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Table of Contents
User Information............................................................................................................................ 2
Table of Contents .......................................................................................................................... 3
Table of Tables............................................................................................................................... 5
Table of Figures............................................................................................................................. 7
Important User Information ........................................................................................................ 11
Change Summary .................................................................................................................... 12
Chapter 1 Introduction................................................................................................................ 16
Aries Products—Overview ....................................................................................................... 17
Compatible Parker Products .................................................................................................... 18
Checking Your Shipment.......................................................................................................... 19
Illustrations in this Installation Guide........................................................................................ 20
Assumptions of Technical Experience ..................................................................................... 20
Technical Support .................................................................................................................... 20
Chapter 2 Mechanical Installation.............................................................................................. 21
Environment & Drive Cooling ................................................................................................... 22
Dimensions............................................................................................................................... 28
Weight ...................................................................................................................................... 30
Mounting Guidelines................................................................................................................. 31
Chapter 3 Electrical Installation................................................................................................. 32
Installation Safety Requirements.............................................................................................. 33
System Installation Overview ................................................................................................... 34
Power Supply ........................................................................................................................... 39
Multiple Drive Installations........................................................................................................ 48
Brake Relay (Optional)............................................................................................................. 50
Regeneration Protection........................................................................................................... 54
LEDs⎯Drive Status Indicators................................................................................................. 56
Connector Descriptions............................................................................................................ 57
Installation Test ........................................................................................................................ 72
Chapter 4 Communications........................................................................................................ 73
RS-232/485 Communications .................................................................................................. 74
Chapter 5 Tuning......................................................................................................................... 78
Servo Tuning Overview............................................................................................................ 79
Position Variable Overview ...................................................................................................... 80
Servo Response Overview....................................................................................................... 81
Servo System Gains................................................................................................................. 83
Servo Tuning Example............................................................................................................. 86
Auto-Tuning.............................................................................................................................. 90
Chapter 6 Command Reference................................................................................................. 91
Aries Communications Set-up.................................................................................................. 92
Description of Format............................................................................................................... 92
Syntax – Letters and Symbols.................................................................................................. 93
Syntax – General Guidelines.................................................................................................... 94
Command Descriptions............................................................................................................ 95
Chapter 7 Troubleshooting....................................................................................................... 156
Troubleshooting Guidelines.................................................................................................... 157
LEDs⎯Drive Status Indicators............................................................................................... 158
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RS-232/485 Communication Problems.................................................................................. 159
Error Messages ...................................................................................................................... 160
Smart Encoders...................................................................................................................... 163
Hall Sensor Configuration/Troubleshooting ........................................................................... 164
Appendix A Additional Specifications .................................................................................... 168
Amplifier.................................................................................................................................. 169
Feedback................................................................................................................................ 169
Protective Circuits .................................................................................................................. 170
Cables .................................................................................................................................... 173
Appendix B External Power-Dump Resistor Selection.......................................................... 174
External Power-Dump Resistor Selection.............................................................................. 175
Simplified Resistor Selection.................................................................................................. 175
Calculating Resistance—Rotary Motors ................................................................................ 177
Resistor Specifications⎯Rotary Motors................................................................................. 181
Calculating Resistance—Linear Motors................................................................................. 183
Resistor Specifications⎯Linear Motors ................................................................................. 187
Appendix C Regulatory Compliance–UL and CE................................................................... 189
System Installation Overview ................................................................................................. 190
Regulatory Agencies .............................................................................................................. 200
Standards of Compliance....................................................................................................... 200
Appendix D Servo Tuning Flow Diagram................................................................................ 201
Servo Tuning Flow Diagram................................................................................................... 202
Appendix E VM26 Expansion Module ..................................................................................... 203
Overview................................................................................................................................. 204
Index ........................................................................................................................................... 205
4
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Table of Tables
Table 1 Output Power Level..................................................................................................... 18
Table 2 Ship Kit Items, AR-01xx through AR-13xx .................................................................. 19
Table 3 Ship Kit Items, AR-20xE and AR-30xE ....................................................................... 19
Table 5 Environmental Specifications, AR-13xx ...................................................................... 23
Table 6 AR-02xx Power Dissipation......................................................................................... 24
Table 7 AR-08xx Power Dissipation......................................................................................... 25
Table 8 AR-13xx Power Dissipation......................................................................................... 26
Table 9 AR-30xE Power Dissipation........................................................................................ 27
Table 10 AR-01xx and AR-02xx Drive Dimensions ................................................................. 28
Table 11 AR-01xx , AR-02xx, & AR-13xx Drive Dimensions................................................... 29
Table 12 AR-20xE and AR-30xE Drive Dimensions ................................................................ 30
Table 13 Drive Weight.............................................................................................................. 30
Table 14 Motor Power Fuse Information.................................................................................. 41
Table 15 Fuse Part Numbers ................................................................................................... 42
Table 16 Drive Motor Power Inrush Current ............................................................................ 42
Table 17 Output Power-Continuous and Peak......................................................................... 43
Table 18 Wiring to Motors ........................................................................................................ 44
Table 19 AR-20xE & AR-30xE DC Link Inductors ................................................................... 45
Table 20 Brake Relay Operation.............................................................................................. 53
Table 21 Regeneration Absorption .......................................................................................... 55
Table 22 LED Status Indicator-Normal Operation.................................................................... 56
Table 23 LED Status Indicator-Internal Drive Fault.................................................................. 56
Table 24 MOTOR FEEDBACK Connector Pinout........................................................................... 63
Table 25 Inputs—Encoder Inputs Electrical/Timing Characteristics ........................................ 63
Table 26 MOTOR FEEDBACK Connector Pinout for Resolver Option .......................................... 66
Table 27 Resolver excitation.................................................................................................... 66
Table 28 Fault Output Operation.............................................................................................. 67
Table 29 DRIVE I/O Connector Pinout........................................................................................ 69
Table 30 Inputs—Enable and Reset Electrical/Timing Characteristics.................................... 70
Table 31 Outputs—Encoder Outputs Electrical/Timing Characteristics................................... 70
Table 32 Outputs— Fault outputs Electrical/Timing Characteristics........................................ 70
Table 33 Inputs—Step & Direction Electrical/Timing Characteristics ...................................... 71
Table 34 Inputs—Analog Electrical/Timing Characteristics ..................................................... 71
Table 36 RS-232 Connector Pinout ......................................................................................... 75
Table 37 RS-485 Connector Pinout ......................................................................................... 75
Table 38 Position Response Types ......................................................................................... 82
Table 39 Commands-Description of Format ............................................................................ 92
Table 40 Commands-Syntax.................................................................................................... 93
Table 41 Syntax Guidelines ..................................................................................................... 94
Table 42 Configuration Errors and Warnings......................................................................... 100
Table 43 Current Foldback Ratings ....................................................................................... 102
Table 44 Drive Control Mode ................................................................................................. 104
Table 45 Peak Current Rating for Aries Drives...................................................................... 109
Table 46 Error Status⎯Text Based Report ........................................................................... 131
Table 47 Error Log⎯Enable/Disable ..................................................................................... 132
Table 49 Communications Port Errors and Resolutions........................................................ 160
Table 50 Error Messages....................................................................................................... 163
Table 51 Configuring Hall Sensors......................................................................................... 167
Table 52 LED Short Circuit Fault............................................................................................ 170
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Table 53 LED Drive Over-Temperature Fault ........................................................................ 170
Table 54 Reset Temperature Values ..................................................................................... 171
Table 55 LED Under-Voltage Fault........................................................................................ 171
Table 56 LED Over-Voltage Fault.......................................................................................... 172
Table 57 Simplified Selection of External Power-Dump Resistor .......................................... 176
Table 58 Drive Capacitor Absorption ..................................................................................... 179
Table 59 Drive Capacitor Absorption ..................................................................................... 185
Table 60 Control Power Filter Selection................................................................................. 194
Table 61 Mains Motor Power Filter Selection ........................................................................ 194
Table 62 Enclosure Mounting Clamps ................................................................................... 196
Table 63 Regulatory Agencies ............................................................................................... 200
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Table of Figures
Figure 5 Drive mounting for the AR-01xx & AR-02xx............................................................... 28
Figure 6 Drive mounting for the AR-04xx, AR-08xx, and AR-13xx.......................................... 29
Figure 7 Drive mounting for the AR-20xE and AR-30xE.......................................................... 30
Figure 8 Panel Layout Dimensions for Aries Drives................................................................. 31
Figure 9 Overview of System Installation for AR-01xx to AR-13xx.......................................... 34
Figure 10 AR-01xx to AR-13xx Factory Installed Jumpers...................................................... 35
Figure 11 Overview of System Installation for AR-20xE & AR-30xE ....................................... 36
Figure 12 AR-20xE to AR-30xE Factory Installed Jumpers..................................................... 37
Figure 13 Connectors on Aries Models AR-01xx to AR-13xx.................................................. 38
Figure 14 Connectors on Aries Models AR-20xE & AR-30xE ................................................. 38
Figure 15 Input Power Requirements ...................................................................................... 39
Figure 16 Motor and Control Mains Power Supply Connection............................................... 40
Figure 17 Output Power Connection........................................................................................ 44
Figure 18 External DC Link Inductor Connection..................................................................... 45
Figure 19 Mains Control Input Power....................................................................................... 47
Figure 20 Multiple Drives AR-01xx to AR-13xx: Single Point Safety Earth ............................. 48
Figure 21 Multiple Drives AR-20xE & AR-30xE: Single Point Safety Earth............................. 49
Figure 22 Typical Brake Relay Connection.............................................................................. 50
Figure 23 Brake Relay Connection for Parker Motors ............................................................. 51
Figure 24 Brake Relay Connection for Non-Parker Motors ..................................................... 52
Figure 25 External Regeneration Connection.......................................................................... 54
Figure 26 Mains/Input Power Connector.................................................................................. 57
Figure 27 Output (MOTOR) Power Connector ........................................................................... 59
Figure 28 AR-20xE & AR30xE Control Connector................................................................... 61
Figure 29 MOTOR FEEDBACK connector, female drive connector pinout.................................... 62
Figure 30 MOTOR FEEDBACK connector, internal circuit diagram............................................... 62
Figure 31 MOTOR FEEDBACK connector, female drive connector pinout.................................... 65
Figure 32 MOTOR FEEDBACK connector for resolver option, internal circuit diagram................. 65
Figure 33 DRIVE I/O connector, female drive connector pinout ................................................. 67
Figure 34 DRIVE I/O connector, internal circuit diagram ............................................................ 68
Figure 35 RS-232/485 Connections......................................................................................... 74
Figure 36 RS-485 Multi-drop Connections............................................................................... 76
Figure 37 Closed Loop and Open Loop System Comparison ................................................. 79
Figure 38 Commanded Position............................................................................................... 80
Figure 39 Integrator Windup (Without Using SGILIMCommand)........................................... 84
Figure 40 Integrator Windup (using the SGILIMCommand)................................................... 85
Figure 41 Clockwise/ Counter-clockwise rotation .................................................................... 99
Figure 42 Time until current foldback occurs ......................................................................... 102
Figure 43 Linear motor track .................................................................................................. 103
Figure 44 Notch Filter Topology............................................................................................. 120
Figure 45 Notch Filter Magnitudes ......................................................................................... 120
Figure 46 Notch Filter A ......................................................................................................... 121
Figure 47 Notch Lead Filter Break Frequency ....................................................................... 123
Figure 48 Clockwise/ Counter-clockwise rotation .................................................................. 154
Figure 49 Hall Connection Diagram....................................................................................... 165
Figure 50 Motor Terminal Voltages (back EMF) and Hall Sensor Signals............................. 167
Figure 51 Time until current foldback occurs ......................................................................... 173
Figure 52 360° Bonding Techniques...................................................................................... 193
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Figure 53 Typical LVD/EMC Installation, AR-02xx to AR-13xx.............................................. 197
Figure 54 Typical LVD/EMC Installation, AR-20xE & AR-30xE............................................. 198
Figure 55 Panel Layout Dimensions for the Aries Drive ........................................................ 199
Figure 56 Servo Tuning Flow Diagram .................................................................................. 202
Figure 57 VM26 Breakout Module.......................................................................................... 204
8
Aries User Guide
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Product Type...........................................Aries Family AR-01Ax, 02Ax, 04Ax,
08Ax, 13Ax, 20AE, and 30AE
................................................................Aries Family AR-01Sx, 02Sx, 04Sx,
08Sx, 13Sx, 20SE, and 30SE
The above product complies with the requirements of directives:
•
•
•
EMC Directive 89/336/EEC
Low Voltage Directive 73/23/EEC
CE Marking Directive 93/68/EEC
Provided the installation requirements described in this guide are met, and
there are no special requirements of the installation and operating
environment so that the application may be considered typical.
The above equipment conforms with the protection requirements of Council
Directive 89/336/EEC as amended by Directive 92/31/EEC on the
approximation of the laws of the Member States relating to Electromagnetic
Compatibility when installed, operated and maintained as intended. Also: -
The above equipment conforms with the requirements of Council Directive
73/23/EEC (Low Voltage Directive) as amended by Directive 93/68/EEC (CE
Marking Directive), when installed, operated, and maintained as intended.
In accordance with IEC 61800-3:1997 (Adjustable speed electrical power
drive systems) this product is of the restricted sales distribution class which
meets the needs of an industrial environment when installed as directed.
However, further measures may need to be taken for use of the product in a
domestic environment.
The installation requirements are detailed in the Information supplied with the
equipment. The equipment is sold only to competent system builders.
Compliance is demonstrated by the application of the following standards:
•
BS EN 61800-3 (1997) including Amendment A11 Adjustable speed
electrical Power drive systems Part 3. EMC product standard
including specific test methods.
•
•
•
BS EN 50081-2 (1994) Electromagnetic compatibility—Generic
emission standard Part 2. Industrial Environment.
BS EN 61000-6-2 (1999) Electromagnetic compatibility Part 6-2:
Generic Standards – Immunity for industrial environments.
BS EN 61010-1 (1993) including Amendment A2. Safety
requirements for electrical equipment for measurement, control, and
laboratory use. Part 1 General Requirements.
9
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Warning — Risk of damage and/or personal injury
The Aries drives described in this guide contain no user-serviceable parts.
Attempting to open the case of any unit, or to replace any internal
component, may result in damage to the unit and/or personal injury. This
may also void the warranty.
Symbols
Description
Protective Earth Ground
Functional Earth (Ground) Terminal
Shield, Frame, or Chassis Terminal
Caution Risk of Electrical Shock
Caution, Refer to Accompanying Documentation
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Important User Information
It is important that motion control equipment is installed and operated in such a way that all
applicable safety requirements are met. It is your responsibility as an installer to ensure that you
identify the relevant safety standards and comply with them; failure to do so may result in
damage to equipment and personal injury. In particular, you should study the contents of this
user guide carefully before installing or operating the equipment.
The installation, set up, test, and maintenance procedures given in this User Guide should only
be carried out by competent personnel trained in the installation of electronic equipment. Such
personnel should be aware of the potential electrical and mechanical hazards associated with
mains-powered motion control equipment—please see the safety warnings below. The individual
or group having overall responsibility for this equipment must ensure that operators are
adequately trained.
Under no circumstances will the suppliers of the equipment be liable for any incidental,
consequential or special damages of any kind whatsoever, including but not limited to lost profits
arising from or in any way connected with the use of the equipment or this guide.
