500 min. in steps of 1

Range: 1 to 50000 s in steps of 1

START INHIBIT

TIMER: None

STARTS/HOUR TIMERS:

0 0 0 0 0 min

TIME BETWEEN STARTS

TIMER: None

RESTART BLOCK TIMER:

None

•

OVERLOAD LOCKOUT TIMER: Determined from the thermal model, this is the

remaining amount of time left before the thermal capacity available will be sufficient

to allow another start and the start inhibit will be removed.

START INHIBIT TIMER: If enabled this timer will indicate the remaining time for the

Thermal Capacity to reduce to a level to allow for a safe start according to the Start

Inhibit setpoints.

STARTS/HOUR TIMER: If enabled this display will indicate the number of starts within

the last hour by showing the time remaining in each. The oldest start will be on the

left. Once the time of one start reaches 0, it is no longer considered a start within the

hour and is removed from the display and any remaining starts are shifted over to the

left.

•

TIME BETWEEN STARTS TIMER: If enabled this timer will indicate the remaining time

from the last start before the start inhibit will be removed and another start may be

attempted. This time is measure from the beginning of the last motor start.

RESTART BLOCK TIMER: If enabled this display will reflect the amount of time since the

last motor stop before the start block will be removed and another start may be

attempted.

6.2.6 Digital Input Status

PATH: A1 STATUS ØØØØØ DIGITAL INPUT STATUS

Range: Open, Closed

Note: Programmed input name displayed

DIGITAL INPUT STATUS

EMERGENCY RESTART:

Open

Range: Open, Closed

DIFFERENTIAL RELAY:

Open

Note: Programmed input name displayed

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A1 STATUS

Range: Open, Closed

Note: Programmed input name displayed

SPEED SWITCH:

Open

Range: Open, Closed

Note: Programmed input name displayed

RESET:

Open

Range: Open, Closed

Note: Programmed input name displayed

ACCESS:

Open

Range: Open, Closed

Note: Programmed input name displayed

SPARE:

Open

The present state of the digital inputs will be displayed here.

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A1 STATUS

CHAPTER 6: ACTUAL VALUES

6.2.7 Output Relay Status

PATH: A1 STATUS ØØØØØØ OUTPUT RELAY STATUS

Range: Energized, De–energized

OUTPUT RELAY STATUS

TRIP: De–energized

ALARM: De–energized

AUX 1: De–energized

AUX 2: De–energized

Range: Energized, De–energized

The present state of the output relays will be displayed here. Energized indicates that the

NO contacts are now closed and the NC contacts are now open. De-energized indicates

that the NO contacts are now open and the NC contacts are now closed.

6.2.8 Real Time Clock

PATH: A1 STATUS ØØØØØØØ REAL TIME CLOCK

Range: month/day/year, hour: minute: second

REAL TIME CLOCK

DATE: 02/28/2007

TIME: 00:00:00

The date and time from the 369 real time clock may be viewed here.

6.2.9 FieldBus Specification Status

PATH: A1 STATUS ØØØØØØØØ FIELDBUS SPEC STATUS

Range: Nonexistent, Configuring, Established,

FIELDBUS SPEC STATUS

EXPLICIT STATUS:

Nonexistent

Timed Out, Deleted

Range: Nonexistent, Configuring, Established,

Timed Out, Deleted

IO POLLED STATUS:

Nonexistent

Range: Power Off/Not Online, Online/Connected,

Link Failure

NETWORK STATUS:

Power Off/Not Online

Note

When the device is on the non-connected bus, the NETWORK STATUS message will

continually cycle between “Power Off/Not Online” and “Online/Connected”.

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A2 METERING DATA

6.3 A2 Metering Data

6.3.1 Current Metering

PATH: A2 METERING DATA Ø CURRENT METERING

Range: 0 to 65535 A in steps of 1

CURRENT METERING

A: 0

C: 0

B: 0

Amps

Range: 0 to 65535 A in steps of 1

Range: 0.00 to 20.00 x FLA in steps of 0.01

Range: 0 to 100% in steps of 1

AVERAGE PHASE

CURRENT: 0 Amps

MOTOR LOAD:

0.00 X FLA

CURRENT UNBALANCE:

Range: 0.00 to 20.00 x FLA in steps of 0.01. Only visible

if unbalance biasing is enabled in thermal

U/B BIASED MOTOR

LOAD: 0.00 x FLA

Range: 0 to 6553.5 A in steps of 0.1 (for 1A/5A CT)

0.00 to 25.00 A in steps of 0.01 (for

50:0.025 A CT)

GROUND CURRENT:

0.0 Amps

All measured current values are displayed here. Note that the unbalance level is de-rated

below FLA. See the unbalance setpoints in Section 5.4.2 Thermal Model on page 5–142 for

more details.

6.3.2 Voltage Metering

PATH: A2 METERING DATA ØØ VOLTAGE METERING

Range: 0 to 65535 V in steps of 1

VOLTAGE METERING

Vab: 0

Vca: 0

Vbc: 0

V RMS φ-φ

Only shown if VT CONNECTION is programmed

Range: 0 to 65535 V in steps of 1

AVERAGE LINE

VOLTAGE: 0 V

Only shown if VT CONNECTION is programmed

Range: 0 to 65535 V in steps of 1

Va: 0

Vc: 0

Vb: 0

V RMS φ-N

Only shown if a Wye connection programmed

Range: 0 to 65535 V in steps of 1

AVERAGE PHASE

VOLTAGE: 0 V

Only shown if a Wye connection programmed

Range: 0.00, 15.00 to 120.00 Hz in steps of 0.01

SYSTEM FREQUENCY:

0.00 Hz

Measured voltage parameters will be displayed here. These displays are only visible if

option M or B has been installed.

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CHAPTER 6: ACTUAL VALUES

6.3.3 Power Metering

PATH: A2 METERING DATA ØØØ POWER METERING

Range: 0.00 to 1.00 lag or lead

POWER METERING

POWER FACTOR:

1.00

Range: –32000 to 32000 kW in steps of 1

REAL POWER:

0 kW

Range: 0 to 42912 hp in steps of 1

REAL POWER:

0 hp

Range: –32000 to 32000 kvar in steps of 1

Range: 0 to 65000 kVA in steps of 1

REACTIVE POWER:

0 kvar

APPARENT POWER:

0 kVA

Range: 0 to 65535 MWh or 0 to 999 kWh in steps of 1

POSITIVE WATTHOURS:

0 MWh

Range: 0 to 65535 Mvarh or 0 to 999 kvarh in steps of

POSITIVE VARHOURS:

0 Mvarh

Range: 0 to 65535 Mvarh or 0 to 999 kvarh in steps of

NEGATIVE VARHOURS:

0 Mvarh

These actual values are only shown if the VT CONNECTION TYPE setpoint has been

programmed (i.e., is not set to “None”). The values for three phase power metering,

consumption and generation are displayed here. The energy values displayed here will be

in units of MWh/Mvarh or kWh/kvarh, depending on the S1 369 SETUP Ö DISPLAY

PREFERENCES ÖØ ENERGY UNIT DISPLAY setpoint. The energy registers will roll over

to zero and continue accumulating once their respective maximums have been reached.

The MWh/Mvarh registers will continue accumulating after their corresponding kWh/kvarh

registers have rolled over. The actual energy is a summation of both the kilo and Mega

values.

These displays are only visible if option M or B has been installed.

6.3.4 Backspin Metering

PATH: A2 METERING DATA ØØØØ BACKSPIN METERING

Range: Low Signal, 1 to 120 Hz in steps of 0.01

BACKSPIN METERING

BACKSPIN FREQUENCY:

Low Signal

Only shown if option B installed and enabled.

Range: Motor Running, No Backspin, Slowdown,

Acceleration, Backspinning, Prediction, Soon to

Restart. Seen only if Backspin Start Inhibit is

enabled

BACKSPIN DETECTION

STATE:

Range: 0 to 50000 s in steps of 1.

BACKSPIN PREDICTION

TIMER:30 s

Shown only if Backspin Start Inhibit is enabled

and predication timer is enabled.

Backspin metering parameters are displayed here. These values are shown if option B has

been installed and the ENABLE BACKSPIN START INHIBIT setting is “Yes”.

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A2 METERING DATA

6.3.5 Local RTD

PATH: A2 METERING DATA ØØØØØ LOCAL RTD

Range: None, 1 to 12 in steps of 1

LOCAL RTD

HOTTEST STATOR RTD

NUMBER: 1

Range: –40 to 200°C or –40 to 392°F

HOTTEST STATOR RTD

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #1

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #2

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #12

TEMPERATURE: 40°C

The temperature level of all 12 internal RTDs are displayed here if the 369 has option R

enabled. The programmed name of each RTD (if changed from the default) appears as the

first line of each message. These displays are only visible if option R has been installed.

6.3.6 Remote RTD

PATH: A2 METERING DATA ØØØØØØ REMOTE RTD Ø REMOTE RTD MODULE 1(4)

Range: None, 1 to 12 in steps of 1

REMOTE RTD MODULE 1

MOD 1 HOTTEST STATOR

NUMBER: 0

Range: –40 to 200°C or –40 to 392°F

MOD 1 HOTTEST STATOR

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

Range: –40 to 200°C or –40 to 392°F

RRTD 1 RTD #1

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

Range: –40 to 200°C or –40 to 392°F

RRTD 1 RTD #2

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

Range: –40 to 200°C or –40 to 392°F

RRTD 1 RTD #12

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

The temperature level of all 12 remote RTDs will be displayed here if programmed and

connected to a RRTD module. The name of each RRTD (if changed from the default) will

appear as the first line of each message. These displays are only visible if option R has

been installed.

If communications with the RRTD module is lost, the RRTD MODULE

COMMUNICATIONS LOST message will be displayed.

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CHAPTER 6: ACTUAL VALUES

6.3.7 Overall Stator RTD

PATH: A2 METERING DATA ØØØØØØØ OVERALL STATOR RTD

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

OVERALL STATOR RTD

HOTTEST OVERALL

STATOR TEMP: 70°C

Range: No RTD, Local 369, RRTD#1 to RRTD#4 (for RTD

Name), 1 to 12 in steps of 1 (for RTD #)

HOTTEST STATOR RTD:

Local 369 RTD#: 4

6.3.8 Demand Metering

PATH: A2 METERING DATA ØØØØØØØØ DEMAND METERING

Range: 0 to 65535 A in steps of 1

DEMAND METERING

CURRENT

DEMAND: 0 Amps

Range: 0 to 32000 kW in steps of 1

REAL POWER

DEMAND: 0 kW

Only shown if VT CONNECTION programmed

Range: 0 to 32000 kvar in steps of 1

REACTIVE POWER

DEMAND: 0 kvar

Only shown if VT CONNECTION programmed

Range: 0 to 65000 kVA in steps of 1

APPARENT POWER

DEMAND: 0 kVA

Only shown if VT CONNECTION programmed

Range: 0 to 65535 A in steps of 1

PEAK CURRENT

DEMAND: 0 Amps

Range: 0 to 32000 kW in steps of 1

PEAK REAL POWER

DEMAND: 0 kW

Only shown if VT CONNECTION programmed

Range: 0 to 32000 kvar in steps of 1

PEAK REACTIVE POWER

DEMAND: 0 kvar

Only shown if VT CONNECTION programmed

Range: 0 to 65000 kVA in steps of 1

PEAK APPARENT POWER

DEMAND: 0 kVA

Only shown if VT CONNECTION programmed

The values for current and power demand are displayed here. Peak demand information

can be cleared using the CLEAR PEAK DEMAND command located in

S1 369 SETUP Ø CLEAR/PRESET DATA. Demand is only shown for positive real (kW) and

reactive (kvar) powers. Only the current demand will be visible if options M or B are not

installed.

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A2 METERING DATA

6.3.9 Phasors

PATH: A2 METERING DATA ØØØØØØØØØ PHASORS

Range: 0 to 359 degrees in steps of 1

PHASORS

Ia PHASOR:

0 Degrees Lag

Range: 0 to 359 degrees in steps of 1

Ib PHASOR:

0 Degrees Lag

Range: 0 to 359 degrees in steps of 1

Ic PHASOR:

0 Degrees Lag

Range: 0 to 359 degrees in steps of 1

Only shown if VT CONNECTION is programmed

Van if WYE connection, Vab if Open Delta Connection

Vax PHASOR:

0 Degrees Lag

Range: 0 to 359 degrees in steps of 1

Only shown if VT CONNECTION is programmed

Vbn if WYE connection, Vbc if Open Delta Connection

Vbx PHASOR:

0 Degrees Lag

Range: 0 to 359 degrees in steps of 1

Only shown if VT CONNECTION is programmed

Vcn if WYE connection, Vca if Open Delta Connection

Vcx PHASOR:

0 Degrees Lag

All angles shown are with respect to the reference phasor. The reference phasor is based

on the VT connection type. In the event that option M has not been installed, V_anfor Wye is

0 V, or V_abfor Delta is 0 V, I_awill be used as the reference phasor

Reference Phasor

VT Connection Type

None

I_a

V_an

V_ab

Wye

Delta

Note that the phasor display is not intended to be used as a protective metering element.

Its prime purpose is to diagnose errors in wiring connections.

To aid in wiring, the following tables can be used to determine if VTs and CTs are on the

correct phase and their polarity is correct. Problems arising from incorrect wiring are

extremely high unbalance levels (CTs), erroneous power readings (CTs and VTs), or phase

reversal trips (VTs). To correct wiring, simply start the motor and record the phasors. Using

the following tables along with the recorded phasors, system rotation, VT connection type,

and motor power factor, the correct phasors can be determined. Note that V_a(V_abif delta)

is always assumed to be 0° and is the reference for all angle measurements.

Common problems include:

Phase currents 180° from proper location (CT polarity

reversed)

Phase currents or voltages 120° or 240° out (CT/VT on

wrong phase.)

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CHAPTER 6: ACTUAL VALUES

Table 6–1: Three Phase Wye VT Connection

ABC

ROTATION

72.5°

= 0.3 PF LAG

45°

0°

–45°

= 0.7 PF LEAD

–72.5°

= 0.2 PF LEAD

= 0.7 PF LAG

= 1.00 PF

Van

Vbn

Vcn

120

240

72.5

192.5

312.5

120

240

165

285

120

240

120

240

315

195

120

240

287.5

47.5

167.5

120

240

kVar

kVA

–

+ (= kW)

ACB

ROTATION

72.5°

= 0.3 PF LAG

45°

= 0.7 PF LAG

0°

= 1.00 PF

–45°

= 0.7 PF LEAD

–72.5°

= 0.2 PF LEAD

Van

Vbn

Vcn

240

120

72.5

312.5

192.5

240

120

285

165

240

120

240

120

315

195

240

120

287.5

167.5

47.5

240

120

kvar

kVA

–

+ (= kW)

Table 6–2: Three Phase Open Delta VT Connection

ABC

ROTATION

72.5°

= 0.3 PF LAG

45°

0°

–45°

= 0.7 PF LEAD

–72.5°

= 0.3 PF LEAD

= 0.7 PF LAG

= 1.00 PF

Vab

Vbc

Vca

120

240

102.5

222.5

342.5

120

240

195

315

120

240

120

240

345

105

225

120

240

317.5

77.5

197.5

150

270

kvar

kVA

–

+ (= kW)

ACB

ROTATION

72.5°

= 0.3 PF LAG

45°

= 0.7 PF LAG

0°

= 1.00 PF

–45°

= 0.7 PF LEAD

–72.5°

= 0.3 PF LEAD

Vab

Vbc

Vca

240

120

42.5

282.5

162.5

240

120

255

135

240

120

330

210

240

120

285

165

240

120

257.5

137.5

17.5

kvar

kVA

–

+ (= kW)

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A3 LEARNED DATA

6.4 A3 Learned Data

6.4.1 Description

This page contains the data the 369 learns to adapt itself to the motor protected.