Warning — High-performance motion control equipment is capable of producing rapid
movement and very high forces. Unexpected motion may occur especially during the
development of controller programs. KEEP WELL CLEAR of any machinery driven by stepper or
servo motors. Never touch any part of the equipment while it is in operation.
This product is sold as a motion control component to be installed in a complete system using
good engineering practice. Care must be taken to ensure that the product is installed and used
in a safe manner according to local safety laws and regulations. In particular, the product must
be positioned such that no part is accessible while power may be applied.
This and other information from Parker Hannifin Corporation, its subsidiaries, and authorized
distributors provides product or system options for further investigation by users having technical
expertise. Before you select or use any product or system, it is important that you analyze all
aspects of your application and review the information concerning the product in the current
product catalog. The user, through its own analysis and testing, is solely responsible for making
the final selection of the system and components and assuring that all performance, safety, and
warning requirements of the application are met.
If the equipment is used in any manner that does not conform to the instructions given in this
user guide, then the protection provided by the equipment may be impaired.
The information in this user guide, including any apparatus, methods, techniques, and concepts
described herein, are the proprietary property of Parker Hannifin or its licensors, and may not be
copied disclosed, or used for any purpose not expressly authorized by the owner thereof.
Since Parker Hannifin constantly strives to improve all of its products, we reserve the right to
modify equipment and user guides without prior notice. No part of this user guide may be
reproduced in any form without the prior consent of Parker Hannifin.
11
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Change Summary
Revision G Changes
This document, 88-021610-01G, supersedes 88-021610-1F. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
Electrical Installation
that 40A fuse is recommended regardless of
single- or 3-phase input power.
Added “Yellow & 5 Green (flashing)” for Encoder
Corrected connector p/n from ELFA13210E to
OSTTJ075102 for Mains/Input Power Connector
Removed reference to 120V motor power for
single- or three-phase AR-20xE in AC Power
Added “—Encoder” to clarify title to section Motor
Corrected Motor Feedback Connector—Resolver
schematic by removing pins 16 and 17.
Corrected diode connection across motor cable in
Command Reference
Corrected “perception” to “misperception” in Servo
E12 because they are not faults.
with info on using DREScommand with 0 value.
link from TOTEMPto TDTEMP.
Added DTHERM to list of commands stored with
ESTORE. Alphabetized list.
Added 3 and 4 to ranges, and additional
information regarding OHALL 1 and OHALL 4 to
OHALL command.
Troubleshooting
E34 link from TOTEMPto TDTEMP.
Added “Yellow & 5 Green (flashing)” for Encoder
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Revision F Changes
This document, 88-021610-01F, supersedes 88-021610-1E. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
Command Reference
Additions to ERES, SFB, and TREVcommands for
Aries Resolver option.
Added TIDACand TIQACcommands.
Corrected DCMDZsyntax.
Corrected ranges for DMTIC, DMTIP, DMTKE,
DMTRES, and ERES.
Aries Names
Updated part number descriptions to include
Resolver and Powerlink Options
LEDs—Drive Status
Indicators
Updated to include Autorun mode.
Resolver option
Added Motor Feedback Connector pinout, circuit
diagram, and resolver excitation frequency.
Error Messages
Added E50, E51, and E52 error messages
Revision E Changes
This document, 88-021610-01E, supersedes 88-021610-1D. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
AC Power Supply
Connection
Clarified jumpering two phases of the motor input
power to the control input power allows for a
single AC connection.
Drive I/O Connector—
Internal Circuit Diagram
Corrected circuit for Step+ and Step-.
Drive I/O Connector
Step and Direction is not optically isolated, but is
5V differential compatible (RS-422 logic level
compatible).
VM26 Breakout Module Added appendix describing the VM26 Breakout
Module.
13
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Revision D Changes
This document, 88-021610-01D, supersedes 88-021610-1C. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
Regulatory Compliance Aries is no longer cUL compliant.
Output Power
Part Number
Corrected to 14.07A
In Appendix C, Table 62 Enclosure Mounting
Clamps, corrected part number to read R CLAMP
KIT.
Environment and Drive
Cooling
Removed separate Still Air and Moving Air
temperature maximums. Now provides only an
Ambient Air temperature.
Revision C Changes
This document, 88-021610-01C, supersedes 88-021610-1B. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
Models
Enhancement: Added models AR-13xx, AR-20xE,
and AR-30xE, and relevant information.
Regeneration
Protection
Enhancement: Added discussion and connections.
DC Inductance Link
Command Reference
Enhancement: Added discussion and connections.
Enhancements: Added the following commands:
ALIGN, DMTSWT, DRES, ENCOFF, ESTORT, IANI,
OHALL, P163
Modified the following commands:
DMTTCM—range
DMTTCW—range
DVMLIM—range and default
DPWM—range and corrected mode information
ERROR—now includes messages E47and E48
SFB—In OS 2.10 or higher, SFB also functions to
set feedback type
TMTEMP—Added new reporting capabilities for
OS 2.10 or higher
Error Messages
Enhancement: Added error messages E47and
E48. See Chapter 7 Troubleshooting.
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Revision B Changes
This document, 88-021610-01B, supersedes 88-021610-1A. Changes
associated with Aries User Guide revisions, and document clarifications and
corrections are as follows:
Topic
Description
Fault Operation
Enhancement: Added a discussion about fault
operations for the DRIVE I/O connector.
DRIVE I/O connector-
internal circuit diagram
Correction: Simplified the circuit diagram for the
Enable input.
Inputs—Enable and
Reset
Enhancement: Added specifications detailing
electrical and timing characteristics on the DRIVE
I/O connector.
Outputs—Encoder
Enhancement: Added specifications detailing
electrical and timing characteristics on the DRIVE
I/O connector.
Inputs—Step &
Direction
Enhancement: Added specifications detailing
electrical and timing characteristics on the DRIVE
I/O connector.
Inputs--Analog
Enhancement: Added specifications detailing
electrical and timing characteristics on the DRIVE
I/O connector.
RS-485 Communication Correction: Both RS-485 channels are Tx/Rx.
Tuning
Enhancements: Added Chapter 5 Tuning,
describing servo tuning.
Added Appendix D Servo Tuning Flow Diagram.
Command Reference
Enhancements: Added the following commands:
DMTD, DMTJ, DNOTAD, DNOTAF, DNOTAQ, DNOTBD,
DNOTBF, DNOTBQ, DNOTLD, DNOTLG, SGVF.
Modified CONFIG—now includes error messages
E13-E18.
Error Messages
Enhancement: Added error messages E13-E18.
See Chapter 7 Troubleshooting.
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Chapter 1 Introduction
C H A P T E R O N E
Introduction
IN THIS CHAPTER
Illustrations in this Installation Guide .........................................................20
Technical Support......................................................................................20
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Aries Products—Overview
The Aries drives are a family of super compact, super efficient digital servo
drives. Their maximum continuous shaft power ranges from 100 Watts to
3000 Watts (3kW). Ready for direct panel mounting, you can select the
precise power level needed for your application.
Aries Product Descriptions
Aries Servo Drives can control the torque, velocity, and position of servo
motors using a digital current loop. Control of Aries Drives is performed using
controllers, which have standard ±10V torque command, ±10V velocity
command, or 5V TTL step & direction interface.
For Aries drives using the analog or step and direction command interface,
configure the drives through RS-232/485 using the Aries Support Tool on a
personal computer (PC), or other standard communication software. For
Aries drives using the Ethernet Powerlink command interface, configure the
drives through Ethernet using the ACR-View software on a PC. Many
advanced features are standard on the product including “plug and play”
capabilities with Aries-compatible motors.
Aries Names
The following diagram explains the Aries part numbers:
AR – 01 A E
Drive Type...............................................Aries
Maximum Shaft Power............................01 = 100W
02 = 200W
04 = 400W
08 = 750W
13 = 1300W
20 = 2000W
30 = 3000W
Command Interface ................................A = Analog
S = Step & Direction
P = Ethernet Powerlink
Motor Feedback ......................................E = Encoder
R = Resolver
Input Power
Motor Power
AR-01xx, AR-02xx
AR-04xx, AR-08xx, AR-13xx...................120/240 VAC single-phase mains
motor power
AR-20xE..................................................240 VAC single-phase or three-
phase mains motor power
AR-30xE..................................................240 VAC three-phase mains motor
power only
Control Power
AR-01xx through AR-30xE......................120/240 VAC single-phase mains
control power
Chapter 1 Introduction 17
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Output Power Level
Servo Motor Drives
equates to a motor bus voltage of 170/340 VDC.
Drive
Continuous
Current (RMS) Current
(RMS)
Peak
Continuous Shaft
Output Power
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
1A
3A
100W, 0.13 hp*
200W, 0.27 hp*
400W, 0.53 hp*
750W, 1.0 hp*
1.75A
3A
5.25A
9A
4.50A
6.3A
10A
16A
13.5A
14.07A
30A
1300W, 1.75 hp*
2000W, 2.7 hp**
3000W, 4.04 hp**
48A
*
Maximum rating at 240 VAC, single-phase
** Maximum rating at 240 VAC, three-phase
Table 1 Output Power Level
Options
Compatible Parker Products
Servo Controller
(±10V torque or velocity mode)...............ACR series or other Parker
controller
Stepper Controller (S&D mode)..............ACR series or other Parker
controller
Software..................................................Aries Support Tool
For information about cables, motors, etc., see “Chapter 2 Mechanical
18 Aries User Guide
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Checking Your Shipment
Inspect your shipment carefully. You should have received the corresponding
ship kit along with your drive.
Ship Kit Items
The following items ship with the AR-01xx through AR-13xx drives:
Part
Part Number
Aries Quick Reference Guide
AR-01xx AR-02xx, AR-04xx, AR-08xx, & AR-13xx
88-021594-01C
R-Clamp
Screw (8-32 3/8 inch)
52-019734-01
51-006055-01
Aries compact disc containing the following:
•
•
Aries Hardware Installation Guide
Aries Support Tool
88-021610-01
Part number N/A
Table 2 Ship Kit Items, AR-01xx through AR-13xx
The following items ship with the AR-20xE and AR-30xE drives:
Part
Part Number
Aries Quick Reference Guide
AR-20xE and AR-30xE
88-025222-01A
R-Clamp
Screw (8-32 3/8 inch)
50-018127-01
51-006055-01
Aries compact disc containing the following:
•
•
Aries Hardware Installation Guide
Aries Support Tool
88-021610-01
Part number N/A
Table 3 Ship Kit Items, AR-20xE and AR-30xE
Motors
You may have ordered a motor from one of the following families of Parker
motors:
•
•
•
•
•
•
SE/SM Series
BE Series
•
•
•
•
•
LXR Linear Series
SL Linear Series
ILM Linear Series
SME Series
NeoMetric Series
J Series
MaxPlus Rotary
MaxPlus Linear
SMN Series
Chapter 1 Introduction 19
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Illustrations in this Installation Guide
Typically, the illustrations in this guide show the Aries AR-01xx and the
AR-30xE. These two models represent other models with similar features.
AR-01xx represents models AR-01xx through AR13xE. Model AR-30xE
represents the similar features of AR-20xE, as well.
If there is a need to illustrate differences between drives, relevant drawings
are shown for each drive.
Assumptions of Technical Experience
The Aries Drive is designed for industrial applications. To effectively install
and troubleshoot the Aries Drive, you must have a fundamental
understanding of the following:
•
•
•
•
Motion control applications
Electromechanical actuators
Electrical concepts such as voltage, current, switches, etc.
Serial Communication (RS-232 or RS-485) depending on which
communications protocol you are using.
Technical Support
For solutions to your questions about implementing the Aries Drive, first refer
to this manual. If you cannot find the answer in this documentation, contact
your local Automation Technology Center (ATC) or distributor for assistance.
If you need to talk to our in-house Application Engineers, please contact us
at the telephone numbers listed on page 2.
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Chapter 2 Mechanical Installation
C H A P T E R T W O
Mechanical
Installation
IN THIS CHAPTER
Dimensions................................................................................................28
Weight........................................................................................................30
Mounting Guidelines..................................................................................31
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Environment & Drive Cooling
The Aries drive operates in an ambient temperature range of 0°C (32°F) to
45°C (113°F) ambient air temperature for all models except the AR-13xx.
The AR-13xx operates in an ambient temperature range of 0°C (32°F) to
40°C (104°F) ambient air temperature. The drive can tolerate atmospheric
pollution degree 2. Only dry, non-conductive pollution is acceptable.
Therefore, it is recommended that the drive be mounted in a suitable
enclosure.
For drive cooling, you must install the drive so that the heatsink fins are
minimum top, bottom, and side installation clearances.
The Aries AR-20xE and AR-30xE models (2 and 3 kWs) employ internal fans
for additional cooling capacity. The AR-20xE has one fan and the AR-30xE
has two. The fans are located at the bottom of the drives. They draw air in
from the bottom, force it up over the heatsink, and out the vents in the top of
the drive. Fan speed is temperature-dependent in order to minimize audible
noise and extend fan operating life.
Notes
•
Avoid installing heat-producing equipment directly below a drive.
•
Make sure the ambient air temperature entering the drive or rising
up to the drive is within acceptable ambient temperature limits.
Under normal use, the temperature of air leaving the drive and
heatsink may be 25°C (45°F) above ambient temperature.
•
After installation, verify that the ambient air temperature directly
below the top-most drive does not exceed the maximum Ambient Air
Operating Temperature shown below. In addition, make sure that
nothing obstructs the circulating airflow.
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Environmental Specifications
(AR-01xx, AR-02xx, AR-04xx,
AR-08xx, AR-20xE, and AR-30xE)
Operating Temperature,
Maximum
Ambient Air
Minimum
45°C (113°F)
0°C (32°F)
Storage Temperature
Humidity
–40°C to 85°C (–40°F to 185°F)
0 to 95%, non-condensing
15g, 11 ms half-sine
10 to 2000 Hz at 2g
Shock
Vibration
Pollution Degree
Installation Category
2 (per IEC 61010)
2 (per IEC 61010)
Table 4 Environmental Specifications, AR-01xx through AR-08xx, AR-20xE and AR-30xE
Environmental Specifications
(AR-13xx)
Operating Temperature,
Maximum
Ambient Air
Minimum
40°C (104°F)
0°C (32°F)
Storage Temperature
Humidity
–40°C to 85°C (–40°F to 185°F)
0 to 95%, non-condensing
15g, 11 ms half-sine
10 to 2000 Hz at 2g
Shock
Vibration
Pollution Degree
Installation Category
2 (per IEC 61010)
2 (per IEC 61010)
Table 5 Environmental Specifications, AR-13xx
Cabinet Cooling
power dissipation per drive.
AR-02xx
the Parker BE231D motor.
Chapter 2 Mechanical Installation 23
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Figure 1 Cabinet Losses for AR-02xx when connected to a Parker BE231D motor
Shaft Power
Voltage
120 VAC
240 VAC
0W*
15W
32W
20W
25W
44W
200W
34W
47W
*
Drive enabled, zero torque.
Table 6 AR-02xx Power Dissipation
AR-08xx
the Parker BE343J motor.
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Figure 2 Cabinet losses for AR-08xx when connected to a Parker BE343J motor
Shaft Power
Voltage
120 VAC
240 VAC
0W*
13W
24W
200W
42W
60W
700W
60W
73W
*
Drive enabled, zero torque.
Table 7 AR-08xx Power Dissipation
AR-13xx
the Parker MPM1421CSJXXXN motor.
Chapter 2 Mechanical Installation 25
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Figure 3 Cabinet losses for AR-13xx when connected to a Parker MPM1421CSJ motor
Shaft Power
Voltage
120 VAC
240 VAC
0W*
14W
25W
700W
82W
95W
1300W
130W
146W
*
Drive enabled, zero torque.
Table 8 AR-13xx Power Dissipation
AR-30xE
the Parker MPM1422CSJXXXN motor.
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Figure 4 Cabinet losses for AR-30xE when connected to a Parker MPM1422CSJ motor
Shaft Power
Voltage
0W*
1500W
3000W
240 VAC
35W
103W
172W
*
Drive enabled, zero torque.
Table 9 AR-30xE Power Dissipation
Cabinet Cooling Calculations
Use the motor’s speed torque curve to determine the torque when the motor
is at running speed for your application. If the torque is not known, use the
“knee” (where the peak-torque curve intersects the continuous-torque curve)
of the graphed motion—this assumes the worst-case scenario for continuous
motion.
PMOTOR
P
=
∗
(
1− EDRIVE
)
LOSS
EMOTOR
PLOSS
PMOTOR
EMOTOR
EDRIVE
=
power dissipated to cabinet (Watts)
=
=
shaft power of the motor (Watts)
efficiency of motor (Percent), approximately 0.85
=
efficiency of Aries drive (Percent), approximately 0.90
Chapter 2 Mechanical Installation 27
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Dimensions
There are three basic housing sizes for the Aries drives. However, the height
of the heatsink fins varies with each model, except for the AR-20xE and
AR-30xE whose dimensions are identical. This section contains the
dimensions for all Aries models.
Drive Dimensions—AR-01xx & AR-02xx
Figure 5 Drive mounting for the AR-01xx & AR-02xx
Fin Height—
in (mm)
Outside Width
(OW)—in (mm)
Overall Depth
with Cables—in (mm)
Drive
AR-01xx
AR-02xx
0.01 (0.25)
0.375 (9.5)
2.29 (58.2)
2.65 (67.3)
7.60 (193.0)
7.60 (193.0)
Table 10 AR-01xx and AR-02xx Drive Dimensions
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Drive Dimensions—AR-04xx, AR-08xx, & AR-13xx
Figure 6 Drive mounting for the AR-04xx, AR-08xx, and AR-13xx
Fin Height—
in (mm)
Overall Width
(OW)—in (mm)
Overall Depth
with Cables—in (mm)
Drive
AR-04xx
AR-08xx
AR-13xx
0.625 (15.9)
1.00 (25.4)
2.00 (50.8)
2.90 (73.7)
3.28 (83.3)
4.28 (108.7)
7.60 (193.0)
7.60 (193.0)
7.60 (193.0)
Table 11 AR-01xx , AR-02xx, & AR-13xx Drive Dimensions
Chapter 2 Mechanical Installation 29
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Drive Dimensions—AR-20xE & AR-30xE
Figure 7 Drive mounting for the AR-20xE and AR-30xE
Overall Depth
with Cables—in
(mm)
Fin Height—
in (mm)
Overall Width
(OW)—in (mm)
Drive
AR-20xE &
AR-30xE
1.48 (37.5)
4.67 (118.5)
9.27 (235.5)
Table 12 AR-20xE and AR-30xE Drive Dimensions
Weight
Weight
pounds (kg)
Weight
pounds (kg)
Drive
Drive
AR-01xx
AR-02xx
AR-04xx
AR-08xx
1.68 (0.76)
AR-13xx
AR-20xE
AR-30xE
3.60 (1.63)
7.35 (3.33)
7.40 (3.36)
1.90 (0.86)
2.54 (1.15)
2.82 (1.28)
Table 13 Drive Weight
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Mounting Guidelines
The Aries drive is a vented product. To prevent material spilling into the
drive, mount it under an overhang or in a suitable enclosure.
Aries products are made available under “Restricted Distribution” for use in
the “Second Environment” as described in EN 61800-3 1996, page 9.
Cable Routing
Route high power cables (motor and mains) at right angles to low power
cables (communications and inputs/outputs). Never route high and low power
cables parallel to each other.
Panel Mounting
The mounting clearance requirements are the same for all models of the
Aries Drive. They are shown in Figure 8.
Figure 8 Panel Layout Dimensions for Aries Drives
Chapter 2 Mechanical Installation 31
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Chapter 3 Electrical Installation
C H A P T E R T H R E E
Electrical
Installation
IN THIS CHAPTER
Power Supply.............................................................................................35
Multiple Drive Installations.........................................................................48
Brake Relay (Optional) ..............................................................................50
Regeneration Protection............................................................................54
Connector Descriptions .............................................................................57
Installation Test..........................................................................................72
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Installation Safety Requirements
Aries drives meet the requirements of both the European LVD (Low Voltage
Directive) and EMC (Electromagnetic Compliance) directives when installed
according to the instructions given within “Appendix C Regulatory
As a rule, it is recommended that you install the drive in an enclosure to
protect it from atmospheric contaminants and to prevent operator access
while power is applied. Metal equipment cabinets are ideally suited for
housing the equipment because they provide operator protection, EMC
screening, and can be fitted with interlocks arranged to remove all hazardous
motor and drive power when the cabinet door is opened.
Do not arrange the interlocks to open circuit the motor phase connections
while the system is still powered as this could damage the drive.
Precautions
During installation, take the normal precautions against damage caused by
electrostatic discharges.
•
•
Wear earth wrist straps.
Include a mains power switch or circuit breaker within easy reach of
the machine operator. Label, clearly, the switch or breaker as the
disconnecting device.
Auto-Configuration for Encoders
The Aries drive recognizes “smart encoders” attached to Parker motors. You
can apply power to the drive, and the drive reads all necessary motor
parameters from the motor. The drive and motor are then ready to use.
If a drive is swapped out for any reason, you can insert a replacement—the
replacement drive automatically reads the motor parameters.
Several drive related parameters may need additional configuration: CMDDIR,
DCMDZ, and ADDR.
Chapter 3 Electrical Installation 33
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System Installation Overview
The figures in this section illustrate the components necessary for electrical
installation of models AR-20xE and AR-30xE, whose connectors differ from
the other five models.
The illustration shows the use of the Aries dongle (part number 71-021609-
01), which connects the Aries drive to both a controller and a personal
computer (PC). The dongle is for setup purposes only. Do not use the dongle
for permanent installation.
AR-01xx, AR-02xx, AR-04xx, AR-08xx, & AR-13xx
Installation
Figure 9 Overview of System Installation for AR-01xx to AR-13xx
Warning — This product has been developed for industrial environments. Due
to exposed high voltage terminals, this product must not be accessible to users
while under normal operation.
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To operate the Aries drive with separate control and motor AC input, remove
the factory installed external jumpers. With the jumpers installed, apply
factory installed jumpers.
Figure 10 AR-01xx to AR-13xx Factory Installed Jumpers
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AR-20xE and AR-30xE Installation
Figure 11 Overview of System Installation for AR-20xE & AR-30xE
Warning — This product has been developed for industrial environments. Due to
exposed high voltage terminals, this product must not be accessible to users
while under normal operation.
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To operate the Aries drive with separate control and motor AC input, remove
the factory installed external jumpers. With the jumpers installed, apply
factory installed jumpers.
Figure 12 AR-20xE to AR-30xE Factory Installed Jumpers
Connector Locations
All Aries drive models have identical DRIVE I/O and Motor Feedback
connectors. However, the connectors for motor and control power, on the
AR-20xE and AR-30xE differ from the other models due to their higher power
capacity. The two power connectors on models AR-01xx through AR-13xx
are removable. The two power connectors on Models AR-20xE and AR-30xE
are non-removable. Descriptions of individual connectors and their
Figure 13 shows the names and location of the connectors on Aries drive
power models AR-20xE and AR-30xE.
Chapter 3 Electrical Installation 37
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Power Supply
Input Power
The mains motor power supply and control power supply for the Aries Drive
must meet the following requirements.
Model
Requirements
Motor Input Power
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, AR-13xx
(L1, L2)
120/240 VAC, 50/60 Hz, single phase
AR-20xE
(L1, L2, L3)
240 VAC, 50/60 Hz, single phase or
three phase
AR-30xE
240 VAC, 50/60 Hz, three phase only
(L1, L2, L3)
Control Input Power
All models
(C1, C2)
120/240 VAC, single phase
Figure 15 Input Power Requirements
Mains/Input Power Connector
AR-01xx, AR-02xx,AR-04xx, AR-08xx, AR-13xx
Connector Type.......................................Removable screw terminal
Terminals ........................................7
Pitch................... 0.200 in (5.08 mm)
Wire Range....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire Strip length .. 0.31 in (7.87 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
AR-20xE, AR-30xE
Connector Type.......................................Non-Removable screw terminal
Terminals ......................................10
Pitch........................ 0.315 in (8 mm)
Wire Range....................10-22 AWG
.......................................12-23 SWG
....................................(0.5-4.0 mm2)
Wire Strip length .... 0.25 in (6.5 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
Chapter 3 Electrical Installation 39
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AC Power Supply Connection
power source and control power sources to the drive.
•
The AR-20xE can accept single-phase or three-phase 240V motor
power. For single-phase connections, make no connection to
terminal labeled L3.
•
The AR-30xE can only accept three-phase 240V motor power.
Use the terminal connector that is supplied with the drive. For the Protective
Earth ground, make the connection directly by means of a low-impedance
path less than or equal to 0.1 ohm (no fuses, etc.). Under normal operation,
no current should flow through the Protective Earth connection.
If desired, you can jumper two phases of the motor input power to the control
input power for a single AC power connection. Jumpers are installed at the
factory for this purpose. Remove the jumpers to apply separate control and
motor mains power.
Figure 16 Motor and Control Mains Power Supply Connection
Note: See warnings on next page.
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Warning — You must connect the drive’s protective conductor terminal, marked
with the earth symbol , to a reliable system Protective Earth.
Warning — The drive’s connector strip terminals have hazardous voltages when
power is applied to the drive, and up to several minutes after power is removed.
Lower voltages may still be present for several minutes after power is removed.
During normal operation, these high voltage terminals must not be accessible to
the user.
Motor Power Fuse Information
Aries drives have no user-serviceable internal fuses. For safety, you must
provide a fuse in each of the AC Mains Motor power input lines. To
determine the proper fuse type and size for your application, see Table 14.
(For fuse recommendations for Control-power input lines, see “Control Power
Drive
AC Voltage Fuse Style
Rating Fuse Type
120 VAC
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
240 VAC
240 VAC
125 VAC Time Delay 10A
250 VAC Time Delay 10A
RK5 or better
AR-01xx
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
RK5 or better
125 VAC Time Delay 10A
250 VAC Time Delay 10A
125 VAC Time Delay 20A
250 VAC Time Delay 20A
125 VAC Time Delay 20A
250 VAC Time Delay 20A
125 VAC Time Delay 30A
250 VAC Time Delay 30A
250 VAC Time Delay 40A
250 VAC Time Delay 40A
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE*
AR-30xE*
* The 40A fuse is recommended regardless of whether the input power is
single-phase or 3-phase.
Table 14 Motor Power Fuse Information
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Table 15 lists part numbers (at time of publication) for suitable fuses from
several manufacturers. These fuses are type RK5 (time delay fuses).
Ferraz
Shawmut
(formerly
Gould)
Amps
Bussmann
Littelfuse
10
FRN-R-10
FRN-R-20
FRN-R-30
FRN-R-40
TR10R
FLNR10
20
30
40
TR20R
TR30R
TR40R
FLNR20
FLNR30
FLNR40
Table 15 Fuse Part Numbers
Drive Inrush Current
The drive inrush current is limited by an internal thermistor that changes
value with the ambient temperature. Drive inrush current is therefore
dependent upon the temperature of the surrounding environment (Tamb). To
determine the drive inrush current for your drive, see Table 16.
AC Voltage
Drive Inrush
(25°C Tamb
Drive Inrush
(50°C Tamb
Drive Type
)
)
120 VAC
34A
73A
AR-01xx
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
120 VAC
240 VAC
240 VAC
240 VAC
68A
34A
68A
17A
34A
17A
34A
17A
34A
68A
68A
146A
73A
AR-02xx
AR-04xx
AR-08xx
AR13xE
146A
36A
73A
36A
73A
36A
73A
AR-20xE
AR-30xE
155A
155A
Table 16 Drive Motor Power Inrush Current
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Output Power
Table 17 contains the continuous and peak output power ratings for all Aries
drive models.
Continuous Output
Peak Output
Drive
Current (Amps,
RMS)
Shaft Power*
(Watts, max)
Current
(Amps, RMS)
Shaft Power
(Watts, max)
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
1.0
1.75
3.0
4.5
6.3
10
100
3.0
300
200
5.25
9.0
600
400
1200
2250
3900
6000
9000
750
13.5
14.1
30
1300
2000
3000
16
48
*
Maximum shaft power rating at 240 VAC
Table 17 Output Power-Continuous and Peak
Motor Connector
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, AR-13xx
Connector Type.......................................Removable screw terminal
Terminals ........................................6
Pitch................... 0.200 in (5.08 mm)
Wire range .....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire strip length...... 0.310 in (8 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
AR-20xE, AR-30xE
Connector Type.......................................Non-Removable screw terminal
Terminals ......................................10
Pitch........................ 0.315 in (8 mm)
Wire range .....................10-22 AWG
.......................................12-23 SWG
....................................(0.5-4.0 mm2)
Wire strip length..... 0.25 in (6.5 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
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Output Power Connection
Figure 17 shows how to connect the motor cable to the drive. Use the screw
terminal connector that is installed in the drive. Current Parker motor cables
are marked with white numbers to indicate the phases. Connect Motor Phase
1 Æ U, 2 Æ V, and 3 Æ W, and Motor Safety Earth to the Protective Earth
ground connector.
Figure 17 Output Power Connection
Table 18 contains information for making connections with Parker Hannifin
motors.
Hi-Flex/ PS/
Gemini
Legacy Parker
Hannifin
Phase
Legacy MaxPlus
U
V
1
2
3
Red/Yellow
Red
White/Yellow
Black/Yellow
Green/Yellow
Black
Blue
W
Green/Yellow
Green
Table 18 Wiring to Motors
Note: On models AR-20xE and AR-30xE, the Motor Brake Relay is on a
Warning — You must connect the Motor Safety Earth conductor terminal,
marked with the earth symbol , to the motor cable’s motor-safety-earth wire
(green/yellow).
Note: See additional warning on next page.
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Warning — The drive’s connector strip terminals have hazardous voltages
when power is applied to the drive, and up to several minutes after power is
removed. Lower voltages may still be present for several minutes after power
is removed. During normal operation, these high voltage terminals must not
be accessible to the user.
External DC Link Inductor (Optional)
The Aries AR-20xE and AR-30xE drives have two extra terminals that allow
an external DC link inductor to be added if required. To add the DC link
inductor, remove the factory installed shorting link, and connect the inductor
as shown in Figure 18.