6.4.2 Motor Data

PATH: A3 LEARNED DATA Ø MOTOR DATA

Range: 1.0 to 250.0 s in steps of 0.1

MOTOR DATA

LEARNED ACCELERATION

TIME: 0.0 s

Range: 0 to 100000 A in steps of 1

LEARNED STARTING

CURRENT: 0 A

Range: 0 to 100% in steps of 1

Range: 0 to 500 min in steps of 1

Range: 0 to 100000 A in steps of 1

Range: 0 to 100% in steps of 1%

Range: 1.0 to 250.0 s in steps of 0.1

Range: 0.00 to 20.00 x FLA in steps of 0.01

Range: 0 to 29 in steps of 1

LEARNED STARTING

CAPACITY: 85%

LEARNED RUNNING COOL

TIME CONST.: 0 min

LEARNED STOPPED COOL

TIME CONST.: 0 min

LAST STARTING

CURRENT: 0 A

LAST STARTING

CAPACITY: 85%

LAST ACCELERATION

TIME: 0.0 s

AVERAGE MOTOR LOAD

LEARNED: 0.00 X FLA

LEARNED UNBALANCE k

FACTOR: 0

Range: 65535 days, 1440 minutes

Range: month/day/year

AVG. RUN TIME AFTER

START: 14 hours,22 min

DATE OF RECORD

Feb 14 2007

Range: 0 to 65535

NUMBER OF RECORDS

250

The learned values for acceleration time and starting current are the average of the

individual values acquired for the last five successful starts. The value for starting current is

used when learned k factor is enabled.

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CHAPTER 6: ACTUAL VALUES

The learned value for starting capacity is the amount of thermal capacity required for a

start determined by the 369 from the last five successful motor starts. The last five learned

start capacities are averaged and a 25% safety margin factored in. This guarantees

enough thermal capacity available to start the motor. The Start Inhibit feature, when

enabled, uses this value in determining lockout time.

The learned cool time constants and unbalance k factor are displayed here. The learned

value is the average of the last five measured constants. These learned cool time

constants are used only when the ENABLE LEARNED COOL TIMES thermal model

setpoint is "Yes". The learned unbalance k factor is the average of the last five calculated k

factors. The learned k factor is only used when unbalance biasing of thermal capacity is

set on and to learned.

Note that learned values are calculated even when features requiring them are turned off.

The learned features should not be used until at least five successful motor starts and

stops have occurred.

Starting capacity, starting current, and acceleration time values are displayed for the last

start. The average motor load while running is also displayed here. The motor load is

averaged over a 15 minute sliding window.

Clearing motor data (see Section 5.2.10: Clear/Preset Data on page –120) resets these

values to their default settings.

6.4.3 Local RTD Maximums

PATH: A3 LEARNED DATA ØØ LOCAL RTD MAXIMUMS

Range: –40 to 200°C or –40 to 392°F

LOCAL RTD MAXIMUMS

RTD #1 MAXIMUM

TEMPERATURE: 40°C

No RTD = open, Shorted = shorted RTD

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #2 MAXIMUM

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #3 MAXIMUM

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #12 MAXIMUM

TEMPERATURE: 40°C

The maximum temperature level of all 12 internal RTDs will be displayed here if the 369 has

option R enabled. The programmed name of each RTD (if changed from the default) will

appear as the first line of each message.

These displays are only visible if option R has been installed and RTDs have been

programmed.

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A3 LEARNED DATA

6.4.4 Remote RTD Maximums

PATH: A3 LEARNED DATA ØØØ REMOTE RTD MAXIMUMS Ø RRTD #1(4)

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RRTD #1

RTD #1 MAXIMUM

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #2 MAXIMUM

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #3 MAXIMUM

TEMPERATURE: 40°C

Range: –40 to 200°C or –40 to 392°F

No RTD = open, Shorted = shorted RTD

RTD #12 MAXIMUM

TEMPERATURE: 40°C

The maximum temperature level of the 12 remote RTDs for each RRTD will be displayed

here if the 369 has been programmed and connected to a RRTD module. The programmed

name of each RTD (if changed from the default) will appear as the first line of each

message. If an RRTD module is connected and no RRTDs are programmed, the display

reads NO RRTDS PROGRAMMED when an attempt is made to enter this actual values

page.

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A4 STATISTICAL DATA

CHAPTER 6: ACTUAL VALUES

6.5 A4 Statistical Data

6.5.1 Trip Counters

PATH: A4 STATISTICAL DATA Ø TRIP COUNTERS

Range: 0 to 50000 in steps of 1

TRIP COUNTERS

TOTAL NUMBER OF

TRIPS: 0

Range: 0 to 50000 in steps of 1

INCOMPLETE SEQUENCE

TRIPS: 0

SWITCH

TRIPS: 0

OVERLOAD

TRIPS: 0

SHORT CIRCUIT

TRIPS: 0

MECHANICAL JAM

TRIPS: 0

UNDERCURRENT

TRIPS: 0

CURRENT UNBALANCE

TRIPS: 0

SINGLE PHASE

TRIPS: 0

GROUND FAULT

TRIPS: 0

ACCELERATION

TRIPS: 0

STATOR RTD

TRIPS : 0

BEARING RTD

TRIPS : 0

OTHER RTD

TRIPS : 0

AMBIENT RTD

TRIPS : 0

UNDERVOLTAGE

TRIPS : 0

OVERVOLTAGE

TRIPS : 0

PHASE REVERSAL

TRIPS: 0

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A4 STATISTICAL DATA

Range: 0 to 50000 in steps of 1

UNDERFREQUENCY

TRIPS: 0

Range: 0 to 50000 in steps of 1

OVERFREQUENCY

TRIPS: 0

LEAD POWER FACTOR

TRIPS : 0

LAG POWER FACTOR

TRIPS : 0

POSITIVE REACTIVE

TRIPS : 0

NEGATIVE REACTIVE

TRIPS : 0

UNDERPOWER

TRIPS : 0

REVERSE POWER

TRIPS : 0

TRIP COUNTERS LAST

CLEARED: 02/28/2007

1.Only shown if option R installed or Channel 3 Application is programmed as RRTD

2.Only shown if option M or B are installed

3.Only shown if option M or B are installed and VT CONNECTION is programmed

The number of trips by type is displayed here. When the total reaches 50000, the counter

resets to 0 on the next trip and continues counting. This information can be cleared with

the setpoints in the CLEAR/PRESET DATA section of setpoints page one. The date the

counters are cleared will be recorded.

6.5.2 Motor Statistics

PATH: A4 STATISTICAL DATA ØØ MOTOR STATISTICS

Range: 0 to 50000 in steps of 1

MOTOR STATISTICS

NUMBER OF MOTOR

STARTS: 0

Range: 0 to 50000 in steps of 1

Range: 0 to 100000 in steps of 1

Range: 0 to 50000 in steps of 1

NUMBER OF EMERGENCY

RESTARTS: 0

MOTOR RUNNING HOURS:

0 hrs

AUTORESTART START

ATTEMPTS: 0

TIME TO AUTORESTART:

Range: 0 to 65535 Units in steps of 1

Shown if Counter set to a digital input

COUNTER:

0 Units

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CHAPTER 6: ACTUAL VALUES

NUMBER OF MOTOR STARTS, and NUMBER OF EMERGENCY RESTARTS values

display the number of motor starts and emergency restarts respectively. This information

is useful for troubleshooting a motor failure or in understanding the history and use of a

motor for maintenance purposes. When any of these counters reaches 50000, they are

automatically reset to 0.

The MOTOR RUNNING HOURS indicates the elapsed time since the 369 determined the

motor to be in a running state (current applied and/or starter status indicating contactor/

breaker closed). The NUMBER OF MOTOR STARTS, NUMBER OF EMERGENCY RESTARTS, and

MOTOR RUNNING HOURS counters can be cleared with the S1 369 SETUP Ø CLEAR/PRESET

DATA Ø CLEAR MOTOR DATA setpoint.

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A5 EVENT RECORD

6.6 A5 Event Record

6.6.1 Event Records

PATH: A5 EVENT RECORD Ø EVENT 01

Time: hours / minutes / seconds / hundreds of

seconds

EVENT 01

TIME OF EVENT 01

00:00:00:00

Date: month / day / year

DATE OF EVENT 01

Feb. 28, 2007

Range: Not Programmed, Low Speed, High Speed

Range: 0 to 65535 A in steps of 1

MOTOR SPEED DURING

EVENT: High Speed

A: 0

C: 0

B: 0

A E: 01

Range: 0.00 to 20.00 x FLA in steps of 0.01

Range: 0 to 100% in steps of 1

MOTOR LOAD

0.00 X FLA E: 01

CURRENT UNBALANCE:

E: 01

Range: 0.0 to 5000.0 A steps of 0.1 (1A/5A CT)

0.00 to 25.00 A steps of 0.01 (50: 0.025 A CT)

GROUND CURRENT:

0.0 Amps E: 01

Range: Local, RRTD1, RRTD2, RRTD3, RRTD4

No RTD = open, Shorted = shorted RTD

–40 to 200°C or –40 to 392°F

HOTTEST STATOR RTD:

Local RTD: 12 76°C

Range: 0 to 20000 V in steps of 1

Vab: 0 Vbc: 0

Vca: 0 V E: 01

Only shown if VT CONNECTION is "Delta"

Range: 0 to 20000 V in steps of 1

Van: 0 Vbn: 0

Vcn: 0 V E: 01

Only shown if VT CONNECTION is "Wye"

Range: 0.00, 15.00 to 120 Hz in steps of 1

SYSTEM FREQUENCY:

0.00 Hz E: 01

Only shown if VT CONNECTION is programmed

Range: –50000 to +50000 in steps of 1

0 kW

0 kVA

Only shown if VT CONNECTION is programmed

0 kvar E: 01

Range: 0.00 lag to 1 to 0.00 lead

POWER FACTOR:

1.00 E: 01

Only shown if VT CONNECTION is programmed

A breakdown of the last 512 events is available here along with the cause of the event and

the date and time. All trips automatically trigger an event. Alarms only trigger an event if

turned on for that alarm. Loss or application of control power, service alarm and

emergency restart opening and closing also triggers an event. After 512 events have been

recorded, the oldest one is removed when a new one is added. The event record may be

cleared in the setpoints page 1, clear/preset data, clear event record section.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

6–219

A5 EVENT RECORD

CHAPTER 6: ACTUAL VALUES

0.1A6 RELAY INFORMATION6.6.2Model Information

PATH: A6 RELAY INFORMATION Ø MODEL INFORMATION

Range: See Autolabel for details

Range: HI/LO, R/0, M/B/0, F/0, P/P1/E/D/0, H/0, E/0

Range: month/day/year

MODEL INFORMATION

SERIAL NUMBER:

MXXXXXXXX

INSTALLED OPTIONS:

369-HI-R-M-0-P1-0-E

MANUFACTURE

DATE: Feb. 28 2007

Range: month/day/year

LAST CALIBRATION

DATE: Feb. 28 2007

The relay model and manufacturing information may be viewed here. The last calibration

date is the date the relay was last calibrated at GE Multilin.

6.6.3 Firmware Version

PATH: A6 RELAY INFORMATION ØØ FIRMWARE VERSION

FIRMWARE VERSION

FIRMWARE REVISION:

320

BUILD DATE & TIME:

Mar 18, 2008 15:39:40

BOOT REVISION:

100

Note: Only shown with the Profibus (P or P1),

Modbus/TCP (E), and DeviceNet (D) options.

FIELDBUS CARD SW

REVISION: 112

This information reflects the revisions of the software currently running in the 369 Relay.

This information should be noted and recorded before calling for technical support or

service.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 7: Applications

Applications

7.1 269-369 Comparison

7.1.1 369 and 269plus Comparison

Table 7–1: Comparison Between 369 Relay and 269plus

369

269Plus

All options can be turned on or added in

the field

Must be returned for option change or

add other devices

Current inputs only. Must use additional

meter device to obtain voltage and power

measurements.

Current and optional voltage inputs are

included on all relays

Optional 12 RTDs with an additional 12

RTDs available with the RRTD. All RTDs are 10 RTDs not programmable, must be

individually configured

(100P, 100N, 120N, 10C)

specified at time of order.

Fully programmable digital inputs

No programmable digital inputs

4 programmable analog outputs

assignable to 33 parameters

1 Analog output programmable for 5

parameters

1 RS232 (19.2K baud), 3 RS485 (1200 TO

19.2K baud programmable)

communication ports. Also Optional

profibus port and optional fiber optics

port

1 RS485 Communication port (2400 baud

maximum)

Flash memory firmware upgrade thru PC

software and comm port

EPROM must be replaced to change

firmware

EVENT RECORDER: time and date stamp

last 512 events. Records all trips and

selectable alarms

Displays cause of last trip and last event

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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269-369 COMPARISON

CHAPTER 7: APPLICATIONS

Table 7–1: Comparison Between 369 Relay and 269plus

369

269Plus

OSCILLOGRAPHY: up to 64 cycles at 16

samples/cycle for last event(s)

N/A

Programmable text message(s)

N/A

Backspin frequency detection and

backspin timer

Backspin timer

N/A

Starter failure indication

Measures up to 20 x CT at 16 samples/

cycle

Measures up to 12 x CT at 12 samples/

cycle

15 standard overload curves

Remote display is standard

8 standard overload curves

Remote display with mod

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

369 FAQS

7.2 369 FAQs

7.2.1 Frequently Asked Questions (FAQs)

1. What is the difference between Firmware and Software?

Firmware is the program running inside the relay, which is responsible for all

relay protection and control elements. Software is the program running on the

PC, which is used to communicate with the relay and provide relay control

remotely in a user friendly format.

2. How can I obtain copies of the latest manual and PC software?

I need it now!: via the GE Multilin website at http://www.GEindustrial.com/

multilin

I guess I can wait: fax a request to the GE Multilin Literature department at

(905) 201-2113

3. Cannot communicate through the front port (RS232).

Check the following settings:

•

Communication Port (COM1, COM2, COM3 etc.) on PC or PLC

Parity settings must match between the relay and the master (PC or PLC)

Baud rate setting on the master (PC or PLC) must match RS232 baud

rate on the 369 relay.

•

Cable has to be a straight through cable, do not use null modem cables

where pin 2 and 3 are transposed

Check the pin outs of RS232 cable (TX - pin 2, RX - pin 3, GND - pin 5)

4. Cannot communicate with RS485.

Check the following settings:

•

Communication Port (COM1, COM2, COM3 etc.) on PC or PLC

Parity settings must match between the relay and the master (PC or PLC)

Baud rate must match between the relay and the master

Slave address polled must match between the relay and the master

Is terminating filter circuit present?

Are you communicating in half duplex? (369 communicates in half

duplex mode only)

•

Is wiring correct? (“+” wire should go to “+” terminal of the relay, and “–”

goes to “–” terminal)

Is the RS485 cable shield grounded? (shielding diminishes noise from

external EM radiation)

Check the appropriate communication port LED on the relay. The LED should

be solidly lit when communicating properly. The LED will blink on and off when

the relay has communication difficulties and the LED will be off if no activity

detected on communication lines.

5. Can the 4 wire RS485 (full duplex) be used with 369?

No, the 369 communicates in 2-wire half duplex mode only. However, there

are commercial RS485 converters that will convert a 4 wire to a 2 wire system.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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369 FAQS

CHAPTER 7: APPLICATIONS

6. Cannot store setpoint into the relay.

Check and ensure the ACCESS switch is shorted, and check for any PASSCODE

restrictions.

7. The 369 relay displays incorrect power reading, yet the power system is

balanced. What could be the possible reasons?

It is highly possible that the secondary wiring to the relay is not correct.

Incorrect power can be read when any of the A, B, or C phases are swapped, a

CT or VT is wired backwards, or the relay is programmed as ABC sequence

when the power system is actually ACB and vice versa. The easiest way to

verify is to check the voltage and the current phasor readings on the 369 relay

and ensure that each respective voltage and current angles match.

8. What are the merits of a residual ground fault connection versus a core

balance connection?

The use of a zero sequence (core balance) CT to detect ground current is

recommended over the G/F residual connection. This is especially true at

motor starting. During across-the-line starting of large motors, care must be

taken to prevent the high inrush current from operating the ground element

of the 369. This is especially true when using the residual connection of 2 or 3

CTs.

In a residual connection, the unequal saturation of the current transformers,

size and location of motor, size of power system, resistance in the power

system from the source to the motor, type of iron used in the motor core &

saturation density, and residual flux levels may all contribute to the

production of a false residual current in the secondary or relay circuit. The

common practice in medium and high voltage systems is to use low

resistance grounding. By using the “doughnut CT” scheme, such systems offer

the advantages of speed and reliability without much concern for starting

current, fault contribution by the motor, or false residual current.

When a zero sequence CT is used, a voltage is generated in the secondary

winding only when zero sequence current is flowing in the primary leads.

Since virtually all motors have their neutrals ungrounded, no zero sequence

current can flow in the motor leads unless there is a ground fault on the motor

side.

9. Can I use an 86 lockout on the 369?

Yes, but if an external 86 lockout device is used and connected to the 369,

ensure the 369 is reset prior to attempting to reset the lockout switch. If the

369 is still tripped, it will immediately re-trip the lockout switch. Also, if the

lockout switch is held reset, the high current draw of the switch coil may

cause damage to itself and/or the 369 output relay.

10. Can I assign more than one output relay to be blocked when using Start

Inhibits?

Yes, but keep in mind that if two output relays are wired in series to inhibit a

start it is possible that another element could be programmed to control one

or both of the relays. If this is happening and the other element is

programmed with a longer delay time, this will make it seem as if the Start

Inhibit is not working properly when in fact, it is.

11. Can I name a digital input?

Yes. By configuring the digital input as "General" a menu will appear that will

allow naming.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

369 FAQS

12. Can I apply an external voltage to the digital inputs on the 369?

No. The 369 uses an internal voltage to operate the digital inputs. Applying an

external voltage may cause damage to the internal circuitry.

13. Can I upload setpoint files from previous versions to the latest version of

firmware?

Yes, with the exception of setpoint files from versions 1.10 and 1.12.

Unfortunately these setpoint files must be rewritten, as they are not

compatible.

14. What method does the 369 use to calculate current unbalance?

The 369 uses the NEMA method. Previous revisions of the 369 manual have

incorrectly included a functional test that measured the ratio of negative

sequence current to positive sequence current. The NEMA method is as

follows:

_max– I_avg

--------------------------

If I_avg≥ I_FLA, then Unbalance =

× 100

I_avg

where:I_avg= average phase current

I_max= current in a phase with maximum derivation from Iavg

I_FLA= motor full load amps setting

_max– I_avg

--------------------------

If I_avg< I_FLA, then Unbalance =

× 100

I_FLA

To prevent nuisance trips/alarms on lightly loaded motors when a much

larger unbalance level will not damage the rotor, the unbalance protection will

automatically be defeated if the average motor current is less than 30% of the

full load current (I_FLA) setting.

15. I need to update the options for my 369/RRTD in the field, can I do this?

Yes. All options of the 369/RRTD can be turned on or added in the field. To do

this contact the factory.

16. Can I test my output relays?

Yes, but keep in mind that the output relays cannot be forced into a different

state while the motor is running.

17. Is the communication interface for Profibus RS232 or RS485?

It is RS485. The 9-pin connector on the rear of the 369 is the connector used

by the manufacturer of the Profibus card and although it is a DB-9, the

electrical interface is RS485.

18. Can I use the options enabler code to upgrade my 369 in the field to get the

Profibus option?

Yes, but keep in mind that there is a Profibus card that is required and is not

installed in units that were not ordered from the factory with the Profibus

option.

19. Can the 369 be used as a remote unit, similar to the 269 remote?

Yes. Every 369 can be used as remote. When ordering the 369, an external 15

foot cable must be ordered.

20. Can the RRTD module be used as a standalone unit?

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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369 FAQS

CHAPTER 7: APPLICATIONS

Yes. The RRTD unit with the IO option, has 4 output relays, 6 digital inputs and

4 analog outputs. With this option the RRTD can provide temperature

protection.

21. Why is there a filter ground and a safety ground connection? Why are they

separate?

The safety ground ensures operator safety with regards to hazardous shocks;

the filter ground protects the internal electronic circuitry from transient noise.

These two grounds are separated for hi-pot (dielectric strength) testing

purposes. Both grounds should be tied to the ground bus external to the relay.

22. 369 doesn't communicate with ethernet after change in IP address, what

should I do?

Cycle the power supply to the 369. In order to make the new IP address active

the power supply of the 369 must be recycled after changing or setting the IP

address of the relay.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

369 DO’S AND DONT’S

7.3 369 Do’s and Dont’s

7.3.1 Do’s and Dont’s

Do’s

Always check the power supply rating before applying power to the relay

Applying voltage greater than the maximum rating to the power supply (e.g.

120 V AC to the low-voltage rated power supply) could result in component

damage to the relay's power supply. This will result in the unit no longer being able

to power up.

Ensure that the 369 nominal phase current of 1 A or 5 A matches the secondary rating

and the connections of the connected CTs

Unmatched CTs may result in equipment damage or inadequate protection.

Ensure that the source CT and VT polarity match the relay CT and VT polarity

Polarity of the Phase CTs is critical for power measurement, and residual ground

current detection (if used). Polarity of the VTs is critical for correct power

measurement and voltage phase reversal operation.

Properly ground the 369

Connect both the Filter Ground (terminal 123) and Safety Ground (terminal 126) of

the 369 directly to the main GROUND BUS. The benefits of proper grounding of the

369 are numerous, e.g,

•

Elimination of nuisance tripping

Elimination of internal hardware failures

Reliable operation of the relay

Higher MTBF (Mean Time Between Failures)

It is recommended that a tinned copper braided shielding and bonding

cable be used. A Belden 8660 cable or equivalent should be used as a

minimum to connect the relay directly to the ground bus.

Grounding of Phase and Ground CTs

All Phase and Ground CTs must be grounded. The potential difference between the

CT's ground and the ground bus should be minimal (ideally zero).

It is highly recommended that the two CT leads be twisted together to minimize

noise pickup, especially when the highly sensitive 50:0.025 Ground CT sensor is

used.

RTDs

Consult the application notes of the 369 Instruction Manual for the full description

of the 369 RTD circuitry and the different RTD wiring schemes acceptable for

proper operation. However, for best results the following recommendations should

be adhered to:

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

7–227

369 DO’S AND DONT’S

CHAPTER 7: APPLICATIONS

1. Use a 3 wire twisted, shielded cable to connect the RTDs from the motor to the

369. The shields should be connected to the proper terminals on the back of

the 369.

2. RTD shields are internally connected to the 369 ground (terminal #126) and

must not be grounded anywhere else.

3. RTD signals can be characterized as very small, sensitive signals. Therefore,

cables carrying RTD signals should be routed as far away as possible from

power carrying cables such as power supply and CT cables.

4. If after wiring the RTD leads to the 369, the RTD temperature displayed by the

Relay is zero, then check for the following conditions:

a. Shorted RTD

b. RTD hot and compensation leads are reversed, i.e. hot lead in compensa-

tion terminal and compensation lead in hot terminal.

RS485 Communications Port

The 369 can provide direct or remote communications (via a modem). An RS232 to

RS485 converter is used to tie it to a PC/PLC or DCS system. The 369 uses the

Modicon MODBUS^®RTU protocol (functions 03, 04, and 16) to interface with PCs,

PLCs, and DCS systems.

RS485 communications was chosen to be used with the 369 because it allows

communications over long distances of up to 4000 ft. However, care must be taken

for it to operate properly and trouble free. The recommendations listed below must

be followed to obtain reliable communications:

1. A twisted, shielded pair (preferably a 24 gauge Belden 9841 type or 120

equivalent) must be used and routed away from power carrying cables, such

as power supply and CT cables.

2. No more than 32 devices can co-exist on the same link. If however, more than

32 devices should be daisy chained together, a REPEATER must be used. Note

that a repeater is just another RS232 to RS485 converter device. The shields of

all 369 units should also be daisy chained together and grounded at the

MASTER (PC/PLC) only. This is due to the fact that if shields are grounded at

different points, a potential difference between grounds might exist resulting

in placing one or more of the transceiver chips (chip used for communications)

in an unknown state, i.e. not receiving nor sending. The corresponding 369

communications might be erroneous, intermittent or unsuccessful.

3. Two sets of 120 ohm/ 0.5 W resistor and 1 nF / 50 V capacitor in series must

be used (value matches the characteristic impedance of the line). One set at

the 369 end, connected between the positive and negative terminals (#46 &

#47 on 369) and the second at the other end of the communications link. This

is to prevent reflections and ringing on the line. If a different value resistor is

used, it runs the risk of over loading the line and communications might be

erroneous, intermittent or totally unsuccessful.

4. It is highly recommended that connection from the 369 communication

terminals be made directly to the interfacing Master Device (PC/PLC/DCS),

without the use of stub lengths and/or terminal blocks. This is also to minimize

ringing and reflections on the line.

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

369 DO’S AND DONT’S

Don’ts

Don’t apply direct voltage to the Digital Inputs.

There are 6 switch inputs (Spare Input; Differential Input; Speed Switch; Access;

Emergency Restart; External Reset) that are designed for dry contact connections

only. Applying direct voltage to the inputs, it may result in component damage to

the digital input circuitry.

Grounding of the RTDs should not be done in two places.

When grounding at the 369, only one Return lead need be grounded as all are

hard-wired together internally. No error will be introduced into the RTD reading by

grounding in this manner.

Running more than one RTD Return lead back will cause significant errors as two

or more parallel paths for return have been created.

Don’t reset an 86 Lockout switch before resetting the 369.

If an external 86 lockout device is used and connected to the 369, ensure that the

369 is reset prior to attempting to reset the lockout switch. If the 369 is still tripped,

it will immediately re-trip the lockout switch. Also if the lockout switch is held

reset, the high current draw of the lockout switch coil may cause damage to itself

and/or the 369 output relay.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

7–229

CT SPECIFICATION AND SELECTION

CHAPTER 7: APPLICATIONS

7.4 CT Specification and Selection

7.4.1 CT Specification

369 CT Withstand

Withstand is important when the phase or ground CT has the capability of driving a large

amount of current into the interposing CTs in the relay. This typically occurs on retrofit

installations when the CTs are not sized to the burden of the relay. Electronic relays

typically have low burdens (mΩ), while the older electromechanical relays have typically

high burdens (1 Ω).

For high current ground faults, the system will be either low resistance or solidly grounded.

The limiting factor that determines the ground fault current that can flow in these types of

systems is the source capacity. Withstand is not important for ground fault on high

resistance grounded systems. On these systems, a resistor makes the connection from

source to ground at the source (generator, transformer). The resistor value is chosen so

that in the event of a ground fault, the current that flows is limited to a low value, typically

5, 10, or 20 A.

Since the potential for very large faults exists (ground faults on high resistance grounded

systems excluded), the fault must be cleared as quickly as possible. It is therefore

recommended that the time delay for short circuit and high ground faults be set to

instantaneous. Then the duration for which the 369 CTs subjected to high withstand will be

less than 250 ms (369 reaction time is less than 50ms + breaker clearing time).

Note

Care must be taken to ensure that the interrupting device is capable of interrupting

the potential fault. If not, some other method of interrupting the fault should be used,

and the feature in question should be disabled (e.g. a fused contactor relies on fuses to

interrupt large faults).

The 369 CTs were subjected to high currents for 1 second bursts. The CTs were capable of

handling 500 A (500 A relates to a 100 times the CT primary rating). If the time duration

required is less than 1 second, the withstand level will increase.

CT Size and Saturation

The rating (as per ANSI/IEEE C57.13.1) for relaying class CTs may be given in a format such

as: 2.5C100, 10T200, T1OO, 10C50, or C200. The number preceding the letter represents

the maximum ratio correction; no number in this position implies that the CT accuracy

remains within a 10% ratio correction from 0 to 20 times rating.

The letter is an indication of the CT type:

•

A 'C' (formerly L) represents a CT with a low leakage flux in the core where there is no

appreciable effect on the ratio when used within the limits dictated by the class and

rating. The 'C' stands for calculated; the actual ratio correction should be different

from the calculated ratio correction by no more than 1%. A 'C' type CT is typically a

bushing, window, or bar type CT with uniformly distributed windings.

•

A 'T' (formerly H) represents a CT with a high leakage flux in the core where there is

significant effect on CT performance. The 'T' stands for test; since the ratio correction

is unpredictable, it is to be determined by test. A 'T' type CT is typically primary wound

7–230

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

CT SPECIFICATION AND SELECTION

with unevenly distributed windings. The subsequent number specifies the secondary

terminal voltage that may be delivered by the full winding at 20 times rated

secondary current without exceeding the ratio correction specified by the first

number of the rating. (Example: a 10C100 can develop 100 V at 20 × 5 A, therefore an

appropriate external burden would be 1 Ω or less to allow 20 times rated secondary

current with less than 10% ratio correction.) Note that the voltage rating is at the

secondary terminals of the CT and the internal voltage drop across the secondary

resistance must be accounted for in the design of the CT. There are seven voltage

ratings: 10, 20, 50, 100, 200, 400, and 800. If a CT comes close to a higher rating, but

does not meet or exceed it, then the CT must be rated to the lower value.

In order to determine how much current CTs can output, the secondary resistance of the

CT is required. This resistance will be part of the equation as far as limiting the current flow.

This is determined by the maximum voltage that may be developed by the CT secondary

divided by the entire secondary resistance, CT secondary resistance included.

7.4.2 CT Selection

The 369 phase CT should be chosen such that the FLA (FLC) of the motor falls within 50 to

100% of the CT primary rating. For example, if the FLA of the motor is 173 A, a primary CT

rating of 200, 250, or 300 can be chosen (200 being the better choice). This provides

maximum protection of the motor.

The CT selected must then be checked to ensure that it can drive the attached burden

(relay and wiring and any auxiliary devices) at maximum fault current levels without

saturating. There are essentially two ways of determining if the CT is being driven into

saturation:

1. Use CT secondary resistance

Burden = CT secondary resistance + Wire resistance + Relay burden resistance

I_{fault maximum}

-----------------------------------

CT secondary voltage = Burden ×

CT ratio

Example:

Maximum fault level = 6 kA

369 burden = 0.003 Ω

CT = 300:5

CT secondary resistance = 0.088 Ω

Wire length (1 lead) = 50 m

Wire Size = 4.00 mm²

Ohms/km = 4.73 Ω

∴ Burden = 0.088 + (2 × 50)(4.73 / 1000) + 0.003 = 0.564 Ω

∴ CT secondary voltage = 0.564 × (6000 / (300 / 5)) = 56.4 V

Using the excitation curves for the 300:5 CT we see that the knee voltage is at 70 V,

therefore this CT is acceptable for this application.

2. Use CT class

Burden = Wire resistance + Relay burden resistance

I_{fault maximum}

-----------------------------------

CT secondary voltage = Burden ×

CT ratio

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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CT SPECIFICATION AND SELECTION

CHAPTER 7: APPLICATIONS

Example:

Maximum fault level = 6 kA, 369 burden = 0.003 Ω, CT = 300:5, CT class = C20,

Wire length (1 lead) = 50 m, Wire Size = 4.00 mm², Ohms/km = 4.73 Ω

∴ Burden = (2 × 50) × (4.73/1000) + 0.003 = 0.476 Ω

∴ CT secondary voltage = 0.476 × (6000 / (300 / 5)) = 47.6 V

From the CT class (C20): The amount of secondary voltage the CT can deliver to the

load burden at 20 × CT without exceeding the 10% ratio error is 20 V. This

application calls for 6000/300 = 20 × CT (Fault current / CT primary). Thus the 10%

ratio error may be exceeded.

The number in the CT class code refers to the guaranteed secondary voltage of the

CT. Therefore, the maximum current that the CT can deliver can be calculated as

follows:

maximum secondary current = CT class / Burden = 20 / 0.476 = 42.02 A

FIGURE 7–1: Equivalent CT Circuit

7–232

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 7: APPLICATIONS

PROGRAMMING EXAMPLE

7.5 Programming Example

7.5.1 Programming Example

Information provided by a motor manufacturer can vary from nameplate information to a

vast amount of data related to every parameter of the motor. The table below shows

selected information from a typical motor data sheet and FIGURE 7–2: Motor Thermal

Limits shows the related motor thermal limit curves. This information is required to set the

369 for a proper protection scheme.