Figure 18 External DC Link Inductor Connection
If a drive is supplied from a low-impedance source (for example, a
transformer that has a kVA rating more than 10 times the drive), the input line
currents to the drive can be non-sinusoidal. They may have a peak that is
two to three times the rms value, compared to 1.4 times for a sinusoidal
waveform. This results in higher currents being drawn from the line at rated
power and harmonics that might interfere with other equipment. The addition
of a DC link inductor reduces the severity of these problems.
Table 19 provides compatible DC link inductors for the Aries AR-20xE and
AR-30xE.
Recommended
Inductance
Drive Type
DC Current Rating
AR-20xE
AR-30xE
1.0 to 3.0 mH
0.75 to 2.0 mH
10A
15A
Note: Where within the recommended range, the larger inductance gives a better
shape to the input current waveform, but at the expense of larger physical size.
Table 19 AR-20xE & AR-30xE DC Link Inductors
Chapter 3 Electrical Installation 45
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Control Power Supply
With Mains power applied to the Control power terminals C1 and C2, the
drive’s internal control board remains powered when the primary motor AC
power source (L1, L2 (L3)) is disconnected. When operated in this
configuration, the Control power input performs a “keep-alive” function. The
keep-alive circuit maintains several important functions, including
communications, diagnostics, position feedback, and other logic functions,
while removing power from the motor output connection. (See the following
Remove the factory installed jumpers to use the product with separate
control and motor mains AC power input.
Fuse Information
Fuse Rating.............................................1 Amp
Fuse Type ...............................................Class CC (Bussmann KTK-R-1 or
equivalent UL listed fuse)
Input Voltage Range ...............................120/240 VAC, 50/60 Hz
Input Current ...........................................0.2 Amps RMS
Control Power Functions.........................Communications
Diagnostics
Motor position feedback
Fault output in fault mode
Brake relay in brake mode
Reset input
Control Power Connector
AR-01xx, AR-02xx,
AR-04xx, AR-08xx, AR-13xx
Connector Type.......................................Removable screw terminal
Terminals ........................................7
Pitch................... 0.200 in (5.08 mm)
Wire Range....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire Strip length .. 0.31 in (7.87 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
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AR-20xE, AR-30xE
Connector Type.......................................Non-Removable screw terminal
Terminals ........................................8
Pitch...................... 0.400 in (10 mm)
Wire Range....................12-28 AWG
.......................................14-29 SWG
................................(0.12-3.30 mm2)
Wire Strip length 0.250 in (6.35 mm)
Control Power Connection
Figure 19 shows how to connect the Control power source to the drive. Use
the screw terminal connector that is supplied with the drive.
Figure 19 Mains Control Input Power
Warning — You must connect the drive’s protective conductor terminal,
marked with the earth symbol , to a reliable system Protective Earth.
Warning — The drive’s connector strip terminals have hazardous
voltages when power is applied to the drive, and up to several minutes
after power is removed. Lower voltages may still be present for several
minutes after power is removed. During normal operation, these high
voltage terminals must not be accessible to the user.
Chapter 3 Electrical Installation 47
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Multiple Drive Installations
In a typical cabinet installation, a single mains line connects to a terminal bus
inside the cabinet. Then from the terminal bus, make individual connections
for Mains and Control power to the corresponding connector(s) on each
drive. Be sure to install fuses for each drive between the terminal bus and the
drive.
Tie each drive’s Protective Earth
conductor terminal directly to the system
operation, no current should flow through the Protective Earth ground.
Safety Earth Connections
AR-01xx, AR-02xx, AR-04xx, AR-08xx, and AR-13xx
For multiple drive installations, Parker Hannifin recommends a single point or
earth connection for Aries models AR-01xx through AR-13xx.
Figure 20 Multiple Drives AR-01xx to AR-13xx: Single Point Safety Earth
AR-20xE and AR-30xE
Figure 21 represents a typical star safety earth connection for Aries models
AR-20xE and AR-30xE. Note that the AR-20xE and AR-30xE Motor/Power
connector has two Earth ground terminals⎯one for the motor and one for
input power. Be sure to use the VAC INPUT POWER
terminal.
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Brake Relay (Optional)
[The Brake Relay connection provides a safety feature for your motion
control system, particularly for vertical applications. The drive acts as a
control switch for the motor brake (if a brake is present). When 24V is applied
from an outside power supply through the drive’s BK terminals, the motor
brake is disabled. When the power supply is interrupted, or the drive faults or
is disabled, the brake is enabled and stops shaft rotation. Connector and
wiring information follow in this section.
Brake Relay Connector
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, AR-13xx
Connector Type.......................................Removable screw terminal
Terminals ........................................6
Pitch................... 0.200 in (5.08 mm)
Wire range .....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire strip length...... 0.310 in (8 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
AR-20xE, AR-30xE
Connector Type.......................................Non-Removable screw terminal
Terminals ........................................8
Pitch...................... 0.400 in (10 mm)
Wire Range....................12-28 AWG
.......................................14-29 SWG
................................(0.12-3.30 mm2)
Wire Strip length 0.250 in (6.35 mm)
Brake Relay Connection
On all models, this set of terminals is optically isolated from the drive’s
internal logic.
Figure 22 Typical Brake Relay Connection
Important warnings:
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Warning — You must connect the drive’s protective conductor terminal, marked
with the earth symbol , to a reliable system Protective Earth.
Warning — The drive’s connector strip terminals have hazardous voltages when
power is applied to the drive, and up to several minutes after power is removed.
Lower voltages may still be present for several minutes after power is removed.
During normal operation, these high voltage terminals must not be accessible to
the user.
Motor with Full Wave Rectifiers
Some Parker brake motors (BE, SM, SE, NeoMetric, and J series motors,
serial numbers greater than 010904xxxxx) contain full wave rectifiers, so
connection polarity is not an issue during installation.
Connecting the Brake Relay
1. Connect one red/blue brake wire (Parker Motor cable or equivalent) to
the BK terminal of the Motor connector on Aries models AR-01xx to
AR-13xx, or the Control connector on models AR-20xE and AR-30xE.
2. Connect the second red/blue brake wire (Parker Motor cable or
equivalent) to the 24V return on your power supply.
3. Connect the +24 VDC power supply to the second BK terminal of the
Motor connector on Aries models AR-01xx to AR-13xx, or the Control
connector on models AR-20xE and AR-30xE.
The following shows a typical application—connecting a motor brake to the
relay terminals.
Figure 23 Brake Relay Connection for Parker Motors
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Motors without Full Wave Rectifiers
When using Parker MaxPlus motors, Parker motors with serial numbers less
than 010904xxxxx, or non-Parker motors, you must install a fly-back diode.
Consult the specifications or the manufacturer of your motor.
Connecting the Brake Relay
1. Connect one red/blue brake wire (Parker Motor cable or equivalent) to
the BK terminal of the Motor connector (Aries drive).
2. Connect the second red/blue brake wire (Parker Motor cable or
equivalent) to the 24V return on your power supply.
3. Between the two red/blue wires, connect the fly-back diode. See
4. Connect the +24 VDC power supply to the second BK terminal of the
Motor connector (Aries drive).
Figure 24 shows a typical installation.
Figure 24 Brake Relay Connection for Non-Parker Motors
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Relay Operation
Drive Condition
Enabled
Relay State
Closed (conducting)
Open
Faulted
No AC power on L1 and L2*, or drive not
enabled
Open
*
Mains Control power on C1 and C2 does not affect the relay. With mains power applied
to C1 and C2, the relay remains open if AC power is not applied to the L1 and L2
terminals.
Table 20 Brake Relay Operation
Relay Specifications
Relay Type..............................................Solid State Relay
Normally open
Relay Maximum Rating...........................1 Amp at 24 VDC
Warning — Do not exceed the ratings of the brake relay. If required,
control a suitable external relay with this relay to meet your power
requirements.
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Regeneration Protection
The Aries drive models AR-20xE and AR-30xE have internal regeneration
power dump (dissipation) resistors. Models AR-01xx through AR-13xx do
not. However, all models can utilize an external regeneration resistor.
Regeneration Connection
To use a external regeneration (power dump) resistor, connect your external
resistor to the R+ and R- terminals as follows:
•
•
For models AR-01x to AR-13xx, use the Mains connector.
For models AR-20xE and AR-30xE, use the Control connector.
Figure 25 illustrates the external regeneration resistor connections.
Figure 25 External Regeneration Connection
Important! For models AR-20xE and AR-30xE, you must remove the
factory-installed link between RINT and R− when you connect the
external regeneration resistor. (Otherwise the internal regeneration
resistor will still be in the circuit, and its thermal protection circuit limits
the performance).
For information on selecting a suitable external regeneration (power dump)
resistor, see “Appendix B External Power-Dump Resistor Selection.”
Warning — The drive’s connector strip terminals are at hazardous voltages
when power is applied to the drive, and up to several minutes after power is
removed. Lower voltages may still be present for several minutes after power
is removed.
During normal operation, these high voltage terminals must not be accessible
to the user.
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Internal Regeneration Capability
The internal regeneration resistor of the AR-20xE and AR-30xE is capable of
dissipating 1kW for 1 second and up to 100 Watts continuously (depending
upon heatsink temperature). If the calculated temperature of the internal
regeneration resistor exceeds 150°C (302°F), the drive turns off the
regeneration circuit and may experience an over-voltage fault.
Similarly, models AR-01xx through AR-13xx may experience an over-voltage
fault if the regeneration exceeds the absorbent capacity of the drive’s internal
bus capacitors, as shown in Table 21.
Regeneration Absorption
The available absorption varies based on mains voltage and the drive’s
internal capacitance. The drives can absorb the following amounts of
regenerated energy in their internal capacitors:
Drive
Absorb (Joules)
120 VAC
Absorb (Joules)
240 VAC
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
28
43
57
72
9
14
19
24
35
50
50
104
N/A
N/A
Table 21 Regeneration Absorption
For more specifications about energy absorption by the Aries drive’s
For more information about selecting an external power-dump resistor, see
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LEDs⎯Drive Status Indicators
The drive has two bi-color LEDs. The LED on the left displays yellow or
green colors; The LED on the right displays red or green colors. The
following tables describe LED illumination states and the conditions they
indicate.
Normal Operation
LED–Left
LED–Right
Green
What it means
Off
Power on, enabled
Yellow
Green
Power on, regeneration active
Power on, disabled–No Fault
Power on, boot process
Waiting for OS download
OS download in process
Off
Red
Yellow
Off
Off
Red (flashing)
Red (flashing)
Yellow (flashing)
Table 22 LED Status Indicator-Normal Operation
Internal Drive Faults
LED–Left
LED–Right
Red
What it means
Yellows
Control power
mode active
Yellow & 1 Green (flashing)
Yellow & 2 Green (flashing)
Yellow & 3 Green (flashing)
Yellow & 4 Green (flashing)
Yellow & 5 Green (flashing)
Red
Red
Red
Red
Red
Bridge Fault
Feedback Fault
Thermal Fault
Other Fault
Encoder Loss
Table 23 LED Status Indicator-Internal Drive Fault
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Connector Descriptions
Motor Mains Power Connector
The drive’s Mains screw terminal connector provides a connection for AC
Mains power to your drive. (For connection information, see “Input Power” on
the others. Specifications for the connectors follow in this section.
On models AR-01xx through AR-13xx, the Mains connector also serves as a
connector for Control power (C1 and C2) and a power dissipation resistor
(R+ and R–). For more information on these additional connections, see
This connector is removable.
On models AR-20xE and AR-30xE, the Motor/Power connector serves as the
connector for Motor Mains power (L1, L2, L3, and ), as well as for output
power to the motor (U, V, W, and ) and a DC Link Inductor. For more
removable.
Figure 26 Mains/Input Power Connector
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Mains/Input Power Connector
AR-01xx, AR-02xx,
AR-04xx, AR-08xx, AR-13xx.................Amphenol PCD: OSTTJ075102
Parker Hannifin Part Number..................43-021069-01
Connector Type.......................................Removable screw terminal
Terminals ........................................7
Pitch................... 0.200 in (5.08 mm)
Wire Range....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire Strip length .. 0.31 in (7.87 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
AR-20xE, AR-30xE ................................Molex: 39960-0110
Parker Hannifin Part Number..................N/A
Connector Type.......................................Non-Removable screw terminal
Terminals ......................................10
Pitch........................ 0.315 in (8 mm)
Wire Range....................10-22 AWG
.......................................12-23 SWG
....................................(0.5-4.0 mm2)
Wire Strip length .... 0.25 in (6.5 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
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Output Power Connector
The drive’s Motor screw terminal connector provides output power to your
connector differs between the two largest Aries models and the others.
Specifications for the connectors follow in this section.
On models AR-01xx through AR-13xx, the Motor connector also serves to
connect an external motor brake to the drive’s internal solid-state relay (BK).
This connector is removable.
On models AR-20xE and AR-30xE, the MOTOR/POWER connector serves as
the connector for output power to the motor, as well as for Mains power (VAC
Input Power) and a DC Link Inductor. For information on these additional
Figure 27 Output (MOTOR) Power Connector
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Motor Connector
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, AR-13xx .................................Amphenol PCD: OSTTJ075102
Parker Hannifin Part Number..................43-021068-01
Connector Type.......................................Removable screw terminal
Terminals ........................................6
Pitch................... 0.200 in (5.08 mm)
Wire range .....................12-26 AWG
.......................................14-27 SWG
................................(0.12-3.30 mm2)
Wire strip length...... 0.310 in (8 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
AR-20xE, AR-30xE ................................Molex: 39960-0110
Parker Hannifin Part Number..................N/A (not replaceable)
Connector Type.......................................Non-Removable screw terminal
Terminals ......................................10
Pitch........................ 0.315 in (8 mm)
Wire range .....................10-22 AWG
.......................................12-23 SWG
....................................(0.5-4.0 mm2)
Wire strip length..... 0.25 in (6.5 mm)
Torque....7.0 in–lbs nom. (0.79 N-m)
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AR-20xE & AR30xE Control Connector
On the AR-20xE & AR 30xE models, the Control connector serves for three
connections: an external power dump resistor (EXTERNAL REGEN), a control
power circuit (CONTROL INPUT POWER), and a safety brake relay (BRAKE
RELAY). The connector is an eight-position non-removable screw terminal.
Specifications for the connector follow in this section.
The Control connector has a factory-installed link between RINT and R− for an
internal regeneration resistor, which provides thermal protection. For more
Figure 28 AR-20xE & AR30xE Control Connector
AR-20xE, AR-30xE ................................PCD: ELM021100
Parker Hannifin Part Number..................N/A (not replaceable)
Connector Type.......................................Non-Removable screw terminal
Terminals ........................................8
Pitch...................... 0.400 in (10 mm)
Wire Range....................12-28 AWG
.......................................14-29 SWG
................................(0.12-3.30 mm2)
Wire Strip length 0.250 in (6.35 mm)
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Motor Feedback Connector—Encoder
Inputs for the resolver feedback, motor thermal switch, and hall effects are
located on the 15-pin Motor Feedback connector.
Figure 29 MOTOR FEEDBACK connector, female drive connector pinout
Important — Encoder inputs use a DS26LV32 differential line receiver.
Parker Hannifin recommends 26LS31 (or compatible) differential line driven
encoders.
Single ended encoders are not compatible.
Figure 30 MOTOR FEEDBACK connector, internal circuit diagram
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Pinout—MOTOR FEEDBACK Connector
Note: A box surrounding pins indicates a requirement for twisted pair wiring.
Pin
Signal
Description
ENC Z+ / Data+
ENC Z– / Data–
DGND
1
Encoder Z Channel in
Encoder Z Channel in
Encoder power return
+5 VDC Encoder power
+5 VDC Hall power
Hall power return
2
3
+5 VDC
4
+5 VDC
5
DGND
6
ENC A– / SIN–
ENC A+ / SIN+
Hall 1 / SCLK+ *
Thermal+
7
Encoder A Channel in
Encoder A Channel in
Hall 1 input
8
9
10
15
11
12
13
14
Motor thermal switch/thermistor
Motor thermal switch/thermistor
Encoder B Channel in
Encoder B Channel in
Hall 2 input
Thermal–
ENC B / COS–
ENC B+ / COS+
Hall 2 / SCLK– *
Hall 3
Hall 3 input
*
When using the SinCos protocol, pins 9 and 13 require twisted pair wiring.
Table 24 MOTOR FEEDBACK Connector Pinout
Inputs—Encoder
Description
Min
Typical
Max
+7
Units
V
Common Mode Range
Current—Encoder
Current—Hall
-7
250
250
+200
mA
mA
Differential Threshold Voltage
-200
mV
Differential Termination
Impedance
120
ohms
Thermal Switch Current
2
mA
V
Thermal Switch Voltage
Maximum (supplied)
15
Input Frequency
(pre-quadrature)
5
MHz
Note: All parameters are at the connector pin.
Table 25 Inputs—Encoder Inputs Electrical/Timing Characteristics
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Connector Specification—Aries Drive
Manufacturer...........................................KYCON or equivalent
Connector Type.......................................15-Pin High Density
D-Subminiature
(female socket)
KYCON Part Number..............................K66-E15S-NR
Connector Specification—Mating Connector
Mating connectors are not provided with Aries drives. Parker cables are
available with mating connectors attached.
Manufacturer...........................................AMP or equivalent
Connector Type.......................................15-Pin High Density D-Subminiature
(male connector)
Cable Kit..................................................AMP Part Number 748473-1
Includes: 748364-1 connector,
shield, enclosure, and two jack
screws
(does not include contacts or
ferrules)
Contacts..................................................Crimp style
30µ” Gold—AMP Part Number
748333-4
Gold Flash—Amp Part Number
748333-7
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Motor Feedback Connector—Resolver
Inputs for the encoder feedback, motor thermal switch, and hall effects are
located on the 15-pin Motor Feedback connector.
Figure 31 MOTOR FEEDBACK connector, female drive connector pinout
Figure 32 MOTOR FEEDBACK connector for resolver option, internal circuit diagram
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Pinout—MOTOR FEEDBACK Connector for Resolver Option
Note: A box surrounding pins indicates a requirement for twisted pair wiring.
Signal
Pin
1
Description
No connection
No connection
Thermal-
—
2
—
3
Motor thermal switch/thermistor
Resolver excitation signal
Resolver excitation signal
—
Reference+
Reference-
No connection
Thermal-
4
15
5
6
Motor thermal switch/thermistor
Motor thermal switch/thermistor
SIN resolver feedback signal
SIN resolver feedback signal
—
Thermal+
SIN–
10
7
SIN+
8
No connection
COS–
9
11
12
13
14
COS resolver feedback signal
COS resolver feedback signal
—
COS+
No connection
No connection
—
Table 26 MOTOR FEEDBACK Connector Pinout for Resolver Option
Resolver Excitation
Description
Min
Typical
Max
Units
Excitation Frequency
—
10
—
KHz
Note: All parameters are at the connector pin.
Table 27 Resolver excitation
Drive I/O Connector
The inputs and outputs (I/O) located on the 26-pin DRIVE I/O connector are
described below. For preparing your own cable, use differential pair wiring
with a minimum of three turns-per-inch (3 TPI).
Optical Isolation
The following describes which differential I/O signals are optically isolated:
•
Enable input is optically isolated with both Anodes (+) and Cathodes
(–) available.
•
Reset input is optically isolated with both Anodes (+) and Cathodes
(–) available.
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•
Fault output is optically isolated with both Collector (+) and Emitter
(–) available.
No Optical Isolation
The following describes which I/O signals are not optically isolated:
•
•
•
•
Step and Direction inputs are 5V differential compatible (RS-422
logic level compatible.
Encoder output signals are non-isolated RS-422 compatible
differential drivers referenced to DGND.
RS-485 is non-isolated RS-485 compatible differential signals
referenced to DGND.
AIN+ Analog input is single-ended non-isolated referenced to AIN–,
and common mode referenced to DGND.
Fault Operation
When the Aries Drive is enabled and there are no fault conditions, the Fault
circuit is closed (conducting). However, the following circumstances can trip
the Fault circuit: a fault condition is present (see “Error Messages” on page
from the drive.
You can use the LED status indicators to help identify internal drive faults.
For more information, see Table 23.
Drive Condition
Enabled
Fault Output
Closed (conducting)
Open
Faulted
No AC power on L1 and L2*,
or drive not enabled
Open
*
Mains Control power on C1 and C2 does not affect the fault circuitry. With mains power
applied to C1 and C2, the fault circuit remains open if AC power is not applied to the L1
and L2 terminals.
Table 28 Fault Output Operation
Figure 33 DRIVE I/O connector, female drive connector pinout
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Pinout—DRIVE I/O Connector
Note: A box surrounding pins indicates a requirement for twisted pair wiring.
Pin
Signal
Description
ENABLE+
ENABLE–
DGND
1
Drive Enable input anode
Drive Enable input cathode
Digital ground
21
2
ENC A+
ENC A–
ENC B+
ENC B–
ENC Z+
ENC Z–
FAULT+ *
FAULT–
STEP+
3
Encoder A Channel out
Encoder A Channel out
Encoder B Channel out
Encoder B Channel out
Encoder Z Channel out (Index +)
Encoder Z Channel out (Index – )
Fault Output collector
Fault Output emitter
4
5
6
7
8
9
16
10
5V Differential compatible (RS-422
logic level compatible) position
command
STEP–
11
12
Position command return
DIRECTION+
5V Differential compatible (RS-422
logic level compatible) direction
command
DIRECTION–
AIN+
13
14
15
17
18
23
19
20
22
24
25
26
Direction command return
Analog ±10V current command
±10V return
AIN–
DGND
Digital Ground
RESET+
RESET–
DGND
Drive Reset input anode
Drive Reset input cathode
Digital Ground
DGND
Digital Ground
DGND
Digital Ground
DGND
Digital Ground
RS-232Rx/ RS-485+
RS-232Tx/ RS-485–
RS-232Rx/ RS-485+ Half-Duplex
RS-232Tx/ RS-485– Half-Duplex
*
Opto is ON and conducting when no fault condition is present. When a fault occurs, the
opto turns OFF and the transistor does not conduct current. This simulates a normally
Table 29 DRIVE I/O Connector Pinout
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Inputs—Enable, Reset
The drive Enable and Reset inputs are optically isolated inputs. Current is
limited internally for input voltage control of 5 to 24 volt logic. The Anode (+)
and Cathode (−) are on separate connector pins to allow significant flexibility
in wiring to different styles of interface.
Description
Min
–
Max
1
Units
ms
Turn-on time
Turn-off time
–
1
ms
Guaranteed on voltage
Guaranteed off voltage
Maximum forward voltage
Maximum reverse voltage
4
–
VDC
VDC
VDC
VDC
mA
–
2
–
30
–
-30
3
Forward current
12
Note: All parameters are at the connector pin.
Table 30 Inputs—Enable and Reset Electrical/Timing Characteristics
Outputs—Encoder
Description
Min
Typical
Max
Units
Output Frequency
(pre-quadrature)
5
MHz
Input Voltage High *
Input Voltage Low *
2.4
V
V
0.5
*
Based on 120Ω differential load impedance.
Note: All parameters are at the connector pin.
Note: Aries encoder is a hardware pass-through; therefore, you cannot change output
resolution.
Table 31 Outputs—Encoder Outputs Electrical/Timing Characteristics
Outputs—Fault
Description
Min
Typical
Max
30
Units
V
Blocking Voltage
Continuous Load Current
10
mA
Output Saturation Voltage
(at 1.0 mA)
1.0
V
*
Based on 120Ω differential load impedance.
Note: All parameters are at the connector pin.
Table 32 Outputs— Fault outputs Electrical/Timing Characteristics
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Inputs—Step & Direction
Description
Min
-7
Typical
Max
+7
Units
V
Common Mode Range
Differential Threshold Voltage
-200
+200
mV
Differential Termination
Impedance
120
ohms
MHz
Input Frequency (pre-quadrature)
5
Note: All parameters are at the connector pin.
Table 33 Inputs—Step & Direction Electrical/Timing Characteristics
Inputs—Analog
Description
Min
Typical
Max
Units
Function Input Range
Resolution
-10
+10
V
14
bits
Impedance
>20
K ohms
Note: All parameters are at the connector pin.
Table 34 Inputs—Analog Electrical/Timing Characteristics
Connector Specification—Aries Drive
Manufacturer...........................................KYCON or equivalent
Connector Type.......................................26-Pin High Density
D-Subminiature
(female socket)
KYCON Part Number..............................K66-A26S-NR
Connector Specification—Mating Connector
Mating connectors are not provided with Aries drives. Parker cables are
available with mating connectors attached.
Manufacturer...........................................AMP or equivalent
Connector Type.......................................26-Pin High Density D-Subminiature
(male connector)
Cable Kit..................................................AMP Part Number 748474-1
Includes: 748365-1 connector,
shield, enclosure, and two jack
screws (does not include contacts or
ferrules)
Contacts..................................................Crimp style
30µ” Gold—AMP Part Number
748333-4
Gold Flash—Amp Part Number
748333-7
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Installation Test
Once you have made the necessary mechanical and electrical connections,
you can test the drive. The Aries Support Tool contains the Auto Run Test
Wizard, which exercises basic functions of the Aries drive.
You must do the following before testing the drive:
•
Configure the drive for the motor to which it is connected. Resolve
any configuration errors before proceeding with the test.
•
•
Enable the drive.
If the Aries drive is connected to a controller, disable the controller’s
servo loop.
•
If the motor is connected to a load, disconnect the motor so that it is
free to turn unimpeded.
Safety Warning — High-performance motion control equipment is capable
of producing rapid movement and very high forces. Unexpected motion may
occur especially during the development of controller programs. KEEP WELL
CLEAR of any machinery driven by stepper or servo motors. Never touch
any part of the equipment while it is in operation.
Testing the Aries Drive
If the Aries drive has been installed correctly, the motor will spin at one
revolution per second. If the motor does not spin, a wiring or configuration
error possibly exists.
1. Start the Aries Support Tool.
2. Under Menu, click Operating System Update.
3. Click Auto Run Test Wizard.
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Chapter 4 Communications
C H A P T E R F O U R
Communications
IN THIS CHAPTER
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RS-232/485 Communications
The Aries drive has a single serial port, located on the DRIVE I/O connector on
the front of the unit. This chapter refers to it as the COM port. The Aries drive
uses ASCII and the RS-232 or RS-485 communication protocols.
Terminal Emulator Configuration
RS-232
RS-485 *
Rx, Tx, Gnd
2-wire plus ground
(Talk+, Talk–, Gnd)
9600 baud
8 data bits
1 stop bit
No parity
9600 baud
8 data bits
1 stop bit
No parity
Full-duplex
Half-duplex
*
Twisted pair cabling recommended
(e.g. Belden 9842)
Table 35 Terminal Emulator Configuration for RS-232/485 Communication
Establishing Communications
The 26-pin DRIVE I/O connector (female D-subminiature) also functions as the
COM port. You can use it with RS-232 or two-wire RS-485 communications.
Figure 35 RS-232/485 Connections
For setup purposes, you can connect a personal computer (PC) directly to
the Aries drive through its COM port. Before attempting to communicate with
the Aries drive, verify your PC’s connector pinout—make sure the cable
connects the following:
•
•
•
The PC’s transmit terminal (pin 3 of the 9-pin connector) to the
Aries’s receive terminal (pin 25).
The PC’s receive terminal (pin 2 of the 9-pin connector) to the
Aries’s transmit terminal (pin 26).
The PC’s ground terminal to the Aries’s ground terminal (pin 24).
You can also use the Aries Drive I/O Dongle (sold separately), which allows
a PC to simultaneously communicate with the Aries drive while also
connected to a controller. For more information, see “RS-232/485 Dongle for
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Depending on the communications protocol you are using, Aries can
automatically configure itself.
•
If using RS-232, Aries will automatically detect and configure itself
for that communications protocol.
•
If using RS-485 (two-wire) and the standard bias configuration,
Aries will automatically detect and configure itself for that
communications protocol.
For automatic detection to work, the RS-485 network must be
configured with an up bias on + (Talk) and a down bias on – (Talk).
RS-232 Communications
The Aries drive supports RS-232 communication. However, you cannot
connect the drive in an RS-232 daisy chain.
Pinout for RS-232 Communication
Pin
25
26
24
Description
Rx (receive). Connect to Tx on your computer.
Tx (transmit). Connect to Rx on your computer.
DGND* (logic ground). Connect to DGND on your computer.
Maximum RS-232 cable length is 50 feet (15.25 meters).
Many PC COM ports connect RS-232 ground to chassis ground.
*
Table 36 RS-232 Connector Pinout
RS-485 Communications
The Aries is designed to use RS-485 half-duplex (two-wire). In addition, you
can use it in multi-drop networks. For more information about multi-drop, see
Pinout for 2-wire RS-485 Communication
Pin
25
26
24
Description
Connect to Tx/Rx+ on your computer.
Connect to Tx/Rx– on your computer.
DGND* (logic ground). Connect to DGND on your computer.
•
•
Maximum RS-485 cable length is 1000 feet (305 meters).
Keep wires as short as possible. Termination resistors may be required on long
cable runs.
•
Connect RS-485 cables before applying power to the drive.
(Reconnecting the cables with power applied may cause the drive to interpret
intermittent connections as RS-232 hardware handshake signals; this may result
in shutdown of the RS-485 interface. If this happens, reset the drive to re-enable
the RS-485 interface.)
•
Recommended cable: Belden 9842.
*
Many PC COM ports connect RS-485 ground to chassis ground.
Table 37 RS-485 Connector Pinout
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Figure 36 RS-485 Multi-drop Connections
RS-485 Multi-Drop
RS-485 multi-drop lets you connect up to 99 Aries drives together (see
Figure 36). Every drive is factory configured with a default address—zero (0).
Using the ADDRcommand, you can assign a unique address to each drive.
You must address each drive individually before connecting it to the multi-
drop network.
Notes
•
For RS-485 to work correctly turn off the echo mode (ECHOØ).
•
Zero (0) is not a valid address for a drive.
Setting up Drives for a Multi-Drop Network
1. Connect the drive you want to configure to a PC that is not part of the
multi-drop network.
2. Apply power to the drive.
3. Using terminal emulation software, send the following command—
Ø_ADDRi(where iis the address you want to assign the new unit).
4. Remove power to the drive. The drive can now be installed in the
network.
5. After installing and connecting the drives to the multi-drop network, test
each drive—use safe methods suitable for your particular application—
to ensure each functions correctly.
To test each unit, send the i_TREVcommand, where irepresents the
address of a drive.