The following is a example of how to determine the 369 setpoints. It is only a example

and the setpoints should be determined based on the application and specific design

of the motor.

Table 7–2: Selected Information from a Typical Motor Data Sheet

Driven equipment

Ambient Temperature

Type or Motor

Reciprocating Compressor

min. –20°C; max. 41°C

Synchronous

Voltage

6000 V

Nameplate power

2300 kW

Service Factor

Insulation class

Temperature rise stator / rotor

Max. locked rotor current

Locked rotor current% FLC

Starting time

79 / 79 K

550% FLC

500% at 100% Voltage / 425% at 85% Voltage

4 seconds at 100% Voltage / 6.5 seconds at

85% Voltage

Max. permissible starts cold / hot

Rated Load Current

3 / 2

229A at 100% Load

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

7–233

PROGRAMMING EXAMPLE

CHAPTER 7: APPLICATIONS

FIGURE 7–2: Motor Thermal Limits

Phase CT

The phase CT should be chosen such that the FLC is 50% to 100% of CT primary. Since the

FLC is 229 A a 250:5, 300:5, or 400:5 CT may be chosen (a 250:5 is the better choice).

229 / 0.50 = 458 or 229 / 1.00 = 229

Motor FLC

Set the Motor Full Load Current to 229A, as per data sheets.

Ground CT

For high resistive grounded systems, sensitive ground detection is possible with the

50:0.025 CT. On solidly grounded or low resistive grounded systems where the fault current

is much higher, a 1A or 5A CT should be used. If residual ground fault connection is to be

used, the ground fault CT ratio most equal the phase CT ratio. The zero sequence CT

chosen needs to be able to handle all potential fault levels without saturating.

VT Settings

The motor is going to be connected in Wye, hence, the VT connection type will be

programmed as Wye. Since the motor voltage is 6000V, the VT being used will be 6000:120.

The VT ratio to be programmed into the 369 will then be 50:1 (6000/120) and the Motor

Rated Voltage will be programmed to 6000V, as per the motor data sheets.

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Overload Pickup

The overload pickup is set to the same as the service factor of the motor. In this case, it

would be set to the lowest setting of 1.01 x FLC for the service factor of 1.

Unbalance Bias Of Thermal Capacity

Enable the Unbalance Bias of Thermal Capacity so that the heating effect of unbalance

currents is added to the Thermal Capacity Used.

Unbalance Bias K Factor

The K value is used to calculate the contribution of the negative sequence current flowing

in the rotor due to unbalance. It is defined as:

R_r2

R_r1

-------

, where: R_r2= rotor negative sequence resistance, R_r1= rotor positive sequence

resistance

175

L²_RA5.5²

175

K = --------- = ---------- @ 6

where: L_RA= Locked Rotor Current

Note

The above formula is based on empirical data.

The 369 has the ability to learn the K value after five successful starts. After 5 starts, turn

this setpoint off so that the 369 uses the learned value

Hot/Cold Curve Ratio

The hot/cold curve ratio is calculated by simply dividing the hot safe stall time by the cold

safe stall time. This information can be extracted from the Thermal Limit curves. From

FIGURE 7–2: Motor Thermal Limits, we can determine that the hot safe stall time is

approximately 18 seconds and the cold safe stall time is approximately 24 seconds.

Therefore, the Hot/Cold curve ratio should be programmed as 0.75 (18 / 24) for this

example.

Running and Stopped Cool Time Constant

The running cool time is the time required for the motor to cool while running. This

information is usually supplied by the motor manufacturer but is not part of the given data.

The motor manufacturer should be contacted to find out what the cool times are.

The Thermal Capacity Used quantity decays exponentially to simulate the cooling of the

motor. The rate of cooling is based upon the running cool time constant when the motor is

running, or the stopped cool time constant when the motor is stopped. The entered cool

time constant is one fifth the total cool time from 100% thermal capacity used down to 0%

thermal capacity used.

The 369 has a unique capability of learning the cool time constant. This learned parameter

is only functional if the Stator RTDs are connected to the 369. The learned cool time

algorithm observes the temperature of the motor as it cools, thus determining the length

of time required for cooling. If the cool times can not be retrieved from the motor

manufacturer, then the Learned Cool Time must be enabled (if the stator RTDs are

connected).

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Motors have a fanning action when running due to the rotation of the rotor. For this reason,

the running cool time is typically half of the stopped cool time.

Refer to the Selection of Cool Time application note for more details on how to determine

the cool time constants when not provided with the motor.

RTD Biasing

This will enable the temperature from the Stator RTD sensors to be included in the

calculations of Thermal Capacity. This model determines the Thermal Capacity Used based

on the temperature of the Stators and is a separate calculation from the overload model

for calculating Thermal Capacity Used. RTD biasing is a back up protection element which

accounts for such things as loss of cooling or unusually high ambient temperature. There

are three parameters to set: RTD Bias Min, RTD Bias Mid, RTD Bias Max.

RTD Bias Minimum

Set to 40°C which is the ambient temperature (obtained from data sheets).

RTD Bias Mid Point

The center point temperature is set to the motor’s hot running temperature and is

calculated as follows:

Temperature Rise of Stator + Ambient Temperature.

The temperature rise of the stator is 79°K, obtained from the data sheets. Therefore, the

RTD Center point temperature is set to 120°C (79 + 40).

RTD Bias Maximum

This setpoint is set to the rating of the insulation or slightly less. A class F insulation is used

in this motor which is rated at 155°C.

Overload Curve

If only one thermal limit curve is provided, the chosen overload curve should fit below it.

When a hot and cold thermal limit curve is provided, the chosen overload curve should fit

between the two curves and the programmed Hot/Cold ratio is used in the Thermal

Capacity algorithm to take into account the thermal state of the motor. The best fitting 369

standard curve is curve # 4, as seen in FIGURE 7–2: Motor Thermal Limits on page 7–234.

Short Circuit Trip

The short circuit trip should be set above the maximum locked rotor current but below the

short circuit current of the fuses. The data sheets indicate a maximum locked rotor current

of 550% FLC or 5.5 × FLC. A setting of 6 × FLC with a instantaneous time delay will be ideal

but nuisance tripping may result due to unusually high demanding starts or starts while

the load is coupled. If need be, set the S/C level higher to a maximum of 8 × FLC to override

these conditions.

Mechanical Jam

If the process causes the motor to be prone to mechanical jams, set the Mechanical Jam

Trip and Alarm accordingly. In most cases, the overload trip will become active before the

Mechanical Trip, however, if a high overload curve is chosen, the Mechanical Jam level and

time delay become more critical. The setting should then be set to below the overload

curve but above any normal overload conditions of the motor. The main purpose of the

mechanical jam element is to protect the driven equipment due to jammed, or broken

equipment.

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Undercurrent

If detection of loss of load is required for the specific application, set the undercurrent

element according to the current that will indicate loss of load. For example, this could be

programmed for a pump application to detect loss of fluid in the pipe.

Unbalance Alarm and Trip

The unbalance settings are determined by examining the motor application and motor

design. In this case, the motor being protected is a reciprocating compressor, in which

unbalance will be a normal running condition, thus this setting should be set high. A setting

of 20% for the Unbalance Alarm with a delay of 10 seconds would be appropriate and the

trip may be set to 25% with a delay of 10 seconds

Ground Fault

Unfortunately, there is not enough information to determine a ground fault setting. These

settings depend on the following information:

1. The Ground Fault current available.

2. System Grounding - high resistive grounding, solidly grounded, etc.

3. Ground Fault CT used.

4. Ground Fault connection - zero sequence or Residual connection.

Acceleration Trip

This setpoint should be set higher than the maximum starting time to avoid nuisance

tripping when the voltage is lower or for varying loads during starting. If reduced voltage

starting is used, a setting of 8 seconds would be appropriate, or if direct across the line

starting is used, a setting of 5 seconds could be used.

Start Inhibit

This function should always be enabled after five successful starts to protect the motor

during starting while it is already hot. The 369 learns the amount of thermal capacity used

at start. If the motor is hot, thus having some thermal capacity, the 369 will not allow a

start if the available thermal capacity is less than the required thermal capacity for a start.

For more information regarding start inhibit refer to application note in section 7.6.6.

Starts/Hour

Starts/Hour can be set to the # of cold starts as per the data sheet. For this example, the

starts/hour would be set to 3.

Time Between Starts

In some cases, the motor manufacturer will specify the time between motor starts. In this

example, this information is not given so this feature can be turned “Off”. However, if the

information is given, the time provided on the motor data sheets should be programmed.

Stator RTDs

RTD trip level should be set at or below the maximum temperature rating of the insulation.

This example has a class F insulation which has a temperature rating of 155°C, therefore

the Stator RTD Trip level should be set to between 140°C to 155°C. The RTD alarm level

should be set to a level to provide a warning that the motor temperature is rising. For this

example, 120°C or 130°C would be appropriate.

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Bearing RTDs

The Bearing RTD alarm and trip settings will be determined by evaluating the temperature

specification from the bearing manufacturer.

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7.6 Applications

7.6.1 Motor Status Detection

The 369 detects a stopped motor condition when the phase current falls below 5% of CT,

and detects a starting motor condition when phase current is sensed after a stopped

motor condition. If the motor idles at 5% of CT, several starts and stops can be detected

causing nuisance lockouts if Starts/Hour, Time Between Starts, Restart Block, Start Inhibit,

or Backspin Timer are programmed. As well, the learned values, such as the Learned

Starting Thermal Capacity, Learned Starting Current and Learned Acceleration time can be

incorrectly calculated.

To overcome this potential problem, the Spare Digital Input can be configured to read the

status of the breaker and determine whether the motor is stopped or simply idling. With

the spare input configured as Starter Status and the breaker auxiliary contacts wired

across the spare input terminals, the 369 senses a stopped motor condition only when the

phase current is below 5% of CT (or zero) AND the breaker is open. If both of these

conditions are not met, the 369 will continue to operate as if the motor is running and the

starting elements remain unchanged. Refer to the flowchart below for details of how the

369 detects motor status and how the starter status element further defines the condition

of the motor.

When the Starter Status is programmed, the type of breaker contact being used for

monitoring must be set. The following are the states of the breaker auxiliary contacts in

relation to the breaker:

•

52a, 52aa - open when the breaker contacts are open and closed when the

breaker contacts are closed

•

52b, 52bb - closed when the breaker contacts are open and open when the

breaker contacts are closed

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FIGURE 7–3: Flowchart Showing How Motor Status is Determined

7.6.2 Selection of Cool Time Constants

Thermal limits are not a black and white science and there is some art to setting a

protective relay thermal model. The definition of thermal limits mean different things to

different manufacturers and quite often, information is not available. Therefore, it is

important to remember what the goal of the motor protection thermal modeling is: to

thermally protect the motor (rotor and stator) without impeding the normal and expected

operating conditions that the motor will be subject to.

The thermal model of the 369 provides integrated rotor and stator heating protection. If

cooling time constants are supplied with the motor data they should be used. Since the

rotor and stator heating and cooling is integrated into a single model, use the longer of the

cooling time constants (rotor or stator).

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If however, no cooling time constants are provided, settings will have to be determined.

Before determining the cool time constant settings, the duty cycle of the motor should be

considered. If the motor is typically started and run continuously for very long periods of

time with no overload duty requirements, the cooling time constants can be large. This

would make the thermal model conservative. If the normal duty cycle of the motor involves

frequent starts and stops with a periodic overload duty requirement, the cooling time

constants will need to be shorter and closer to the actual thermal limit of the motor.

Normally motors are rotor limited during starting. Thus RTDs in the stator do not provide

the best method of determining cool times. Determination of reasonable settings for the

running and stopped cool time constants can be accomplished in one of the following

manners listed in order of preference.

1. The motor running and stopped cool times or constants may be provided on

the motor data sheets or by the manufacturer if requested. Remember that

the cooling is exponential and the time constants are one fifth the total time

to go from 100% thermal capacity used to 0%.

2. Attempt to determine a conservative value from available data on the motor.

See the following example for details.

3. If no data is available an educated guess must be made. Perhaps the motor

data could be estimated from other motors of a similar size or use. Note that

conservative protection is better as a first choice until a better understanding

of the motor requirements is developed. Remember that the goal is to protect

the motor without impeding the operating duty that is desired.

Example:

Motor data sheets state that the starting sequence allowed is 2 cold or 1 hot after which

you must wait 5 hours before attempting another start.

•

This implies that under a normal start condition the motor is using between 34 and

50% thermal capacity. Hence, two consecutive starts are allowed, but not three

(i.e. 34 × 3 > 100).

•

If the hot and cold curves or a hot/cold safe stall ratio are not available program

0.5 (1 hot / 2 cold starts) in as the hot/cold ratio.

Programming Start Inhibit ‘On’ makes a restart possible as soon as 62.5%

(50 × 1.25) thermal capacity is available.

After 2 cold or 1 hot start, close to 100% thermal capacity will be used. Thermal

capacity used decays exponentially (see 369 manual section on motor cooling for

calculation). There will be only 37% thermal capacity used after 1 time constant

which means there is enough thermal capacity available for another start.

Program 60 minutes (5 hours) as the stopped cool time constant. Thus after 2 cold

or 1 hot start, a stopped motor will be blocked from starting for 5 hours.

Since the rotor cools faster when the motor is running, a reasonable setting for the running

cool time constant might be half the stopped cool time constant or 150 minutes.

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7.6.3 Thermal Model

FIGURE 7–4: Thermal Model Block Diagram

UB, U/BUnbalance

I/PInput

IavgAverage Three Phase Current

IeqEquivalent Average Three Phase Current

IpPositive Sequence Current

InNegative Sequence Current

KConstant Multiplier that Equates In to Ip

FLCFull Load Current

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FLC TCRFLC Thermal Capacity Reduction setpoint

TCThermal Capacity used

RTD BIAS TCTC Value looked up from RTD Bias Curve

Note

If Unbalance input to thermal memory is enabled, the increase in heating is reflected in

the thermal model. If RTD Input to Thermal Memory is enabled, the feed-back from the

RTDs will correct the thermal model.

7.6.4 RTD Bias Feature

FIGURE 7–5: RTD Bias Feature

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Legend

TmaxRTD Bias Maximum Temperature Value

TminRTD Bias Minimum Temperature Value

Hottest RTDHottest Stator RTD measured

TCThermal Capacity Used

TC RTDThermal Capacity Looked up on RTD Bias Curve.

TC ModelThermal Capacity based on the Thermal Model

7.6.5 Thermal Capacity Used Calculation

The overload element uses a Thermal Capacity algorithm to determine an overload trip

condition. The extent of overload current determines how fast the Thermal Memory is

filled, i.e. if the current is just over FLC × O/L Pickup, Thermal Capacity slowly increases;

versus if the current far exceeds the FLC pickup level, the Thermal Capacity rapidly

increases. An overload trip occurs when the Thermal Capacity Used reaches 100%.

The overload current does not necessarily have to pass the overload curve for a trip to take

place. If there is Thermal Capacity already built up, the overload trip will occur much faster.

In other words, the overload trip will occur at the specified time on the curve only when the

Thermal Capacity is equal to zero and the current is applied at a stable rate. Otherwise, the

Thermal Capacity increases from the value prior to overload, until a 100% Thermal

Capacity is reached and an overload trip occurs.

It is important to chose the overload curve correctly for proper protection. In some cases it

is necessary to calculate the amount of Thermal Capacity developed after a start. This is

done to ensure that the 369 does not trip the motor prior to the completion of a start. The

actual filling of the Thermal Capacity is the area under the overload current curve.

Therefore, to calculate the amount of Thermal Capacity after a start, the integral of the

overload current most be calculated. Below is an example of how to calculate the Thermal

Capacity during a start:

Thermal Capacity Calculation:

4. Draw lines intersecting the acceleration curve and the overload curve. This is

illustrated in FIGURE 7–6: Thermal Limit Curves on page 7–246.