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Warning — Risk of damage and/or personal injury When testing the
installation of drives, use safe methods suitable for your particular
application.
Replacing a Unit in the Network
If you need to replace a drive, do the following:
1. Remove the old unit from the network.
2. Connect the new drive to a PC that is not part of the multi-drop network.
3. Apply power to the drive.
4. Using terminal emulation software, send the following command—
Ø_ADDRi(where iis the address you want to assign the new unit).
5. If you can communicate with the old drive, upload its configuration using
the Aries Support Tool. Alternatively, you can create a new configuration
file using the Aries Support Tool. Then download the configuration file to
the new drive.
6. Remove power to the drive. The drive can now be installed in the multi-
drop network.
Sending Commands to a Specific Unit
You can send ASCII commands from the master unit (for example a personal
computer, PLC, or controller) to a specific unit in the multi-drop network.
Prefix the command with the unit address and an underscore (_). For
example, 3_ERES4ØØØsets the encoder resolution to 4000 for unit 3. The
master unit can receive data from any unit in the network.
RS-232/485 Dongle for Communications Setup
The Aries Dongle is a Y-cable (part number 71-021609-01) that breaks out
the RS-232/485 portion of the DRIVE I/O cable so that you may simultaneously
communicate with the Aries Drive while it is also connected with a motion
controller.
Note: When using the Aries Dongle, you must use a null-modem (cross-
over) cable between your PC and the Aries drive
Caution — The dongle is designed for setup and troubleshooting purposes
only. Do not use the dongle in a permanent installation; it does not meet
EMC requirements.
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Chapter 5 Tuning
CHAPTER FIVE
Tuning
IN THIS CHAPTER
Servo Tuning Overview .............................................................................79
Position Variable Overview........................................................................80
Servo System Gains..................................................................................83
Servo Tuning Example ..............................................................................86
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Servo Tuning Overview
The drive uses a digital control algorithm to control and maintain the position
and velocity. The digital control algorithm consists of a set of numerical
equations used to periodically (once every servo sampling period) calculate
the value of the control output.
The numerical terms of the equations consist of the current commanded and
actual position values (including a few from the previous sampling period),
and a set of control parameters. Each control parameter, commonly called a
gains to achieve optimal servo performance.
When using the control algorithm described above, the whole servo system
because the control algorithm accounts for both the command (position,
velocity, tension, etc.) and the feedback data from the encoder. Therefore, it
forms a closed loop of information. When all gains are set to zero, the digital
control algorithm is disabled.
Figure 37 Closed Loop and Open Loop System Comparison
To command a drive, controllers can provide ±10V analog output or step and
direction signals. Once the digital control algorithm has calculated the digital
control signal, the resultant digital value is sent out from the DSP (digital
signal processor) to the DAC (Digital-to-Analog Converter). The DAC has an
analog output range of -10V to +10V.
It is possible for the digital control signal, calculated by the control algorithm,
to exceed the DACs output range. If this occurs, the resulting analog output
becomes saturated—where the analog output signal remains at the limit until
the position error changes such that the control algorithm calculates a control
signal less than the limit.
The phenomenon of reaching the output limit is called controller output
saturation. When saturation occurs, increasing the gains does not help
improve performance because the DAC is already operating at its maximum
level.
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Position Variable Overview
In a servo system, the controller uses two types of position information:
commanded position and actual position. As these positions change with
time, you can use the position values to determine if the system is positioning
as you expect.
Commanded Position
The commanded position is calculated by the motion profile routine from the
controller and it is updated every servo sampling period. Therefore, the
commanded position is the intended position at any given point of time.
To view the commanded position, use the TPC(Transfer Commanded
Position) command; the response represents the commanded position at the
instant the command is received.
Figure 38 Commanded Position
Actual Position
The actual position of the motor/load is the drive’s response to the
commanded position, and is measured with the feedback device. The profile
resulting from the actual position across time is the position response (for
To view the actual position, use the TPE(Transfer Position of Encoder)
command; the response represents the actual position at the instant the
command is received.
The difference between commanded and actual positions is called position
error. To view the position error, use the TPER(Transfer Position Error)
command; the response represents the position error at the instant the
command is received.
If the motor is not moving, the position error is called a steady-state position
error. If a position error occurs when the motor is moving, it is called a
position tracking error.
Even when the system is properly tuned, the position error can still be quite
significant due to a combination of factors such as the desired profile, the
motor's limitation, the dynamic characteristics of the system, etc. For
example, if the commanded velocity is higher than the maximum velocity the
motor can physically achieve, the actual position will always lag behind the
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commanded position. Under these circumstances, a position error will
accumulate no matter how high the gains are set.
Servo Response Overview
Stability
The first objective of tuning is to stabilize the system. The formal definition of
system stability is when a bounded input is introduced to the system, the
output of the system is also bounded. What this means to a motion control
system is if the system is stable, and the position setpoint is a finite value,
the final actual position of the system is also a finite value.
In contrast, if the system is unstable, no matter how small the position
setpoint or how little a disturbance (motor torque variation, load change,
noise from the feedback device, etc.) the system receives, the position error
will increase exponentially in almost all cases. In practice, when the system
experiences instability, the actual position will oscillate in an exponentially
diverging fashion as shown in Table 38.
One common misperception is that whenever there is oscillation, the system
is unstable. It is important to recognize that a system is considered stable if
the oscillation finally diminishes (damps out), even if it takes a long time.
Position Response Types
Table 38 identifies the six basic types of position responses. The primary
difference among these responses is due to damping—the suppression (or
cancellation) of oscillation.
Response
Description
Profile (position/time)
Unstable
Instability causes the
position to oscillate in
an exponentially
diverging fashion.
Over-
damped
A highly damped, or
over-damped, system
gives a smooth but
slower response.
Under-
damped
A slightly damped, or
under-damped,
system gives a slightly
oscillatory response.
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Response
Description
Profile (position/time)
Critically
damped
A critically-damped
response is the most
desirable because it
optimizes the trade-off
between damping and
speed of response.
Oscillatory
Chattering
An oscillatory
response is
characterized by a
sustained position
oscillation of equal
amplitude.
Chattering is a high-
frequency, low-
amplitude oscillation
that is usually audible.
Table 38 Position Response Types
Performance Measurements
If you plot of the position response versus time, you can make a few
measurements to quantitatively assess the performance of the servo. These
three measurements are made before or shortly after the motor stops
moving:
•
Overshoot—The measurement of the maximum magnitude that the
actual position exceeds the position setpoint. It is usually measured
in terms of the percentage of the setpoint value.
•
•
Rise Time—The time it takes the actual position to pass the
setpoint.
Settling Time—The time between when the commanded position
reaches the setpoint and the actual position settles within a certain
percentage of the position setpoint. (Note the settling time definition
here is different from that of a control engineering text book, but the
goal of the performance measurement is still intact.).
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Servo System Gains
Proportional Feedback Control (SGP)
Proportional feedback is the most important feedback for stabilizing a servo
system. When the controller uses proportional feedback, the control signal is
linearly proportional to the position error (the difference between the
commanded position and the actual position—see TPERcommand). The
proportional gain is set by the Servo Gain Proportional (SGP) command.
Proportional feedback can be used to make the servo system more
responsive (stiff), as well as reduce the steady state position error.
Because the control is proportional to the position error, whenever there is
any disturbance (such as torque ripple or a spring load) forcing the load away
from its commanded position, the proportional control can immediately output
a signal to move it back toward the commanded position. This function is
called disturbance rejection.
If you tune your system using only the proportional feedback, increasing the
proportional feedback gain (SGPvalue) too much will cause the system
response to be oscillatory, under-damped, or in some cases unstable.
Note: Do not set the proportional feedback gain (SGP) to zero, except when
open-loop operation is desired.
Velocity Feedback Control (SGV)
Using velocity feedback control, the control signal is proportional to the
feedback device's velocity (rate of change of the actual position). The Servo
Gain Velocity (SGV) command sets the gain, which is in turn multiplied by the
feedback device's velocity to produce the control signal. Because the velocity
feedback acts upon the feedback device's velocity, its control action
essentially anticipates the position error and corrects it before it becomes too
large. Such control tends to increase damping and improve the stability of the
system.
A high velocity feedback gain (SGV) can also increase the position tracking
error when traveling at constant velocity. In addition, setting the velocity
feedback gain too high tends to slow down (over-damp) the response to a
commanded position change.
Integral Feedback Control (SGI)
Using integral feedback control, the value of the control signal is integrated at
a rate proportional to the feedback device position error. The rate of
integration is set by the Servo Gain Integral (SGI) command.
The primary function of the integral control is to overcome friction and/or
gravity and to reject disturbances so that steady state position error is
minimized or eliminated. This control action is important for achieving high
system accuracy. However, if you can achieve acceptable position accuracy
by using only the proportional feedback (SGP), then there is no need to use
the integral feedback control.
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Controlling Integral Windup
If you are using integral control (SGI) and there is an appreciable position
error that persists long enough during the transient period (time taken to
reach the setpoint), the control signal generated by the integral action can
end up too high; this saturates to the maximum level of the controller's
analog control signal output. This phenomenon is called integrator windup
Figure 39 Integrator Windup (Without Using SGILIM Command)
After windup occurs, it takes time before the integrator output returns to a
level within the limit of the controller's output. Such a delay causes excessive
position overshoot and oscillation.
The integral windup limit (SGILIM) command allows you to set the absolute
limit of the integral. The commanded limit, in essence, turns off the integral
action as soon as it reaches the limit; consequently, position overshoot and
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Servo Tuning Example
The example below illustrates how to experimentally obtain the highest
a Servo Tuning flow diagram, see “Appendix A Additional Specifications” on
The motion command used for this example is a step command with a step
size of 200. The plots shown are as they appear in the Aries Support Tool
(X axis = time, Y axis = position).
Note: The steps shown below (steps 1 to 11) represent the major steps of
the process; the actual progression between these steps may require several
iterations.
Step 1
For a starting trial, we set
the proportional feedback
can see by the plot, the
response is slow.
In the next step, we should
response is slightly under
damped.
Step 2
response becomes slightly
under damped (see plot).
Therefore, we should
introduce the velocity
damp out the oscillation.
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Step 3
Step 3
response is fairly well
damped (see plot).
At this point, the SGP
should be raised again
until oscillation or
excessive overshoot
appears.
Step 4
As we iteratively increase
chattering becomes
significant (see plot). This
high.
Next, we should try raising
dampen out the overshoot
and chattering.
Step 5
raised to 5, the overshoot
was reduced but
chattering is still quite
pronounced. This means
either one or both of the
gains is too high.
The next step should be to
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Step 6
does not help reduce the
chattering by much.
Therefore, we should
chattering stops.
Step 7
Chattering stops after
However, the overshoot is
still a little too high.
The next step should be to
damp out the overshoot.
Step 8
to 4, overshoot is reduced
a little, but chattering
reappears. This means the
gains are still too high.
Next, we should lower the
stops.
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Step 9
After lowering the SGV
gain to 3 (even less than in
Step 7—3.5), chattering
stops.
Next we should lower the
Step 10
Overshoot is reduced very
little after lowering the SGP
might have been lowered
too much in Step 9.)
Next, we should try raising
the overshoot is gone.
Step 11
When we raised the SGV
gain to 3.5, the step
response became fast and
very stable.
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Auto-Tuning
The Aries drive can automatically determine the inertia of the load attached
to the motor. This is performed by applying a specified torque to the motor
and measuring the acceleration and deceleration of the motor. From this, the
Aries drive can calculate the load inertia and store the value in the LJRAT
command.
Note: Excess friction can affect the measured inertia, thereby estimating the
value higher than the actual inertia. While the drive can compensate for
some friction, it may not compensate for all. If the estimated load inertia
seems overly high, this may be the cause.
Note: Use this method of auto-tuning only with the step and direction
versions of the Aries drive.
The Auto-Tune process should only last a few seconds, during which time
the motor will rotate about one-quarter of a turn in each direction. Following
are the two methods to start Auto-Tune mode.
►
In the Aries Support Tool, select the Servo Tuner tab. Then click
Auto-Tune.
—or—
►
Put the drive in position mode (DMODE6or 7). On the drive’s ±10V
Analog Input, apply a command voltage greater than 3V, then reset the
drive.
To return to normal operation, remove the command voltage and reset
the drive.
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Chapter 6 Command Reference
CHAPTER SIX
Command
Reference
IN THIS CHAPTER
Description of Format ................................................................................92
Command Descriptions .............................................................................95
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Aries Communications Set-up
Before you can communicate with the Aries drive, you must configure your
terminal emulator. You can use HyperTerminal or an equivalent terminal
emulator. For information about setting up communications, see “RS-232/485
Description of Format
1.
2.
3.
ERES
Type
Encoder Resolution
Encoder Configuration
<a_>ERES<i>
4.
5.
6.
Product Rev
Aries 1.0
Syntax
Units
Rotary motor: i = counts/revolution
Linear motor: i = counts/electrical pitch
2ØØ to 1Ø73741823
4ØØØ
7.
8.
9.
Range
Default
ERES:
<*>4ØØØ
Response
10. See Also
Number Description
1.
2.
3.
Mnemonic Code: This field contains the command's mnemonic code.
Full Name: This field contains the command's full name.
Valid Product & Revision: This field lists the Aries Series products and the revision of
each product when this command was incorporated or modified per the description. If
the command does not apply to that particular product, the Revision is specified as
“N/A”. All commands applicable to the standard product versions are applicable to the
OEM versions unless otherwise noted (e.g., 6250 commands are applicable to the
OEM6250 controller).
You can use the TREVcommand to determine which product revision you are using.
For example, if the TREVresponse is Aries Revision 1.0, The product revision is 1.0
4.
5.
Type: This field contains the command’s type.
Syntax: The proper syntax for the command is shown here. The specific parameters
associated with the command are also shown. Definitions of the parameters are
described in the Syntax sections below.
6.
7.
8.
9.
Units: This field describes what unit of measurement the parameter (b, d, i, r, or t) in
the command syntax represents.
Range: The range of valid values that you can specify for an argument (or any other
parameter specified).
Default: The default setting for the command is shown in this field. A command will
perform its function with the default setting if you do not provide a value.
Response: Some commands allow you to check the status of the command. In the
example above, entering the EREScommand by itself, you will receive the response
<*>4ØØØ. The <*> only appears for RS-485 communication, and does not appear for
RS-232 communication.
10.
See Also: Commands related or similar to the command described are listed here.
Table 39 Commands-Description of Format
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Syntax – Letters and Symbols
The command descriptions provided within this manual use alphabetic letters
and ASCII symbols within the Syntax description (see example below) to
represent different parameter requirements.
ERES
Type
Encoder Resolution
Encoder Configuration
Product Rev
Aries 1.0
<a_>ERES<i>
Syntax
Units
→
Rotary motor: i = counts/revolution
Linear motor: i = counts/electrical pitch
2ØØ to 1Ø73741823
4ØØØ
Range
Default
ERES:
<*>4ØØØ
Response
Symbol Description
a_
Represents an address specifier, numeric value from Ø to 99. An address
specifier is required if multiple Aries drives are connected in a daisy-chain or
multi-drop configuration; in fact, leaving off the address specifier will cause
parameter assignment commands to affect all units and response/transfer
commands to request information from all units at the same time (multiple
units transmitting characters at one time will garble the communication). To
assign unique unit addresses to multiple drives, refer to the ADDRcommand.
b
Represents the values 1or Ø; does not require field separator between
values. *
c
d
Represents a character (Ato Z, or ato z)
Represents the values 1or Ø, Eor e; does not require field separator between
values. Eor eenables a specific command field.
i
r
Represents a numeric value that cannot contain a decimal point (integer
values only). The numeric range varies by command. Field separator
required.