5. Determine the time at which the drawn line intersect, the acceleration curve

and the time at which the drawn line intersects the chosen overload curve.

6. Integrate the values that have been determined.

Table 7–3: Thermal Capacity Calculations

Time Period

(seconds)

Motor Starting

Current

(% of FLC)

Custom Curve

Trip Time

Total Accumulated Thermal

Capacity Used (%)

(seconds)

0 to 3

3 to 6

6 to 9

580

560

540

3 / 38 × 100 = 7.8%

(3 / 41 × 100) + 7.8% = 15.1%

(3 / 44 × 100) + 15.1% = 21.9%

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Table 7–3: Thermal Capacity Calculations

Time Period

(seconds)

Motor Starting

Current

(% of FLC)

Custom Curve

Trip Time

Total Accumulated Thermal

Capacity Used (%)

(seconds)

9 to 12

520

500

480

460

440

380

300

160

(3 / 47 × 100) + 21.9% = 28.3%

(2 / 51 × 100) + 28.3% = 32.2%

(1 / 56 × 100) + 32.2% = 34.0%

(1 / 61 × 100) + 34.0% = 35.6%

(1 / 67 × 100) + 35.6% = 37.1%

(1 / 90 × 100) + 37.1% = 38.2%

(1 / 149 × 100) + 38.2% = 38.9%

(1 / 670 × 100) + 38.9% = 39.0%

12 to 14

14 to 15

15 to 16

16 to 17

17 to 18

18 to 19

19 to 20

149

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Therefore, after this motor has completed a successful start, the Thermal Capacity would

have reached approximately 40%.

FIGURE 7–6: Thermal Limit Curves

Thermal limit curves illustrate thermal capacity used calculation during a start.

7.6.6 Start Inhibit

The Start Inhibit element of the 369 provides an accurate and reliable start protection

without unnecessary prolonged lockout times causing production down time. The lockout

time is based on the actual performance and application of the motor and not on the

worst case scenario, as other start protection elements.

The 369 Thermal Capacity algorithm is used to establish the lockout time of the Start

Inhibit element. Thermal Capacity is a percentage value that gives an indication of how hot

the motor is and is derived from the overload currents (as well as Unbalance currents and

RTDs if the respective biasing functions are enabled). The easiest way to understand the

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Thermal Modeling function of the 369 is to image a bucket that holds Thermal Capacity.

Once this imaginary bucket is full, an overload trip occurs. The bucket is filled by the

amount of overload current integrated over time and is compared to the programmed

overload curve to obtain a percentage value. The thermal capacity bucket is emptied

based on the programmed running cool time when the current has fallen below the Full

Load Current (FLC) and is running normally.

Upon a start, the inrush current is very high, causing the thermal capacity to rapidly

increase. The Thermal Capacity Used variable is compared to the amount of the Thermal

Capacity required to start the motor. If there is not enough thermal capacity available to

start the motor, the 369 blocks the operator from starting until the motor has cooled to a

level of thermal capacity to successfully start.

Assume that a motor requires 40% Thermal Capacity to start. If the motor was running in

overload prior to stopping, the thermal capacity would be some value; say 80%. Under

such conditions the 369 (with Start Inhibit enabled) will lockout or prevent the operator

from starting the motor until the thermal capacity has decreased to 60% so that a

successful motor start can be achieved. This example is illustrated in FIGURE 7–7:

Illustration of the Start Inhibit Functionality on page 7–248.

The lockout time is calculated as follows:

TCused

100 – TClearned

⎛

⎝

⎞

⎠

----------------------------------------

lockout time = stopped_cool_time_constant × ln

(EQ 7.1)

where:

TC_used = Thermal Capacity Used

TC_learned = Learned Thermal Capacity required to start

= one of two variables will be used:

stopped_cool_time

1. Learned cool time is enabled, or

2. Programmed stopped cool time

The learned start capacity is updated every four starts. A safe margin is built into the

calculation of the LEARNED START CAPACITY REQUIRED to ensure successful

completion of the longest and most demanding starts. The Learned Start Capacity is

calculated as follows:

Start_TC1 + Start_TC2 + Start_TC3 + Start_TC4 + Start_TC5

LEARNED START CAPACITY = ----------------------------------------------------------------------------------------------------------------------------------------------------

(EQ 7.2)

where:

Start_TC1 = the thermal capacity required for the first start

Start_TC2 = the thermal capacity required for the second start, etc.

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FIGURE 7–7: Illustration of the Start Inhibit Functionality

7.6.7 Two-Phase CT Configuration

This section illustrates how to use two CTs to sense three phase currents.

The proper configuration for using two CTs rather than three to detect phase current is

shown below. Each of the two CTs acts as a current source. The current from the CT on

phase ‘A’ flows into the interposing CT on the relay marked ‘A’. From there, the it sums with

the current flowing from the CT on phase ‘C’ which has just passed through the interposing

CT on the relay marked ‘C’. This ‘summed’ current flows through the interposing CT marked

‘B’ and splits from there to return to its respective source (CT). Polarity is very important

since the value of phase ‘B’ must be the negative equivalent of 'A' + 'C' for the sum of all

the vectors to equate to zero. Note that there is only one ground connection. Making two

ground connections creates a parallel path for the current

FIGURE 7–8: Two Phase Wiring

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In the two CT configuration, the currents sum vectorially at the common point of the two

CTs. The following diagram illustrates the two possible configurations. If one phase is

reading high by a factor of 1.73 on a system that is known to be balanced, simply reverse

the polarity of the leads at one of the two phase CTs (taking care that the CTs are still tied

to ground at some point). Polarity is important.

FIGURE 7–9: Vectors Showing Reverse Polarity

To illustrate the point further, the diagram here shows how the current in phases 'A' and 'C'

sum up to create phase 'B'.

FIGURE 7–10: Resultant Phase Current, Correctly Wired Two-Phase CT System

Once again, if the polarity of one of the phases is out by 180°, the magnitude of the

resulting vector on a balanced system will be out by a factor of 1.73.

FIGURE 7–11: Resultant Phase Current, Incorrectly Wired Two-Phase CT System

On a three wire supply, this configuration will always work and unbalance will be detected

properly. In the event of a single phase, there will always be a large unbalance present at

the interposing CTs of the relay. If for example phase ‘A’ was lost, phase ‘A’ would read zero

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while phases ‘B’ and ‘C’ would both read the magnitude of phase ‘C’. If on the other hand,

phase ‘B’ was lost, at the supply, ‘A’ would be 180× out of phase with phase ‘C’ and the

vector addition would be zero at phase ‘B’.

7.6.8 Ground Fault Detection on Ungrounded Systems

The 50:0.025 ground fault input is designed for sensitive detection of faults on a high

resistance grounded system. Detection of ground currents from 1 to 10 A primary

translates to an input of 0.5 mA to 5 mA into the 50:0.025 tap. Understanding this allows

the use of this input in a simple manner for the detection of ground faults on ungrounded

systems.

The following diagram illustrates how to use a wye-open delta voltage transformer

configuration to detect phase grounding. Under normal conditions, the net voltage of the

three phases that appears across the 50:0.025 input and the resistor is close to zero. Under

a fault condition, assuming the secondaries of the VTs to be 69 V, the net voltage seen by

the relay and the resistor is 3V_oor 3 × 69 V = 207 V.

FIGURE 7–12: Ground Fault Detection on Ungrounded Systems

Since the wire resistance should be relatively small in comparison to the resistor chosen,

the current flow will be a function of the fault voltage seen on the open delta transformer

divided by the chosen resistor value plus the burden of the 50:0.025 input (1200 Ω).

Example:

If a pickup range of 10 to 100 V is desired, the resistor should be chosen as follows:

1. 1 to 10 A pickup on the 2000:1 tap = 0.5 mA – 5 mA.

2. 10 V / 0.5 mA = 20 kΩ.

3. If the resistor chosen is 20 kΩ – 1.2 kΩ = 18.8 kΩ, the wattage should be greater than

E /R, approximately (207 V) / 18.8 kΩ = 2.28 W. Therefore, a 5 W resistor will suffice.

Note

The VTs must have a primary rating equal or greater than the line to line voltage, as

this is the voltage that will be seen by the unfaulted inputs in the event of a fault.

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7.6.9 RTD Circuitry

This section illustrates the functionality of the RTD circuitry in the 369 Motor Protection

Relay.

FIGURE 7–13: RTD Circuitry

A constant current source sends 3 mA DC down legs A and C. A 6 mA DC current returns

down leg B. It may be seen that:

(V_AB= V_LeadA+ V_LeadB

)

and V_CB= V_LeadC+ V_RTD+ V_LeadB

(EQ 7.3)

(V_AB= V_comp+ V_return

)

and V_CB= V_hot+ V_RTD+ V_return

(EQ 7.4)

The above holds true providing that all three leads are the same length, gauge, and

material, hence the same resistance.

R_LeadA= R_LeadB= R_LeadC= R_Lead

(EQ 7.5)

R_comp= R_return= R_hot= R_Lead

(EQ 7.6)

Electronically, subtracting V_ABfrom V_BCleaves only the voltage across the RTD. In this

manner lead length is effectively negated:

_CB– V_AB= (V_Lead+ V_RTD+ V_Lead) – (V_Lead+ V_Lead)

(EQ 7.7)

_CB– V_AB= V_RTD

7.6.10 Reduced RTD Lead Number Application

The 369 requires three leads to be brought back from each RTD: Hot, Return, and

Compensation. In certain situations this can be quite expensive. However, it is possible to

reduce the number of leads so that three are required for the first RTD and only one for

each successive RTD. Refer to the following diagram for wiring configuration.

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FIGURE 7–14: Reduced Wiring RTDs

The Hot line for each RTD is run as usual for each RTD. However, the Compensation and

Return leads need only be run for the first RTD. At the motor RTD terminal box, connect the

RTD Return leads together with as short as possible jumpers. At the 369 relay, the

Compensation leads must be jumpered together.

Note that an error is produced on each RTD equal to the voltage drop across the RTD

return jumper. This error increases for each successive RTD added as:

_RTD1= V_RTD1

V_RTD2= V_RTD2+ V_J3

V_RTD3= V_RTD3+ V_J3+ V_J4

V_RTD4= V_RTD4+ V_J3+ V_J4+ V_J5, etc....

This error is directly dependent on the length and gauge of the jumper wires and any error

introduced by a poor connection. For RTD types other than 10C, the error introduced by the

jumpers is negligible.

Although this RTD wiring technique reduces the cost of wiring, the following disadvantages

must be noted:

1. There is an error in temperature readings due to lead and connection

resistances. Not recommended for 10C RTDs.

2. If the RTD Return lead to the 369 or one of the jumpers breaks, all RTDs from

the point of the break onwards will read open.

3. If the Compensation lead breaks or one of the jumpers breaks, all RTDs from

the point of the break onwards will function without any lead compensation.

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7.6.11 Two Wire RTD Lead Compensation

An example of how to add lead compensation to a two wire RTD is shown below.

FIGURE 7–15: 2 Wire RTD Lead Compensation

The compensation lead would be added and it would compensate for the Hot and the

Return assuming they are all of equal length and gauge. To compensate for resistance of

the Hot and Compensation leads, a resistor equal to the resistance of the Hot lead could be

added to the compensation lead, though in many cases this is unnecessary.

7.6.12 Auto Transformer Starter Wiring

FIGURE 7–16: Auto Transformer, Reduced Voltage Starting Circuit

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Chapter 8: Testing

Testing

8.1 Test Setup

8.1.1 Introduction

This chapter demonstrates the procedures necessary to perform a complete functional

test of all the 369 hardware while also testing firmware/hardware interaction in the

process. Testing of the relay during commissioning using a primary injection test set will

ensure that CTs and wiring are correct and complete.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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TEST SETUP

CHAPTER 8: TESTING

8.1.2 Secondary Injection Test Setup

FIGURE 8–1: Secondary Injection Test Setup

8–256

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CHAPTER 8: TESTING

HARDWARE FUNCTIONAL TESTING

8.2 Hardware Functional Testing

8.2.1 Phase Current Accuracy Test

The 369 specification for phase current accuracy is 0.5% of 2 × CT when the injected

current is less than 2 × CT. Perform the steps below to verify accuracy.

1. Alter the following setpoint:

S2 SYSTEM SETUP Ø CT / VT SETUP Ø PHASE CT PRIMARY: 1000 A

2. Measured values should be within 10A of expected. Inject the values shown

in the table below and verify accuracy of the measured values. View the

measured values in:

A2 METERING DATA Ø CURRENT METERING

INJECTED INJECTED EXPECTED MEASURE MEASURE MEASURE

CURRENT CURRENT CURRENT

1 A UNIT

5 A UNIT

READING

CURRENT CURRENT CURRENT

PHASE A PHASE B PHASE C

0.1 A

0.5 A

100 A

0.2 A

0.5 A

1 A

1.0 A

2.5 A

5 A

200 A

500 A

1000 A

1500 A

2000 A

1.5 A

2 A

7.5 A

10 A

8.2.2 Voltage Input Accuracy Test

The 369 specification for voltage input accuracy is 1.0% of full scale (240 V). Perform the

steps below to verify accuracy.

1. Alter the following setpoints:

S2 SYSTEM Ø CT/VT SETUP Ø VT CONNECTION TYPE: Wye

S2 SYSTEM SETUP Ø CT/VT SETUP Ø VOLTAGE TRANSFORMER RATIO:

2. Measured values should be within 24 V (±1 × 240 × 10) of expected. Apply the

voltage values shown in the table and verify accuracy of the measured values.

View the measured values in:

A2 METERING DATA Ø VOLTAGE METERING

APPLIED LINE- EXPECTED MEASURED MEASURED MEASURED

NEUTRAL

VOLTAGE

VOLTAGE VOLTAGE A- VOLTAGE B- VOLTAGE C-

READING

30 V

300 V

50 V

500 V

100 V

150 V

200 V

240 V

1000 V

1500 V

2000 V

2400 V

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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HARDWARE FUNCTIONAL TESTING

CHAPTER 8: TESTING

8.2.3 Ground (1 A / 5 A) Accuracy Test

The 369 specification for the 1 A/5 A ground current input accuracy is 0.5% of 1 × CT for

the 5 A input and 0.5% of 5 × CT for the 1 A input. Perform the steps below to verify

accuracy.

5A Input:

1. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø GROUND CT TYPE: 5A Secondary

S2 SYSTEM SETUP Ø CT/VT SETUP Ø GROUND CT PRIMARY: 1000 A

2. Measured values should be 5 A. Inject the values shown in the table below

into one phase only and verify accuracy of the measured values. View the

measured values in A2 METERING DATA Ø CURRENT METERING

INJECTED

CURRENT

5 A UNIT

EXPECTED

CURRENT

READING

MEASURED

GROUND

CURRENT

0.5 A

100 A

1.0 A

2.5 A

5 A

200 A

500 A

1000 A

1A Input:

1. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø GROUND CT TYPE: 1A Secondary

S2 SYSTEM SETUP Ø CT/VT SETUP Ø GROUND CT PRIMARY: 1000 A

2. Measured values should be 25 A. Inject the values shown in the table below

into one phase only and verify accuracy of the measured values. View the

measured values in A2 METERING DATA Ø CURRENT METERING

INJECTED

CURRENT

1 A UNIT

EXPECTED

CURRENT

READING

MEASURED

GROUND

CURRENT

0.1 A

100 A

0.2 A

0.5 A

1.0 A

200 A

500 A

1000 A

8.2.4 50:0.025 Ground Accuracy Test

The 369 specification for GE Multilin 50:0.025 ground current input accuracy is 0.5% of CT

rated primary (25 A). Perform the steps below to verify accuracy.