Represents a numeric value that may contain a decimal point, but is not
required to have a decimal point. The numeric range varies by command.
Field separator required.
t
,
Represents a string of alphanumeric characters from 1 to 16 characters in
length. The string must start with an alpha character.
(Comma) Represents a field separator. Commands with the symbol ror iin
their Syntax description require field separators.
Commands with the symbol b or d in their Syntax description do not require
field separators (but they may be included). See Table 41.
< >
Indicates that the item contained within the < >is optional, and not required
by that command.
Note: Do not confuse with <cr>, <sp>, and <lf>, which refer to the ASCII
characters corresponding to a carriage return, space, and line feed,
respectively.
*
The ASCII character bcan also be used within a command to precede a binary number.
When the bis used in this context, it is not to be replaced with a Øor 1. For example,
comparisons such as ERROR= b1x1.
Table 40 Commands-Syntax
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Syntax – General Guidelines
Guideline Topic Guideline
Examples
Command Delimiters All commands must be separated
by a delimiter. A carriage return is
the most commonly used.
(<cr>and <lf>)
Neutral Characters
Using neutral characters
Set velocity limit to 100 rps:
anywhere within a command will
not affect the command.
(<sp>)
DMVLIM<sp>1ØØ<cr>
Case Sensitivity
There is no case sensitivity. Use Initiate motion:
upper or lower case letters within
commands.
GO1
go1
Comment Delimiter
[semi-colon ( ; ) or
apostrophe ( ‘ )]
All text between a comment
delimiter and a command delimiter
is considered program comments.
Add a comment to the command:
DMVLIM<sp>
velocity
; set
; limit
Binary and
When making assignments with or Binary:
Hexadecimal Values comparisons against binary or
hexadecimal values, you must
ERRORL = bØ1111x11111111111
precede the binary value with the
letter “b” or “B”, and the hex value
with “h” or “H”. In the binary
Hexadecimal:
ERRORL = h7FxF
syntax, an “x” simply means the
status of that bit is ignored.
Note: The command line is limited to 32 characters (including spaces).
Table 41 Syntax Guidelines
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Command Descriptions
You can use the ASCII commands, provided in this chapter, to configure,
check errors, and reset the Aries drive through a terminal emulator. A
terminal emulator, however, is not required, Instead, you can use the Aries
Supp0ort Tool software to perform the same operations.
Note: The Aries Support Tool does not support the CMDDIRand ADDR
commands. You must use a terminal emulator to set the commanded
direction and address of each drive.
Before you can communicate with the Aries Drive, you must configure your
terminal emulator. You can use HyperTerminal or an equivalent terminal
emulator, For more information about setting up communications, see “RS-
ADDR
Type
Multiple Unit Address
Drive Configuration
<a_>ADDR<i>
i = unit number
Ø to 255
Product
Aries
Rev
1.0
Syntax
Units
Range
Ø
Default
Response
See Also
ADDR:
none
<*>Ø
The ADDRcommand configures the unit address for an RS-485 multi-drop
network. The factory default address for an Aries drive is zero (0). The ADDR
command allows you to uniquely address up to 255 units (99 unit maximum
on a single network).
After establishing a unique address for each Aries drive, you can address
commands to specific units. To do this, prefix the command with the unit’s
address followed by an underscore ( _ ). For example, 2_ERES reports the
resolution on unit 2.
RS-485 Multi-Drop
You must address each unit before adding it to the multi-drop network.
For example, you want to set up a 4-unit multi-drop network, where the
drives are addressed as units 1 through 4. After addressing a drive, you
can install it in the multi-drop network.
1. Connect the drive to become unit 1. Through a terminal emulator,
send the following command: Ø_ADDR1
2. Connect the drive to become unit 2. Through a terminal emulator,
send the following command: Ø_ADDR2
3. Connect the drive to become unit 3. Through a terminal emulator,
send the following command: Ø_ADDR3
4. Connect the drive to become unit 4. Through a terminal emulator,
send the following command: Ø_ADDR4
If you need to replace a unit in the multi-drop network, connect to the
individual device and send the Ø_ADDRicommand, where “i”
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represents the address of the new unit. Then connect the drive to the
network.
Note: All command responses on an RS-485 network are preceded by <*>.
ALIGN
Type
Align encoder
Drive configuration
Product
Rev
<a_>ALIGN
Syntax
Units
Aries
1.0
N/A
N/A
0
Range
Default
Response
See Also
none
The ALIGNcommand aligns the encoder on the motor so that the drive can
commutate the motor correctly. This command is especially useful for
configuring a custom motor. To align the motor, use the following procedure:
1. Remove any load from the shaft. The procedure works best with an
unloaded motor.
2. Disable the drive by means of the hardware enable or by typing DRIVE0
into the terminal and pressing Enter.
3. Type DMODE3in the terminal and press Enter to enter alignment mode.
4. Enable the drive by means of either the hardware enable or by typing
DRIVE1into the terminal and press Enter.
5. Type ALIGNinto the terminal and press Enter to begin the alignment
process.
6. The drive then begins the alignment procedure. This could take up to 20
seconds.
Note: The motor turns up to 90 degrees during this procedure.
7. The alignment process may modify the following parameters:
ENCOFF, ENCPOL, SHALL, CMDDIR, P163
These parameters are stored in the drive. If you want to store them in a
smart encoder, type the ESTOREcommand into the terminal and press
Enter. It takes a couple of seconds to store the motor data in the motor.
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ANICDB
Type
Analog Input Center Deadband
Drive Configuration
<a_>ANICDB<r>
r = volts
Product
Rev
Syntax
Aries
2.0
Units
Ø.ØØ to 1Ø.ØØ
Ø.Ø4
Range
Default
Response
See Also
ANICDB: *ANICDBØ.Ø4
The ANICDBallows the user to specify the voltage deadband for the
command input. ANICDBis used with DCMDZto configure the command input
for DMODE2 and DMODE4. The commanded torque, Trqcommand, is calculated
from the input voltage, Vin, using DMTSCLas follows:
DMTSCL
DCMDZ ANICDB
−
−
V
= (
)
Trqcommand
in
10
Vin >
DCMDZ+ ANICDB
)
when
Trqcommand = 0
DCMDZ-ANICDB
)
≤ Vin ≤
DCMDZ+ ANICDB
)
when
DMTSCL
DCMDZ ANICDB
−
+
V
= (
)
Trqcommand
in
10
Vin <
DCMDZ-ANICDB
)
when
The commanded velocity, Velcommand, is calculated from the input voltage, Vin,
using DMVSCLas follows:
DMVSCL
DCMDZ ANICDB
−
−
V
= (
)
Velcommand
in
10
when Vin >
DCMDZ+ ANICDB
)
Velcommand = 0
when
DCMDZ-ANICDB
)
≤ Vin ≤
DCMDZ+ ANICDB
)
DMVSCL
DCMDZ ANICDB
−
+
V
= (
)
Velcommand
in
10
when Vin <
DCMDZ-ANICDB
)
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CERRLG
Type
Clear the Error Log
Error Handling
Product
Rev
<a_>CERRLG
N/A
Syntax
Aries
1.0
Units
N/A
Range
N/A
Default
N/A
Response
See Also
The CERRLGcommand erases the stored contents of the error log. Clearing
the error log is a helpful diagnostic tool; it allows you to start the diagnostic
process when the error log is in a known state so that you can check the
error log in response to subsequent events.
The error log is updated every time an error occurs. The TERRLGcommand
displays the last ten error conditions that the drive has experienced, as
recorded in these status registers:
• TANI (current command input voltage)
• CONFIG(text-based status report of configuration errors)
• ERROR(list of error messages)
• TDHRS(number of hours since the drive was powered up or RESET)
• TDTEMP(measured temperature of the drive in centigrade)
• TMTEMP(estimated temperature of the motor in centigrade)
• TVBUS(measured bus voltage in volts)
CMDDIR
Type
Direction of Rotation
Drive Configuration
Product
Rev
<a_>CMDDIR<b>
Syntax
Units
Aries
1.0
b = enable bit
Ø (CW rotation for positive analog input) or
1 (CCW rotation for positive analog input)
Range
Ø
Default
CMDDIR
<*>Ø
Response
See Also
The CMDDIRcommand determines the direction of shaft rotation (or direction
of travel for linear motors) for positive analog input. The default is clockwise
shaft rotation for a positive command.
Sending a CMDDIR1 command changes the direction to counter clockwise.
In addition, the encoder counts positive for counter clockwise rotation with
CMDDIR1.
Note: This command does not take effect until you cycle power to the drive,
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Rotary Motors—Positive values represent
clockwise motion and negative values represent
counter-clockwise motion (assuming CMDDIR = Ø,
and that you connected the feedback device
according to instructions provided in “Chapter 2
Installation”).
Figure 41 Clockwise/
Counter-clockwise rotation
CONFIG
Type
Configuration Errors and Warnings
Error Handling
Product
Rev
<a_>CONFIG
N/A
Syntax
Aries
1.0
Units
N/A
Range
N/A
Default
Response
See Also
CONFIG
<*>No Errors
The CONFIG command gives a text-based status report of current
configuration errors and warnings (EØthrough E24).
Error
Resolution
EØ—Motor Configuration
Warning
The motor rating is too high for the drive, and the
drive is using its own limits for safety reasons.
E1—Motor Configuration Error
One of the motor parameters is set to zero (0).
Look at the additional errors to find which
parameters are set at zero (0). Refer to your
motor specifications for the correct value.
E3—Max Inductance = Ø
E4—Rated Speed = Ø
E5—DPOLE = Ø
This parameter is set to zero (0). To correct the
error, you must set a non-zero (0) value. Refer to
your motor specifications for the correct value.
(DMTIND)
This parameter is set to zero (0). To correct the
error, you must set a non-zero value. Refer to
your motor specifications for the correct value.
(DMTW)
(DPOLE)
E6—Resistance = Ø
E7—Ke = Ø
This parameter is set to zero (0). To correct the
error, you must set a non-zero value. Refer to
your motor specifications for the correct value.
(DMTRES)
(DMKE)
E8—Continuous Current = Ø
(DMTIC)
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Error
Resolution
E9—Peak Current = Ø
(DMTIP)
E1Ø—Use Drive Continuous
Current Warning
The continuous current of the motor is higher than
the continuous current rating of the drive. Use the
continuous current rating for the drive.
E11—Torque Rating > Peak
Power Rating Warning
The motor’s torque rating is too high for the power
level of the drive. Use the drive’s torque rating.
E12— Use Drive Peak Current
Warning
The peak current of the motor is higher than the
peak current rating of the drive. Use the drive’s
value for peak current.
E13 - Inertia = Ø
E14 – Damping = Ø
This parameter is set to zero (0). The drive will not
enable Velocity or Position Modes. To correct the
error, you must set to a non-zero value. Refer to
your motor specifications for the correct value.
(DMTJ)
This parameter is set to zero (0). The drive will not
enable Velocity or Position Modes. To correct the
error, you must set to a non-zero value. Refer to
your motor specifications for the correct value.
(DMTD)
E15 – Notch filter Calc
Error.
The notch filter settings caused an internal
calculation error. The last valid value was used.
Try different values for the notch filter parameters.
(DNOTAF, DNOTAQ, DNOTBF, DNOTBQ)
E16 – Lead < Lag Freq
E17 – Lead ≥ 4* Lag Freq
E18 – Lag Freq < 2Ø Hz
The lead filter setting (DNOTLD) must be greater
than or equal to the lag filter setting. (DNOTLG)
The lead filter setting (DNOTLD) must be less than
or equal to 4 times the lag filter setting. (DNOTLG)
The lag filter setting (DNOTLG) must be greater
than or equal to 20 Hz.
E19–E24
RESERVED
Table 42 Configuration Errors and Warnings
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DCMDZ
Type
Zero the Drive Command Offset
Drive Configuration
<a_>DCMDZ=<r>
r = volts
Product
Rev
Syntax
Aries
1.0
Units
-1Ø.ØØ to 1Ø.ØØ
Ø.ØØ
Range
Default
Response
See Also
N/A
The DCMDZcommand sets the zero point for the command input. When in
torque/force mode (DMODE2), this will minimize motor drift.
Executing the DCMDZcommand without an argument sets the zero reference
point to the last voltage read at the command input. To execute this
command correctly, short the AIN + and AIN – pins together on the DRIVE I/O
connector, or command zero volts from the servo controller.
You can also use DCMDZto set the zero point to an arbitrary voltage by
entering that value. For example, DCMDZ = Ø.5makes 0.5 volts equal to a
commanded velocity of zero (0) rps. Note that this value is the internal level
and does not take into account any offsets in the incoming command signal.
DIBW
Type
Current Loop Bandwidth
Tuning
<a_>DIBW<i>
Hz
Product
Rev
Syntax
Units
Aries
3.0
250-3000
1200
Range
Default
Response
See Also
DIBW:
<*>1200
When used in conjunction with IAUTO1, this command sets the current loop
bandwidth. Higher values of DIBWwill give a faster response to changes in
commanded current, at the expense of some overshoot. Lower values of
DIBW, will give a slower response, with much less overshoot.
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DIFOLD
Type
Current Foldback Enable
Drive Configuration
<a_>DIFOLD<b>
b = enable bit
Ø (disable) or 1 (enable)
1
Product
Rev
Syntax
Aries
1.0
Units
Range
Default
Response
See Also
DIFOLD: <*>Ø
none
The DIFOLDcommand enables (1) or disables (Ø) the drive’s current
foldback protection feature. The current foldback feature reduces the drive’s
continuous current output by 20% when sustained current has the potential
to overheat the drive. For the AR-20xE and AR-30xE drives, this feature is
always enabled.
ratings are for the drive, not for the motor.
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
1.0
Arms
1.75
Arms
3.0
Arms
4.5
Arms
6.3
Arms
10
Arms
16
Arms
Drive Continuous Current
Rating (100%)
3.0
Arms
5.25
Arms
9.0
Arms
13.5
Arms
14.07
Arms
30
Arms
48
Arms
Max Current Rating
3.375
sec
3.375
sec
3.375
sec
3.375
sec
8.64
sec
3.375
sec
3.375
sec
Max Time at Peak Current
Rating
Table 43 Current Foldback Ratings
the number of seconds until foldback occurs. For example, the graph shows
that at the drive’s peak current rating (300% of continuous), foldback occurs
after 3.375 seconds.
Note: For model AR-13xx, foldback occurs after 8.64 seconds at its peak
rating (225% of continuous).
Figure 42 Time until current foldback occurs
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DMEPIT
Type
Motor Electrical Pitch
Motor (Linear only)
<a_>DMEPIT<r>
Product
Rev
Syntax
Aries
1.0
r = millimeters
Ø to 3ØØ.ØØ : ±Ø.Ø1
Ø
Units
Range
Default
Response
See Also
DMEPIT: <*>4Ø.ØØ
Note: This command does not take effect until you cycle power to the drive,
The DMEPITcommand sets the electrical pitch of the magnets for use with
permanent magnet brushless linear motors. The DMEPITvalue is required to
convert between linear units and rotary units. The electrical pitch can be
equated to one revolution in a rotary motor. Mechanically, the definition of the
electrical pitch is the linear distance between two magnets comprising a full
magnetic cycle. For example, the illustration below shows an electrical pitch
of 42 mm (DMEPIT42).