1. Alter the following setpoint:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø GROUND CT TYPE: MULTILIN

50:0.025

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 8: TESTING

HARDWARE FUNCTIONAL TESTING

2. Measured values should be within 0.125 A of expected. Inject the values

shown below either as primary values into a GE Multilin 50:0.025 Core Balance

CT or as secondary values that simulate the core balance CT. Verify accuracy

of the measured values. View the measured values in A2 METERING DATA Ø

CURRENT METERING

PRIMARYINJECTED

CURRENT 50:0.025

SECONDARY

INJECTED

CURRENT

EXPECTED

CURRENT

READING

MEASURED

GROUND

CURRENT

0.25 A

1 A

0.125 mA

0.25 A

0.5 mA

5 mA

1.00 A

10 A

25 A

10.00 A

25.00 A

12.5 mA

8.2.5 RTD Accuracy Test

1. The 369 specification for RTD input accuracy is 2°. Alter the following

setpoints:

S6 RTD TEMPERATURE Ø RTD TYPE Ø STATOR RTD TYPE: “100 ohm

Platinum” (select desired type)

2. Measured values should be 2°C or ±4°F. Alter the resistances applied to the

RTD inputs as per the table below to simulate RTDs and verify accuracy of the

measured values. View the measured values in:

A2 METERING DATA Ø LOCAL RTD (and/or REMOTE RTD if using the RRTD Module)

3. Select the preferred temperature units for the display. Alter the following

setpoint:

S1 369 SETUP Ø DISPLAY PREFERENCES Ø TEMPERATURE DISPLAY:

“Celsius” (or “Fahrenheit” if preferred)

4. Repeat the above measurements for the other RTD types (120 ohm Nickel,

100 ohm Nickel and 10 ohm Copper)

APPLIED

RESISTANCE

100 Ohm

EXPECTED RTD

TEMPERATURE READING

MEASURED RTD TEMPERATURE

9 SELECT ONE: ____(°C) ____(°F)

CELSIUS

FAHRENHEIT

10 11 12

PLATINUM

84.27 ohms

100.00 ohms

119.39 ohms

138.50 ohms

157.32 ohms

175.84 ohms

–40°C

–40°F

32°F

0°C

50°C

122°F

212°F

302°F

392°F

100°C

150°C

200°C

APPLIED

RESISTANCE

120 Ohm

EXPECTED RTD

TEMPERATURE READING

MEASURED RTD TEMPERATURE

9 SELECT ONE: ____(°C) ____(°F)

CELSIUS

–40°C

0°C

FAHRENHEIT

10 11 12

NICKEL

92.76 ohms

–40°F

32°F

120.00 ohms

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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HARDWARE FUNCTIONAL TESTING

CHAPTER 8: TESTING

APPLIED

EXPECTED RTD

TEMPERATURE READING

MEASURED RTD TEMPERATURE

9 SELECT ONE: ____(°C) ____(°F)

RESISTANCE

120 Ohm

CELSIUS

FAHRENHEIT

3 10 11 12

NICKEL

157.74 ohms

200.64 ohms

248.95 ohms

303.46 ohms

50°C

122°F

212°F

302°F

392°F

100°C

150°C

200°C

APPLIED

RESISTANC

E 100 Ohm

NICKEL

EXPECTED RTD

TEMPERATURE

READING

MEASURED RTD TEMPERATURE

9 SELECT ONE: ____(°C) ____(°F)

CELSIUS

FAHRENHE

10 11 12

79.13 ohms

100.0 ohms

129.1 ohms

161.8 ohms

198.7 ohms

240.0 ohms

–40°C

–40°F

32°F

0°C

50°C

122°F

212°F

302°F

392°F

100°C

150°C

200°C

APPLIED

RESISTANC

E 10 Ohm

EXPECTED RTD

MEASURED RTD TEMPERATURE

TEMPERATURE

READING

9 SELECT ONE: ____(°C) ____(°F)

COPPER

CELSIUS

FAHRENHE

10 11 12

7.49 ohms

9.04 ohms

10.97 ohms

12.90 ohms

14.83 ohms

16.78 ohms

–40°C

0°C

–40°F

32°F

50°C

122°F

212°F

302°F

392°F

100°C

150°C

200°C

8.2.6 Digital Inputs

The digital inputs can be verified easily with a simple switch or pushbutton. Perform the

steps below to verify functionality of the digital inputs.

1. Open switches of all of the digital inputs.

2. View the status of the digital inputs in A1 STATUS Ø DIGITAL INPUT STATUS

3. Close switches of all of the digital inputs.

4. View the status of the digital inputs in A1 STATUS Ø DIGITAL INPUT STATUS

INPUT

EXPECTED

STATUS

(SWITCH OPEN)

9 PASS

8 FAIL

EXPECTED

STATUS

(SWITCH

CLOSED)

9 PASS

8 FAIL

SPARE

Open

Shorted

DIFFERENTIAL RELAY

SPEED SWITCH

Shorted

8–260

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 8: TESTING

HARDWARE FUNCTIONAL TESTING

INPUT

EXPECTED

STATUS

(SWITCH OPEN)

9 PASS

8 FAIL

EXPECTED

STATUS

(SWITCH

CLOSED)

9 PASS

8 FAIL

ACCESS SWITCH

Open

Shorted

EMERGENCY RESTART

EXTERNAL RESET

Shorted

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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HARDWARE FUNCTIONAL TESTING

CHAPTER 8: TESTING

8.2.7 Analog Inputs and Outputs

The 369 specification for analog input and analog output accuracy is 1% of full scale.

Perform the steps below to verify accuracy.

4 to 20mA ANALOG INPUT:

1. Alter the following setpoints:

S10 ANALOG OUTPUTS Ø ANALOG OUTPUT 1 Ø ANALOG RANGE: 4-20

mA (repeat for analog inputs 2 to 4)

2. Analog output values should be 0.2 mA on the ammeter. Force the analog

outputs using the following setpoints:

S11 TESTING Ø TEST ANALOG OUTPUTS Ø FORCE ANALOG OUTPUT 1:

(enter desired percent, repeat for analog outputs 2 to 4)

3. Verify the ammeter readings for all the analog outputs

4. Repeat 1 to 3 for the other forced output settings

ANALOG

EXPECTED

MEASURED AMMETER READING

(mA)

OUTPUT FORCE AMMETER READING

VALUE

4 mA

8 mA

12 mA

16 mA

20 mA

100

0 to 1mA Analog Input:

1. Alter the following setpoints:

S10 ANALOG OUTPUTS Ø ANALOG OUTPUT 1 Ø ANALOG RANGE: “0-1

mA” (repeat for analog inputs 2 to 4)

2. Analog output values should be 0.01 mA on the ammeter. Force the analog

outputs using the following setpoints:

S11 TESTING Ø TEST ANALOG OUTPUTS Ø FORCE ANALOG OUTPUT 1:

“0%”

(enter desired percent, repeat for analog outputs 2 to 4)

3. Verify the ammeter readings for all the analog outputs

4. Repeat 1 to 3 for the other forced output settings.

ANALOG

OUTPUT

FORCE VALUE

EXPECTED

AMMETER

READING

MEASURED AMMETER READING (mA)

0 mA

0.25 mA

0.5 mA

0.75 mA

1.0 mA

100

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CHAPTER 8: TESTING

HARDWARE FUNCTIONAL TESTING

0 to 20mA Analog Input:

1. Alter the following setpoints:

S10 ANALOG OUTPUTS Ø ANALOG OUTPUT 1 Ø ANALOG RANGE: “0-20

mA” (repeat for analog inputs 2 to 4)

2. Analog output values should be 0.2 mA on the ammeter. Force the analog

outputs using the following setpoints:

S11 TESTING Ø TEST ANALOG OUTPUTS Ø FORCE ANALOG OUTPUT 1:

“0%”

(enter desired percent, repeat for analog outputs 2 to 4)

3. Verify the ammeter readings for all the analog outputs

4. Repeat steps 1 to 3 for the other forced output settings.

ANALOG

OUTPUT

FORCE VALUE

EXPECTED

AMMETER

READING

MEASURED AMMETER READING (mA)

0 mA

100

5 mA

10 mA

15 mA

20 mA

8.2.8 Output Relays

To verify the functionality of the output relays, perform the following steps:

1. Use the following setpoints:

S11 TESTING Ø TEST OUTPUT RELAYS Ø FORCE TRIP RELAY: “Energized”

S11 TESTING Ø TEST OUTPUT RELAYS Ø FORCE TRIP RELAY

DURATION: “Static”

2. Using the above setpoints, individually select each of the other output relays

(AUX 1, AUX 2 and ALARM) and verify operation.

FORCE

OPERATIO

EXPECTED MEASUREMENT (9 for

ACTUAL MEASUREMENT (9 for

SHORT)

SETPOINT

no nc no nc no nc no nc no nc no nc no nc no nc

R1 Trip

R2 Auxiliary

R3 Auxiliary

R4 Alarm

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ADDITIONAL FUNCTIONAL TESTING

CHAPTER 8: TESTING

8.3 Additional Functional Testing

8.3.1 Overload Curve Test

The 369 specification for overload curve timing accuracy is 100 ms or 2% of time to trip.

Pickup accuracy is as per current inputs ( 0.5% of 2 × CT when the injected current is

< 2 × CT; 1% of 20 × CT when the injected current is ≥ 2 × CT).

1. Perform the steps below to verify accuracy. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø PHASE CT PRIMARY: “1000”

S2 SYSTEM SETUP Ø CT/VT SETUP Ø MOTOR FULL LOAD AMPS FLA:

“1000”

S3 OVERLOAD PROTECTION Ø OVERLOAD CURVES Ø SELECT CURVE

STYLE:

“Standard”

S3 OVERLOAD PROTECTION Ø OVERLOAD CURVES Ø STANDARD

OVELOAD CURVE NUMBER: “4”

S3 OVERLOAD PROTECTION Ø THERMAL MODEL Ø OVERLOAD

PICKUP LEVEL: “1.10”

S3 OVERLOAD PROTECTION Ø THERMAL MODEL Ø UNBALANCE BIAS

K FACTOR: “0”

S3 OVERLOAD PROTECTION Ø THERMAL MODEL Ø HOT/COLD SAFE

STALL RATIO: “1.00”

S3 OVERLOAD PROTECTION Ø THERMAL MODEL Ø ENABLE RTD

BIASING: “No”

2. Any trip must be reset prior to each test. Short the emergency restart

terminals momentarily immediately prior to each overload curve test to

ensure that the thermal capacity used is zero. Failure to do so will result in

shorter trip times. Inject the current of the proper amplitude to obtain the

values as shown and verify the trip times. Motor load may be viewed in A2

METERING DATA Ø CURRENT METERING

Thermal capacity used and estimated time to trip may be viewed in A1 STATUS Ø MOTOR

STATUS

AVERAGE

PHASE

CURRENT

DISPLAYED

INJECTE PICKU

EXPECTED

TIME TO

TRIP

TOLERANCE

RANGE

MEASURE

D TIME

TO TRIP

CURREN LEVEL

1 A UNIT

1050 A

1200 A

1750 A

3000 A

6000 A

10000 A

1.05 A

1.20 A

1.75 A

3.0 A

1.05

1.20

1.75

3.00

6.00

10.00

never

N/A

795.44 s

169.66 s

43.73 s

9.99 s

779.53 to 811.35 s

166.27 to 173.05 s

42.86 to 44.60 s

9.79 to 10.19 s

6.0 A

10.0 A

5.55 s

5.44 to 5.66 s

8–264

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 8: TESTING

ADDITIONAL FUNCTIONAL TESTING

8.3.2 Power Measurement Test

The 369 specification for reactive and apparent power is 1.5% of 2 × CT × VT full scale at

_avg< 2 × CT. Perform the steps below to verify accuracy.

1. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø PHASE CT PRIMARY: “1000”

S2 SYSTEM SETUP Ø CT/VT SETUP Ø VT CONNECTION TYPE: “Wye”

S2 SYSTEM SETUP Ø CT/VT SETUP Ø VT RATIO: “10.00:1”

2. Inject current and apply voltage as per the table below. Verify accuracy of the

measured values. View the measured values in A2 METERING DATA Ø POWER

METERING

INJECTED CURRENT / APPLIED

VOLTAGE (Ia is reference vector)

POWER QUANTITY

POWER FACTOR

1 A UNIT

5 A UNIT

EXPECTE TOLERANC MEASURE EXPECTE MEASURE

E RANGE

Ia = 1 A∠0°

Ia = 5 A∠0°

Ib = 1 A∠120°

Ib = 5 A∠120°

Ic = 1 A∠240°

Ic = 5 A∠240°

3352 to

3496 kW

+3424 kW

0.95 lag

Va = 120 V∠342°

Vb = 120 V∠102°

Vc = 120 V∠222°

Va = 120 V∠342°

Vb = 120 V∠102°

Vc = 120 V∠222°

Ia = 1 A∠0°

Ia = 5 A∠0°

Ib = 1 A∠120°

Ic = 1 A∠240°

Va = 120 V∠288°

Vb = 120 V∠48°

Vc = 120 V∠168°

Ib = 5 A∠120°

Ic = 5 A∠240°

Va = 120 V∠288°

Vb = 120 V∠48°

Vc = 120 V∠168°

+3424 kva 3352 to

3496 kvar

0.31 lag

8.3.3 Voltage Phase Reversal Test

The 369 can detect voltage phase rotation and protect against phase reversal. To test the

phase reversal element, perform the following steps:

1. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø VT CONNECTION TYPE:

“Wye” or “Open Delta”

S7 VOLTAGE ELEMENTS Ø PHASE REVERSAL Ø PHASE REVERSAL

TRIP: “On”

S7 VOLTAGE ELEMENTS Ø PHASE REVERSAL Ø ASSIGN TRIP RELAYS:

“Trip”

S2 SYSTEM SETUP Ø CT/VT SETUP Ø SYSTEM PHASE SEQUENCE: “ABC”

2. Apply voltages as per the table below. Verify the 369 operation on voltage

phase reversal.

APPLIED VOLTAGE

EXPECTED RESULT

OBSERVED RESULT

8 NO TRIP

9 PHASE REVERSAL TRIP 9 PHASE REVERSAL TRIP

Va = 120 V∠0°

Vb = 120 V∠120°

Vc = 120 V∠240°

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ADDITIONAL FUNCTIONAL TESTING

CHAPTER 8: TESTING

APPLIED VOLTAGE

EXPECTED RESULT

OBSERVED RESULT

8 NO TRIP

9 PHASE REVERSAL TRIP 9 PHASE REVERSAL TRIP

Va = 120 V∠0°

Vb = 120 V∠240°

Vc = 120 V∠120°

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369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER 8: TESTING

ADDITIONAL FUNCTIONAL TESTING

8.3.4 Short Circuit Test

The 369 specification for short circuit timing is +40 ms or 0.5% of total time. The pickup

accuracy is as per the phase current inputs. Perform the steps below to verify the

performance of the short circuit element.

1. Alter the following setpoints:

S2 SYSTEM SETUP Ø CT/VT SETUP Ø PHASE CT PRIMARY: “1000”

S4 CURRENT ELEMENTS Ø SHORT CIRCUIT Ø SHORT CIRCUIT TRIP:

“On”

S4 CURRENT ELEMENTS Ø SHORT CIRCUIT Ø ASSIGN TRIP RELAYS:

“Trip”

S4 CURRENT ELEMENTS Ø SHORT CIRCUIT Ø SHORT CIRCUIT

PICKUP LEVEL:

“5.0 x CT”

S4 CURRENT ELEMENTS Ø SHORT CIRCUIT Ø ADD S/C DELAY: “0”

2. Inject current as per the table below, resetting the unit after each trip by

pressing the [RESET] key, and verify timing accuracy. Pre-trip values may be

viewed in

A1 STATUS Ø LAST TRIP DATA

INJECTED CURRENT

5 A UNIT 1 A UNIT

30 A

TIME TO TRIP (ms)

EXPECTED MEASURED

6 A

8 A

< 40 ms

40 A

50 A

10 A

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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ADDITIONAL FUNCTIONAL TESTING

CHAPTER 8: TESTING

8–268

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Appendix A: 369 Drawout Options -

MOD

369 Drawout Options

MOD

A.1 MOD Options Table

Table A–1: MOD Options Table

369-D/O

Phase CT Ground CT

50:0.025

Relay Failsafe Code

Trip

NFS

Alarm

NFS

Aux1

NFS

Aux2

NFS

Relay Contact Arrangement

Alarm

N.O.

N.C.

Aux1

N.O.

N.C.

N.O.

N.C.

Aux2

N.O.

N.C.

N.O.

N.C.

N.O.

N.C.

N.O.

N.C.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

A–269

MOD OPTIONS TABLE

CHAPTER A: 369 DRAWOUT OPTIONS - MOD

Note

1. FS = Fail Safe: A failsafe relay is one that changes state when control power is

applied to the 369.

NFS = Non Fail Safe: A non-failsafe relay is one that remains in its shelf state

with control power applied to the 369 and no trips or alarms present.

2. N.O. and N.C. are defined as the open and closed contacts of an output relay

with control power applied to the 369 and no trips or alarms present.

EXAMPLE-1:

For a 369 Drawout with MOD options: 369-D/O-151

151 = CTs option 1, Relay Failsafe Code 5, and Relay Contact Arrangement 1

EXAMPLE-2:

369 Drawout with MOD option: 369-D/O-267

267 = CT option 2, Relay Failsafe Code 6, and Relay Contact Arrangement 7

A–270

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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Multilin

369 Motor Management Relay

Appendix B: Revisions

Revisions

B.1 Change Notes

B.1.1 Revision History

Table B–1: Revision History

MANUAL P/N

1601-0077-B1

1601-0077-B2

1601-0077-B3

1601-0077-B4

1601-0077-B5

1601-0077-B6

1601-0077-B7

1601-0777-B8

1601-0777-B9

1601-0777-BA

1601-0077-BB

1601-0077-BC

1601-0077-BD

1601-0077-BE

1601-0077-BF

1601-0077-BG

1601-0077-BH

1601-0077-BJ

369 REVISION

RELEASE DATE

53CMB105.000

53CMB110.000

53CMB120.000

53CMB130.000

53CMB142.000

53CMB145.000

53CMB160.000

53CMB161.000

53CMB17x.000

53CMB18x.000

53CMB19x.000

53CMB20x.000

53CMB21x.000

53CMB22x.000

53CMB23x.000

53CMB24x.000

07 May 1999

08 June 1999

15 June 1999

04 August 1999

15 October 1999

03 January 2000

03 April 2000

14 June 2000

12 October 2000

19 October 2000

09 February 2001

15 June 2001

01 August 2002

01 March 2004

05 November 2004

11 April 2005

19 September 2005

21 November 2005

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

B–269

CHANGE NOTES

CHAPTER B: REVISIONS

Table B–1: Revision History

MANUAL P/N

1601-0077-BK

1601-0077-BL

1601-0077-BM

1601-0077-BN

1601-0077-BP

1601-0077-BR

1601-0077-BS

1601-0077-BT

1601-0077-BU

1601-0077-BV

369 REVISION

RELEASE DATE

53CMB25x.000

53CMC310.000

53CMC320.000

53CMC330.000

53CMC340.000

May 15, 2006

June 7, 2007

February 29, 2008

June 6, 2008

August 8, 2008

Oct ober 17, 2008

March 6, 2009

March 23, 2010

June 23, 2010

June 27, 2011

Table B–2: Major Updates for 369-BV

SECTION

CHANGES

New manual revision number: BV

Fieldbus Loss of Communications - change to DeviceNet timing

accuracy spec

2.2.4

Table B–3: Major Updates for 369-BU

SECTION

CHANGES

New manual revision number: BU

5.2.3

Fieldbus Loss of Communications added

Table B–4: Major Updates for 369-BT

SECTION

CHANGES

New manual revision number: BT

Index corrected and updated

Index

Table B–5: Major Updates for 369-BS

SECTION

CHANGES

New manual revision number: BS

2.2.4

Fieldbus Loss of Comms section added

B–270

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER B: REVISIONS

CHANGE NOTES

Table B–6: Major Updates for 369-BR

SECTION

CHANGES

New manual revision number: BR

5.2.3

7.2.1 (FAQ)

Note added, re cycling power supply.

Q/A added, re cycling of power supply.

Table B–7: Major Updates for 369-BP

SECTION

CHANGES

New manual revision number: BP

Note added, re editing of RTD name and General Switch Name via

EnerVista only.

5.7.2/5.10.1

Table B–8: Major Updates for 369-BN

SECTION

CHANGES

New manual revision number: BN

2.2.8/2.2.11

2.2.10

Add T-Code rating to Specifications/Type Tests.

Add new UL file number to UL Listings.

Update Hazardous Location note.

2.2.2

3.3.3

Add Reboot Time information.

Table B–9: Major Updates for 369-BM

SECTION

CHANGES

New manual revision number: BM

Chapter 9 - Communications - removed and a separate

Communications Guide created from it.

Chapter 9

Chapters 2, 3, 5, 6 2-speed motor feature added

Chapters 5, 6,

Datalogger feature added

Comm Guide

Chapter 3

Chapter 2

5.3.5

New Forward/Reverse wiring diagram added

Update Control Power specs.

Latched trip and alarm note added

6.6.1

Motor Speed and Hottest Stator display information added/changed

Motor Start Data Logger changes

4.6.4

4.6.5

Motor Health Report changes

5.2.3

Profibus Loss of Communication display change

Phase Reversal info changes, new diagram added

Phasor information changes

5.7.4

6.3.9

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

B–271

CHANGE NOTES

CHAPTER B: REVISIONS

Table B–9: Major Updates for 369-BM

SECTION

Chapter 5

CHANGES

MMI Display hiding changes

5.7.4

6.2.2

Phase Reversal description changes

Speed of Last Trip MMI display added

Table B–10: Major Updates for 369-BL

CHANGES

Added new UL and CSA information

Deleted MOD 502 hazardous location option

Fig. 3.3.10 - Clarified that resistance is per-lead, and not total resistance

Firmware revision to 3.10

Increase number of event records from 250 to 512

New feature added: Undervoltage Autorestart

New feature added: Motor Start Data Logger

New feature added: Enhanced Motor Learned Data

New feature added: Detect If 369 Is Communicating With RRTDs

New feature added: New Order Code Item For "MMI Display Style"

New feature added: DeviceNet Poll Data Groups

Table B–11: Major Updates for 369-BK

CHANGES

Added new START CONTROL RELAY TIMER setpoint under the Reduced Voltage Starting

Added new Modbus register for “Starts Per Hour Lockout Time” at address 0x02CA

Section 5.10.5: SPEED SWITCH modified to reflect the correct front panel display order

Table in section 8.2.3 updated to reflect correct ground fault CT range

Broadcast date and time in Modbus address corrected (0x00F0 and 0x00F2)

DeviceNet Assembly object, class code 04h, instance 68h, attribute 03 access type

corrected to “GET”

Added ODVA DeviceNet CONFORMANCE TESTED™ certification to technical

specifications

Updated section 2.2.10: TYPE TEST STANDARDS to reflect updates to IEC and EN test

numbers

Table B–12: Major Updates for 369-BJ

CHANGES

Updated custom curve ranges from “0 to 32767 s” to “0 to 65534 s”

B–272

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER B: REVISIONS

CHANGE NOTES

Table B–13: Major Updates for 369-BH

CHANGES

Updated manual for the Profibus-DPV1 option

Added BLOCK PROTECTION FUNCTIONS and FORCE OUTPUT RELAYS sections

Added communications sections of Chapter 9

Table B–14: Major Updates for 369-BG

CHANGES

Updated the 369 order code for the Harsh Environment option

Added setpoints for DeviceNet communications and Starter Operation Monitor

Added DeviceNet communications section to Chapter 9

Table B–15: Major Updates for 369-BF

CHANGES

Changes made to Modbus/TCP interface

Additions for variable frequency functionality

Table B–16: Major Updates for 369-BE

CHANGES

Added MOTOR LOAD AVERAGING INTERVAL setpoint to the Thermal Model feature.

Added starter failure and energy metering to analog output parameters

Table B–17: Major Updates for 369-BD

CHANGES

Added DEFAULT TO HOTTEST STATOR RTD TEMP setpoint to default messages.

Updated Section 5.3.7: AUTORESTART and Figure 5–5: AUTORESTART LOGIC.

Updated EVENT RECORDER section to reflect 250 events

Added EVENT RECORDS setpoints to S1 369 SETUP section.

Added Filter/Safety Ground question to Section 7.2.1: FREQUENTLY ASKED QUESTIONS.

Updated MEMORY MAP and MEMORY MAP FORMATS tables.

Table B–18: Major Updates for 369-BC

CHANGES

Updated ORDERING TABLE to reflect Modbus/TCP option

Updated Figure 1–1: FRONT AND REAR VIEW to 840702BF

Updated Figure 3–4: TYPICAL WIRING

Added new Modbus/TCP setpoints and description in Section 5.2.4: COMMUNICATIONS

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

B–273

CHANGE NOTES

CHAPTER B: REVISIONS

Table B–18: Major Updates for 369-BC

CHANGES

Updated Figures 5–3 and 5–4, REDUCED VOLTAGE STARTER AUXILIARY INPUTS

Updated Section 7.2.4: CT SELECTION to fix errors in the application example

Updated Figure 8–1: SECONDARY INJECTION TEST SETUP

Updated Table 9–1: SETPOINTS TABLE to include new Modbus/TCP setpoints

Updated MEMORY MAP and MEMORY MAP FORMATS to include new Modbus/TCP

setpoints

Table B–19: Major Updates for 369-BB

CHANGES

Updated Figure 1–1: FRONT AND REAR VIEW

Corrected errors in Table 3–1: TERMINAL LIST

Updated Figure 3–4: TYPICAL WIRING

Removed SINGLE VT WYE/DELTA connection diagram in Chapter 3 (feature no longer

supported)

Removed ENABLE SINGLE VT OPERATION setpoint from Section 5.3.2: CT/VT SETUP

(feature no longer supported)

Added new Section 5.3.7: AUTORESTART

Table B–20: Major Updates for 369-BA

CHANGES

There were no changes to the content of the manual for this release.

Table B–21: Major Updates for 369-B9

CHANGES

Updated Figure 3-4: TYPICAL WIRING

Updated Figure 3-15: REMOTE RTD MODULE

Added menu item PROFIBUS ADDRESS to the 369 Setup Communications menu

Added menu item CLEAR ENERGY DATA to the 369 Setup Clear/Preset Data menu

Added Section 10.2: PROFIBUS PROTOCOL to Communications chapter

Table B–22: Major Updates for 369-B8

CHANGES

Firmware version 53CMB145.000 contains only minor software changes that do not

affect the functionality of the 369 or the 1601-0777-B8 manual contents.

B–274

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHAPTER B: REVISIONS

WARRANTY

B.2 Warranty

B.2.1 Warranty Information

GE MULTILIN RELAY WARRANTY

General Electric Multilin (GE Multilin) warrants each relay it manufactures to

be free from defects in material and workmanship under normal use and

service for a period of 24 months from date of shipment from factory.

In the event of a failure covered by warranty, GE Multilin will undertake to

repair or replace the relay providing the warrantor determined that it is

defective and it is returned with all transportation charges prepaid to an

authorized service centre or the factory. Repairs or replacement under

warranty will be made without charge.

Warranty shall not apply to any relay which has been subject to misuse,

negligence, accident, incorrect installation or use not in accordance with

instructions nor any unit that has been altered outside a GE Multilin

authorized factory outlet.

GE Multilin is not liable for special, indirect or consequential damages or for

loss of profit or for expenses sustained as a result of a relay malfunction,

incorrect application or adjustment.

For complete text of Warranty (including limitations and disclaimers), refer to

GE Multilin Standard Conditions of Sale.

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

B–275

WARRANTY

CHAPTER B: REVISIONS

B–276

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

Digital Energy

Multilin

369 Motor Management Relay

Index

Numerics

2 PHASE CT CONFIGURATION ......................................................................... 7-248

269-369 CONVERSION TERMINAL LIST ..............................................................3-31

369

pc interface .......................................................................................................4-60

ground CT installation........................................................................................3-55

input ............................................................................................................... 8-258

86 LOCKOUT SWITCH ...................................................................................... 7-229

A1 STATUS ....................................................................................................... 6-202

A2 METERING DATA ......................................................................................... 6-207

A3 LEARNED DATA........................................................................................... 6-213

A4 STATISTICAL DATA ..................................................................................... 6-216

A5 EVENT RECORD .......................................................................................... 6-219

A6 RELAY INFORMATION .................................................................................6 -220

ACCELERATION TRIP ............................................................................ 5-161, 7-237

ACCESS SECURITY .......................................................................................... 5-111

ACCESS SWITCH ............................................................................................. 5-187

ACCESSORIES .................................................................................................... 1-3

ACTUAL VALUES .............................................................................................. 6-199

main menu ......................................................................................................6 -199

overview ......................................................................................................... 6-199

page 6 menu ................................................................................................... 6-220

ADDITIONAL FEATURES.....................................................................................2-12

ADDITIONAL FUNCTIONAL TING ...................................................................... 8-264

ALARM RELAY

setpoints ......................................................................................................... 5-130

ALARM STATU S ................................................................................................ 6-203

ANALOG

inputs and outputs ........................................................................................... 8-262

outputs ......................................................................................... 3-42, 3-43, 5-190

outputs (Option M).............................................................................................2-15

APPROVALS / CERTIFICATIO N ...........................................................................2-24

AUTO TRANSFORMER STARTER WIRING ........................................................ 7-253

AUTORESTART .......................................................................... 5-134, 5 -136, 5-137

AUX 1 RELAY

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX–1

INDEX

see AUXILIARY RELAYS

AUX 2 RELAY

see AUXILIARY RELAYS

AUXILIARY RELAYS

setpoints ......................................................................................................... 5-130

BACK PORTS (3) ................................................................................................ 2-17

BACKSPIN

detectio n ......................................................................................................... 5-163

voltage inputs ................................................................................................... 3-41

BEARING RTDS ................................................................................................ 7-238

BSD INPUTS (OPTION B) .................................................................................... 2-15

CLEAR/PRESET DATA ...................................................................................... 5-120

COMMUNICATIONS ............................................................................................ 2-17

control ............................................................................................................ 5-132

Modbus/TCP ................................................................................................... 5-113

RS232 ..................................................................................................... 4-63, 4-65

RS485 ..................................................................................................... 4-63, 4-65

CONTROL

functions ......................................................................................................... 5-131

power ...................................................................................................... 3-38, 3-44

COOL TIME CONSTANTS ................................................................................. 7-240

CORE BALANCE CONNECTION ........................................................................ 7-224

burden ............................................................................................................ 7-231

circuit ............................................................................................................. 7-232

ground CT primary .......................................................................................... 5-122

phase CT primary ............................................................................................ 5-122

secondary resistance....................................................................................... 7-231

selection ......................................................................................................... 7-231

setpoints ......................................................................................................... 5-122

size and saturation .......................................................................................... 7-230

withstand ........................................................................................................ 7-230

CT AND VT

polarity ........................................................................................................... 7-227

CT/VT SETUP ................................................................................................... 5-122

CURRENT

metering ......................................................................................................... 6-207

unbalance ....................................................................................................... 5-158

CURRENT DEMAND............................................................................... 5-126, 5-127

CURRENT TRANSFORMER

see CT

CUSTOM OVERLOAD CURVE ........................................................................... 5-148

DATE ................................................................................................................ 5-115

DEFAULT MESSAGES

cycle time ....................................................................................................... 5-111

setpoints ......................................................................................................... 5-119

timeout ........................................................................................................... 5-111

DEMAND

calculation ...................................................................................................... 5-127

metering ......................................................................................................... 6-210

setpoints .............................................................................................. 5-126, 5-127

DEVICENET

INDEX–2

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX

settings ........................................................................................................... 5-113

specifications ....................................................................................................2-17

DIAGNOSTIC MESSAGES .................................................................................6 -203

DIELECTRIC STRENGTH ....................................................................................2-24

DIFFERENTIAL SWITCH ................................................................................... 5-187

Digital ............................................................................................................... 8-260

DIGITAL COUNTER ........................................................................................... 5-185

DIGITAL INPUT ................................................................................................. 7-229

status.............................................................................................................. 6-204

DIGITAL INPUT FUNCTION

digital counter ................................................................................................. 5-185

general switch ................................................................................................. 5-184

waveform capture ............................................................................................ 5-185

DISPLAY .............................................................................................................4-57

preferences ..................................................................................................... 5-111

DO’S AND DON’TS ............................................................................................ 7-227

DUST/MOISTUR E .......................................................................................2 -22, 2-25

ELECTRICAL INSTALLATION ..............................................................................3-37

EMERGENCY RESTART.................................................................................... 5-187

EMI .....................................................................................................................2-25

ENABLE

start inhibit ......................................................................................................7 -237

ENERVISTA VIEWPOINT WITH THE 369 ........................................................... 4-102

ENVIRONMENATAL SPECIFICATIONS ................................................................2-22

ENVIRONMEN T ...................................................................................................2-25

ETHERNET

specifications ....................................................................................................2-17

FACEPLATE

interface............................................................................................................4-57

FACTORY DATA ...............................................................................................5 -121

FAQ .................................................................................................................. 7-223

FAST TRANSIENTS.............................................................................................2-25

FIBER OPTIC PORT (OPTION F) .........................................................................2-17

FIRMWARE

history................................................................................................................ 1-3

upgrading via EnerVista 369 setup software .......................................................4-84

versio n ............................................................................................................ 6-220

FLA ................................................................................................................... 5-123

FLASH MESSAGES

duration .......................................................................................................... 5-111

FORCE OUTPUT RELAYS

settings ........................................................................................................... 5-139

FREQUENCY .................................................................................................... 5-124

FREQUENTLY ASKED QUESTIONS .................................................................. 7-223

FRONT PORT......................................................................................................2-17

communicating ................................................................................................ 7-223

FULL LOAD AMP S ............................................................................................. 5-123

GATEWAY ADDRESS ........................................................................................5 -113

GENERAL SWITCH ........................................................................................... 5-184

GROUND

(1A/5A) ACCURACY TEST .............................................................................. 8-258

accuracy test................................................................................................... 8-258

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX–3

INDEX

bus ................................................................................................................. 7-227

CT ....................................................................................................... 5-123, 7-234

current input...................................................................................................... 3-39

fault ..................................................................................................... 5-159, 7-237

fault detection

ungrounded system s ............................................................................... 7-250

filter ................................................................................................................ 7-227

safety ............................................................................................................. 7-227

GUIDEFORM SPECIFICATIONS ............................................................................2-9

HARDWARE FUNCTIONAL TESTING ................................................................ 8-257

HGF GROUND CT INSTALLATION

3” and 5” window ............................................................................................... 3-56

8” window ......................................................................................................... 3-56

HOT/COLD CURVE RATIO ..................................................................... 5-151, 7-235

HOT/COLD SAFE STALL RATIO ........................................................................ 5-143

HUMIDITY ........................................................................................................... 2-25

IED SETUP ......................................................................................................... 4-60

IMPULSE TEST ................................................................................................... 2-24

INPUT S ............................................................................................................... 2-13

INSTALLATION ................................................................................................... 3-27

electrical ........................................................................................................... 3-37

mechanical ....................................................................................................... 3-27

upgrade ............................................................................................................ 4-60

INSULATION RESISTANCE ................................................................................. 2-25

INTRODUCTION AND ORDERING .........................................................................1-1

IP ADDRESS ..................................................................................................... 5-113

KEYPAD ............................................................................................................. 4-58

LAG POWER FACTOR ...................................................................................... 5-179

LAST TRIP DATA .............................................................................................. 6-202

LEAD POWER FACTOR .................................................................................... 5-178

LEARNED START CAPACITY ............................................................................ 7-247

LOCAL / REMOTE RTD OPERATION ................................................................. 5-167

LOCAL RTD ...................................................................................................... 6-209

maximums ...................................................................................................... 6-214

protection........................................................................................................ 5-165

LONG-TERM STORAGE ...................................................................................... 2-24

MECHANICAL INSTALLATIO N ............................................................................. 3-27

MECHANICAL JA M ................................................................................. 5-156, 7-236

MESSAGE SCRATCHPAD ................................................................................. 5-118

METERED QUANTITIES ...................................................................................... 2-10

METERING ......................................................................................................... 2-16

MODBUS

serial communications control .......................................................................... 5-132

setpoints .............................................................................................. 5-112, 5-114

INDEX–4

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX

MODBUS/TCP COMMUNICATIONS ................................................................... 5-113

MODEL INFORMATION ..................................................................................... 6-220

MODIFY OPTIONS ............................................................................................ 5-121

MONITORING SETUP........................................................................................5 -125

MOTOR

cooling ............................................................................................................ 5-151

data ................................................................................................................ 6-213

FLA................................................................................................................. 5-123

FLC ................................................................................................................ 7-234

rated voltage ................................................................................................... 5-122

statistics ......................................................................................................... 6-217

status................................................................................................... 6-202, 6-204

status detection ...............................................................................................7 -239

thermal limits .................................................................................................. 7-234

MOTOR FLA ......................................................................................................5 -123

MPM-369

conversion terminal list ......................................................................................3-35

MTM-369

conversion terminal list ......................................................................................3-34

NEGATIVE REACTIVE POWER ......................................................................... 5-180

NOMINAL FREQUENCY .................................................................................... 5-124

OPEN RTD ALAR M ............................................................................................ 5-169

OPERATION......................................................................................................5 -131

OPTIONS, MODIFYING ..................................................................................... 5-121

ORDERING .......................................................................................................... 1-2

OUTPUT RELAYS ........................................................................... 2-15, 3-44, 8-263

forcing ............................................................................................................ 5-139

setpoints .............................................................................................. 5-129, 5-130

OUTPUTS ...........................................................................................................2-15

OVERFREQUENCY ........................................................................................... 5-176

OVERLOAD

alarm .............................................................................................................. 5-154

curve .............................................................................................................. 7-236

curve test ........................................................................................................ 8-264

pickup ............................................................................................................. 7-235

OVERLOAD CURVES

custom ............................................................................................................ 5-148

setpoints ................................................................................... 5-144, 5 -145, 5-196

standard ................................................................................... 5-145, 5 -146, 5-147

OVERLOAD/STALL/THERMAL MODEL ................................................................2-18

OVERVOLTAGE ................................................................................................ 5-172

PARITY ............................................................................................................. 5-112

PASSWORDS

comm password .............................................................................................. 5-111

PC PROGRAM

software history .................................................................................................. 1-4

PC SOFTWARE

obtaining ......................................................................................................... 7-223

PHASE

CT ....................................................................................................... 5-122, 7-234

CT installation ...................................................................................................3-54

current (CT) inputs ............................................................................................3-38

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX–5

INDEX

current accuracy test ....................................................................................... 8-257

line voltage input, VT (Option M )........................................................................ 2-14

reversal .......................................................................................................... 5-173

voltage (VT/PT) inputs ....................................................................................... 3-40

VT .................................................................................................................. 5-123

PHASE SEQUENCY .......................................................................................... 5-124

PHASORS ......................................................................................................... 6-211

POLARITY

CT and VT ...................................................................................................... 7-227

POSITIVE REACTIVE POWE R ........................................................................... 5-179

POWER

measurement test............................................................................................ 8-265

metering ......................................................................................................... 6-208

metering (option m) ........................................................................................... 2-16

POWER DEMAND ............................................................................................. 5-127

PRODUCTION TESTS ......................................................................................... 2-25

PROFIBUS

setpoints ......................................................................................................... 5-114

PROFIBUS ADDRESS ....................................................................................... 5-113

PROFIBUS PORT (OPTION P) ............................................................................. 2-17

PROGRAMMING EXAMPLE ............................................................................... 7-233

PROTECTION ELEMENTS...................................................................................2 -18

REAL TIME CLOCK ........................................................................................... 6-206

setpoints ......................................................................................................... 5-115

REDUCED RTD LEAD NUMBER ........................................................................ 7-251

REDUCED VOLTAGE START ................................................................. 5-132, 5-134

RELAY LABEL DEFINITION ...................................................................................1-8

REMOTE RESET ............................................................................................... 5-189

REMOTE RTD ................................................................................................... 6-209

address........................................................................................................... 5-112

maximums ...................................................................................................... 6-215

module electrical installation .............................................................................. 3-53

module mechanical installation .......................................................................... 3-51

protection........................................................................................................ 5-166

RESET .............................................................................................................. 5-130

RESIDUAL GROUND FAULT CONNECTION ...................................................... 7-224

REVERSE POWER ............................................................................................ 5-183

REVISION HISTORY ........................................................................................ A-269

RFI ..................................................................................................................... 2-25

ROLLING DEMAND WINDOW ............................................................................ 5-127

RRTD ADDRESS ............................................................................................... 5-112

RS232

communicating ................................................................................................ 7-223

program port ..................................................................................................... 4-58

setpoints ......................................................................................................... 5-112

RS232 COMMUNICATIONS

configuring with EnerVista 369 Setup ................................................................. 4-63

configuring with EnerVista 369 setup ................................................................. 4-65

RS485

4 wire ............................................................................................................. 7-223

cable .............................................................................................................. 7-228

communication difficulties ................................................................................ 7-223

communications ................................................................................................ 3-45

communications port ....................................................................................... 7-228

converter ........................................................................................................ 7-228

distances ........................................................................................................ 7-228

full duplex ....................................................................................................... 7-223

interfacing master device ................................................................................. 7-228

repeater .......................................................................................................... 7-228

setpoints ......................................................................................................... 5-112

INDEX–6

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX

RS485 COMMUNICATIONS

configuring with EnerVista 369 setup.........................................................4 -63, 4-65

RTD ......................................................................................................... 3-42, 7-227

2 wire lead compensation ................................................................................ 7-253

accuracy test................................................................................................... 8-259

bias .......................................................................................... 5-143, 5 -152, 5-153

bias maximum ................................................................................................. 7-236

bias mid point.................................................................................................. 7-236

bias minimum .................................................................................................. 7-236

circuitr y ........................................................................................................... 7-251

grounding........................................................................................................ 7-229

inputs................................................................................................................3-42

inputs (Option r) ................................................................................................2-15

stator .............................................................................................................. 7-237

RUNNING COOL TIME ...................................................................................... 7-235

S10 ANALOG OUTPUTS .................................................................................... 5-190

S11 369 TESTING ............................................................................................. 5-192

S2 SYSTEM SETUP .......................................................................................... 5-122

S3 OVERLOAD PROTECTION ........................................................................... 5-141

S4 CURRENT ELEMENTS .................................................................................5 -155

S5 MOTOR START / INHIBITS ........................................................................... 5-161

S6 RTD TEMPERATURE ................................................................................... 5-165

S7 VOLTAGE ELEMENTS .................................................................................. 5-171

S8 POWER ELEMENTS ..................................................................................... 5-177

S9 DIGITAL INPUTS .......................................................................................... 5-184

SECONDARY INJECTION TEST SETUP ............................................................ 8-256

SECURITY ........................................................................................................ 5-111

SELF-TEST MODE ............................................................................................ 5-129

SELF-TEST RELAY ........................................................................................... 5-129

SERIAL COMMUNICATION CONTROL ............................................................... 5-132

SETPOINTS ......................................................................................................5 -107

access ............................................................................................................ 5-111

entering with EnerVista 369 Setup softwar e ........................................................4-69

entry .................................................................................................................4-59

loading from a fil e ..............................................................................................4-83

main menu ......................................................................................................5 -107

page 1 menu ................................................................................................... 5-111

saving to a file...................................................................................................4-84

SHORT CIRCUIT ...............................................................................................5 -155

test ................................................................................................................. 8-267

trip .................................................................................................................. 7-236

SHORT/LOW TEMP RTD ALARM ....................................................................... 5-169

SOFTWARE

entering setpoints ..............................................................................................4-69

installation ........................................................................................................4-60

loading setpoints ...............................................................................................4-83

saving setpoints ................................................................................................4-84

serial communications ..............................................................................4 -63, 4-65

SPARE SWITCH ................................................................................................ 5-186

SPEED SWITCH ................................................................................................ 5-188

START INHIBIT ........................................................................... 5-162, 7-241, 7-246

enable d ........................................................................................................... 7-247

starter

status switch ................................................................................................... 5-133

STARTER FAILURE........................................................................................... 5-126

STARTS/HOUR ................................................................................................. 7-237

STATOR RTD S .................................................................................................. 7-237

STOPPED COOL TIME ...................................................................................... 7-236

STOPPED COOL TIME CONSTANT ................................................................... 7-241

SUBNET MASK ................................................................................................. 5-113

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX–7

INDEX

SYSTEM ........................................................................................................... 5-124

SYSTEM FREQUENCY ...................................................................................... 5-124

TECHNICAL SPECIFICATIONS............................................................................2 -13

TEMPERATURE .................................................................................................. 2-25

TEMPERATURE DISPLAY ................................................................................. 5-111

TERMINAL

identification ..................................................................................................... 3-29

layout ............................................................................................................... 3-36

list .................................................................................................................... 3-29

TEST

burn in .............................................................................................................. 2-25

calibration and functionality ............................................................................... 2-25

dielectric strengt h .............................................................................................. 2-25

ground accuracy.............................................................................................. 8-258

hardware functional ......................................................................................... 8-257

input accurac y ................................................................................................. 8-257

overload curve ................................................................................................ 8-264

phase current accuracy ................................................................................... 8-257

power measurement ........................................................................................ 8-265

productio n ......................................................................................................... 2-25

RTD accuracy ................................................................................................. 8-259

secondary injection ......................................................................................... 8-256

setup .............................................................................................................. 8-255

short circuit ..................................................................................................... 8-267

type test standards ............................................................................................ 2-24

unbalance ....................................................................................................... 8-265

voltage

metering ............................................................................................... 6-207

phase reversal ....................................................................................... 8-265

TESTING

analog outputs ................................................................................................ 5-193

output relays ................................................................................................... 5-192

setpoints ......................................................................................................... 5-192

THERMAL

capacity calculation ......................................................................................... 7-244

capacity used .................................................................................................. 7-244

limit ................................................................................................................ 7-241

limit curves ..................................................................................................... 7-246

THERMAL CAPACITY USED.............................................................................. 5-143

THERMAL MODEL

coolin g ............................................................................................................ 5-152

description ...................................................................................................... 5-142

limit curves ..................................................................................................... 5-142

setpoints ......................................................................................................... 5-142

TIME ................................................................................................................. 5-115

TIME BETWEEN STARTS .................................................................................. 7-237

TRIP COUNTER .......................................................................... 5-125, 6-209, 6-216

TRIP RELAY ....................................................................................................... 3-45

setpoints ......................................................................................................... 5-130

TWO PHASE WIRING ........................................................................................ 7-248

TWO WIRE RTD LEAD COMPENSATION ........................................................... 7-253

TYPE TEST STANDARDS.................................................................................... 2-24

UNBALANCE

alarm and tri p .................................................................................................. 7-237

bias ................................................................................................................ 5-149

INDEX–8

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX

bias k factor .................................................................................................... 7-235

bias of thermal capacity ................................................................................... 7-235

setpoints ......................................................................................................... 5-142

test ................................................................................................................. 8-265

UNDERCURRENT .................................................................................. 5-157, 7-237

UNDERFREQUENCY ......................................................................................... 5-175

UNDERPOWER ................................................................................................. 5-182

UNDERVOLTAGE .............................................................................................. 5-171

UPGRADING FIRMWARE ....................................................................................4-84

VIBRATION .........................................................................................................2-23

VOLTAGE

input accuracy test .......................................................................................... 8-257

metering ......................................................................................................... 6-207

phase reversal test .......................................................................................... 8-265

VOLTAGE TRANSFORMER

see VT

connection type ...............................................................................................5 -123

ratio ................................................................................................................ 5-123

VT RATIO............................................................................................... 5-122, 5-123

VT SETTINGS ................................................................................................... 7-234

WARRANTY ..................................................................................................... A-275

WAVEFORM CAPTURE ................................................................. 2-16, 5-116, 5-185

setpoints .............................................................................................. 5-116, 5-118

WIRING DIAGRAM ..............................................................................................3-37

ZERO SEQUENCE

ground CT placement ........................................................................................3-40

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

INDEX–9

INDEX

INDEX–10

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

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