Figure 43 Linear motor track
Important! For rotary motors, set the DMEPITto zero (0). The Aries drive
uses the DMEPITparameter as the determinant for which type of motor,
linear or rotary, is connected.
DMODE
Type
Drive Control Mode
Drive Configuration
Product
Rev
<a_>DMODE<i>
Syntax
Aries
1.0
i = control mode setting
2
Units
Range
Default
Response
See Also
DMODE: <*>2
none
Use the DMODEcommand to select the drive control mode for your Aries
drive. For drive mode descriptions and drive compatibility, see Table 44.
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DMODE
Mode
Description
1
Autorun
Rotates the motor at 1 rps/mps. Current is
reduced by 10%.
2
Torque/Force
Control
Allows direct control of rotary motor
torque, or linear motor force.
3
4
Feedback Alignment Auto-configure for feedback setup.
Velocity Control
Allows direct control of rotary or linear
motor velocity.
6
7
Position Control
Uses 5V Differential compatible (RS-422
logic level compatible) step and direction
control.
Reversed Position Reverses the polarity of the step and
Control direction signal.
Table 44 Drive Control Mode
Note: dmodes 6 and 7 are available only on the step and direction versions
of the Aries drive.
DMPSCL
Type
Incoming Pulse Scaling
Drive Configuration
<a_>DMPSCL<i>
i = multiplier setting
0 to 127
Product
Rev
Syntax
Aries
2.0
Units
Range
1
Default
DMPSCL: <*>1
Response
See Also
Use the DMPSCL command to scale the incoming pulses for the step and
direction input. A setting of 10 would move the motor 10 encoder pulses for
DREScommand: Added DREScommand for step and direction inputs. Input
steps will be scaled to DRESvalue so DRESsteps on the input would
translate to 1 revolution of the motor.
DRESis set to ERESinternally if DMPSCLis non-zero for backward
compatibility. DMPSCL should be set to 0 to enable DRESsupport.
NB: DRESchange requires a reset to take effect. DMPSCLworks immediately
so the user could use DMPSCL0to enable DRESsupport then enable DMPSCL
and have both features working at once.
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DMTAMB
Type
Motor Ambient Temperature
Motor
Product
Rev
<a_>DMTAMB<r>
Syntax
Aries
1.0
r = Degrees Celsius
-5Ø.ØØ to 25Ø.ØØ : ±Ø.Ø1
4Ø.Ø
Units
Range
Default
DMTAMB: <*>4Ø.Ø
Response
See Also
The DMTAMBcommand sets the motor ambient temperature used by the
software motor thermal model. The DMTAMBvalue, in conjunction with the
motor thermal time constant (DMTTCM), the motor winding time constant
(DMTTCW), the motor thermal resistance (DMTRWC) and the continuous motor
current (DMTIC), is used in a real-time estimation of the motor winding
temperature. When the winding temperature exceeds DMTMAX, the drive
faults and reports E35–Motor Thermal Fault.
DMTD
Type
Motor Damping
Motor
Product
Rev
<a_><!>DMTD<r> (does not take effect until RESET or
cycle power)
Syntax
Aries
2.0
Rotary motor: r = uNm/rad/sec
Linear motor: r = N/meter/sec
Units
Rotary motor: Ø.ØØØØØØ to 1ØØØØ : ±1
Range
Linear motor: DMEPIT (electrical pitch) dependent
Ø.ØØØØØØ
Default
DMTD:
*DMTD2ØØ
Response
See Also
Note: This command does not take effect until you cycle power to the drive,
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTDcommand specifies the damping of the motor itself. This includes
both magnetic losses and bearing losses.
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DMTIC
Type
Continuous Current
Motor
Product
Rev
<a_>DMTIC<r>
Syntax
Units
Aries
1.0
r = Amps-RMS
Ø.ØØ to 2ØØ.ØØ : ±Ø.Ø1
Range
Default
Ø.ØØ (DMTIC of Ø results in motor configuration
warning)
DMTIC: <*>6.5Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors EØ–Motor Configuration Error and
E8–Continuous Current = Ø.
The DMTICcommand sets the continuous operating current for a motor.
Rotary motors: The internal winding temperature will reach 125°C with a
specified heatsink in a 40°C ambient—for Parker motors only.
Linear motors: The winding will reach 90°C in a 25°C ambient—for Parker
motors only.
Example
DMTIC5
; Set the motor current to 5 amps rms (equates to
; 7.Ø7 amps peak)
DMTICD
Type
Continuous Current Derating
Motor
Product
Rev
<a_>DMTICD<i>
Syntax
Aries
1.0
I = Percent derating at rated speed
Ø.ØØ to 1ØØ.ØØ : ±Ø.Ø1
Ø.ØØ (DMTICD of Ø results in no current derating)
DMTICD: <*>5
Units
Range
Default
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
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The DMTICDcommand sets the current derating percentage at rated speed
(DMTW). This value sets the extent to which continuous current must be
reduced at speed to compensate for velocity-related losses in the motor.
For example, DMTICD3sets the motor’s continuous current derating to 3%
(or 97% of continuous value DMTIC) at the motor’s rated speed (DMTW). At
half this speed, it will be reduced 1.5%.
DMTIND
Type
Motor Inductance
Motor
Product
Rev
<a_>DMTIND<r>
r = mH
Syntax
Units
Aries
1.0
Ø.Ø to 2ØØ.Ø : ±Ø.1
Range
Ø.Ø (DMTIND of Ø results in motor configuration
error)
Default
DMTIND
<*>1Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Error and
E3–Maximum Inductance = Ø, and shuts down the drive.
The DMTINDcommand specifies the maximum value of motor inductance.
This usually differs from the nominal nameplate value because actual
inductance is usually position dependent. If the maximum value of motor
inductance is not known, specify the nominal inductance as listed on the
motor’s nameplate.
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DMTINF
Type
Motor Inductance Factor
Motor
Product
Rev
<a_>DMTINF<r>
r = units
Ø.ØØ to 1.ØØ
1
Syntax
Aries
1.0
Units
Range
Default
Response
See Also
DMTINF
<*>1.ØØ
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Errorand
E3–Maximum Inductance = Ø, and shuts down the drive.
The DMTINF command specifies the minimum motor inductance divided by
the maximum motor inductance. Setting DMTINFto 1.ØØdoes not derate the
motor.
If the minimum value of the motor inductance is not known, use the nominal
inductance as listed on the motor’s nameplate (or set DMTINF1.ØØ)
DMTIP
Type
Peak Current
Motor
Product
Rev
<a_>DMTIP<r>
r = Amps-RMS
Ø.ØØ to 4ØØ.ØØ : ±Ø.Ø1
Syntax
Units
Aries
1.0
Range
Default
Ø.ØØ (DMTIP of Ø results in motor configuration
warning)
DMTIP: <*>7.5Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Error and
E9–Peak Current = Ø.
The DMTIPcommand sets a limit that the commanded current cannot
exceed. This is typically set to three times the motor’s continuous current
rating (DMTIC) or less.
If DMTIPis set higher than the full-scale value calculated by DMTLIM
(torque/force limit) the new DMTIPvalue will be ignored.
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If the DMTIPvalue exceeds the drive’s maximum output current (TDIMAX),
the DMTIPvalue will be ignored and the maximum allowable value will be
Warning and E12–Peak Current Too High.
Maximum Current Rating (RMS)
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
3A
5.25A
9A
13.5A
14.1
30
48
Table 45 Peak Current Rating for Aries Drives
DMTJ
Type
Motor Rotor Inertia / Forcer Mass
Motor
Product
Rev
<a_><!>DMTJ<r> (does not take effect until RESET or
cycle power)
Syntax
Aries
2.0
Rotary motor: r = kgm2 * 1Ø-6
Linear motor: r = kg
Units
Range
Rotary motor: Ø.ØØØ to 1ØØØØØØ.ØØØ : ±Ø.ØØ1
Linear motor: DMEPIT (electrical pitch) dependent
Ø.ØØØ (DMTJ of Ø results in motor config. error)
Default
DMTJ:
*DMTJ2ØØ.6ØØ
Response
See Also
Note: This command does not take effect until you cycle power to the drive,
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
If the drive is powered up when this command is set to zero (for instance, if
RFSis executed), the drive reports a motor configuration error with E13, and
shuts down the drive (DRIVEØ).
The DMTJcommand sets the motor rotor inertia for rotary motors, or the
forcer mass for linear motors.
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DMTKE
Type
Motor Ke
Motor
Product
Rev
<a_>DMTKE<r>
Rotary motor: r = volts
Syntax
Units
Aries
1.0
(Ø-peak)/krpm (measured line-to-line)
Linear motor: r = volts
(Ø-peak)/meter/second (measured line-to-line)
Rotary motor: Ø.Ø to 8ØØ.Ø : ±Ø.1
Range
Linear motor: DMEPIT (electrical pitch) dependent
Ø.Ø (DMTKE of Ø results in motor configuration error)
DMTKE: <*>15.Ø
Default
Response
See Also
Note: This command does not take effect until you cycle power to the drive,
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Errorand
E7–Bad Hall State, and shuts down the drive.
The DMTKEcommand specifies the motor voltage constant (Ke). This
defaults to the nominal Ke of the motor selected with the DMTRcommand.
The motor’s torque/force constant (Kt) is derived from the motor’s voltage
constant (Ke) by the following relationship:
3 3
Kt(Nm / A† ) =
Ke(Volts‡ / krpm)
200π
† RMS, 0 - peak value
‡
Rotary motors:
Linear motors:
3 3
Kt(N / A† ) =
Ke(Volts‡ /(meter /sec))
200π
† RMS, 0 - peak value
‡
Note: The Aries requires values in rotary units. The Aries Support Tool
automatically performs these conversions when you use the Configuration
Wizard. If you do not use the Configuration Wizard, you must convert your
linear units to rotary units. For more information about conversion, see the
DMEPITcommand.
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DMTLIM
Type
Torque/Force Limit
System
Product
Rev
<a_>DMTLIM<r>
Syntax
Units
Aries
1.0
Rotary motor: r = Nm
Linear motor: r = N
Rotary motor: Ø.Ø to 5ØØ.Ø (motor/drive dependent):
±Ø.1
Range
Linear motor: DMEPIT (electrical pitch) dependent
4ØØ.Ø
Default
DMTLIM: <*>1Ø.5
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTLIMcommand sets a maximum torque/force limit for the system.
Requests for higher torque/force will be clamped to this value. This command
will default automatically to a value appropriate to the motor selection (DMTR)
and the Aries drive you are using, and no changes are required in many
cases.
If your mechanical system has torque/force limitations (due, for example, to
the limitations of a coupler or belt), you can use this command to limit system
torque/force without affecting system scaling or gains.
During initial tuning, this command can be used to limit the torque/force
produced if the system becomes unstable, reducing the rate of motor heating
and allowing more reaction time for the person tuning the system, and
reducing the chances of damage to the mechanical system.
If DMTLIMis set higher than the value allowed by the motor’s peak current
times the motor’s Kt, or the drive’s peak current times the motor’s Kt
(whichever is lower), the new DMTLIMvalue will be ignored (but not
overwritten). In addition, the drive reports EO –Motor configuration
Warningand E11–Torque Rating Too High for Drive, and the
maximum internal value is used. You can clear the warning by sending the
RESETcommand or cycling power to the drive.
The motor’s torque/force constant (Kt) is derived from the motor’s voltage
constant (Ke, which is set by the DMTKEcommand) by the following
relationship (Note: Ke is set with the DMTKEcommand):
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3 3
Kt(Nm / A† ) =
Ke(Volts‡ / krpm)
Rotary motors:
Linear motors:
200π
† RMS, 0 - peak value
‡
3 3
Kt(N / A† ) =
Ke(Volts‡ /(meter /sec))
200π
† RMS, 0 - peak value
‡
DMTMAX
Type
Maximum Motor Winding Temperature
Motor
Product
Rev
<a_>DMTMAX<r>
Syntax
Aries
1.0
r = Degrees Celsius
Ø.Ø to 2ØØ.Ø : ±Ø.1
125.Ø
Units
Range
Default
DMTMAX: <*>125.Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTMAXcommand sets the maximum motor winding temperature
allowed. The DMTMAXvalue, in conjunction with the motor thermal time
constant (DMTTCM), the motor winding time constant (DMTTCW), the motor
thermal resistance (DMTRWC) and the continuous motor current (DMTIC), is
used in a real-time estimation of the motor winding temperature. When the
winding temperature exceeds DMTMAX, a drive fault occurs and the drive
reports E35–Motor Thermal Model Fault.
DMTR
Type
Identify Motor
Drive Configuration
Product
Rev
<a_>DMTR<t> this command is only a report back
Syntax
Units
Aries
1.0
t = Parker motor identification number
N/A
Range
“Blank”
Default
Response
See Also
DMTR:
<*>SM232AE
The purpose of the DMTRcommand is to record and report the identification
number of the Parker motor you selected in the Aries Support Tool.
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When you select a specific Parker motor using the Aries Support Tool, the
Parameters below) are automatically configured for the associated motor.
Using the Aries Support Tool, you can save the parameters in a configuration
file.
For the DMTRand all the motor parameter commands to take effect after
downloading the configuration file to the Aries drive, you must cycle drive
power or send the RESETcommand.
Note: For a non-Parker motor, the default setting is blank (empty). You must
set all relevant motor parameters manually.
Avoid using the DMTRcommand to change the motor name, because the
new DMTRvalue may not represent the actual motor parameters that are
currently loaded in the drive.
Servo Motor Data Parameters
MEPIT
DMTMAX
Motor Electrical Pitch
Maximum Motor Winding
Temperature
DMTD
DMTRES
DMTRWC
Motor Damping
Motor Winding Resistance
DMTIC
Continuous Current
Motor Winding Thermal
Resistance
DMTICD
DMTIND
DMTTCM
DMTTCW
Continuous Current
Derating
Motor Thermal Time
Constant
Motor Inductance (max)
Motor Winding Time
Constant
DMTINF
DMTIP
DMTJ
DMTW
Motor Inductance (min)
Peak Current
Motor Rated Speed
Velocity Limit
DMVLIM
DMVSCL
Motor rotor Inertia/Forcer
Mass
Velocity Scaling
DMTKE
DPOLE
ERES
Motor Ke
Number of Motor Pole
Pairs
DMTLIM
Torque/Force Limit
Encoder Resolution
Although these command values are auto-configured when you select a
Parker motor (using the Aries Support Tool), you may individually set the
command values with the respective configuration command.
Motor Configuration Error
Many of the above motor parameters, if not configured (i.e. a command
remains at its factory default value, or an RFScommand is executed) will
report a motor configuration warning or error when powering up the Aries
drive—EØ–Motor Configuration Warningor E1–Motor
Configuration Error(an error also disables the drive—DRIVEØ). To
resolve the error or warning condition, you must select a Parker motor using
the Aries Support Tool (or configure each motor parameter command with a
value other than zero using a terminal emulator), download the resulting
configuration information, and then send the RESETcommand or cycle
power.
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DMTRES
Type
Motor Winding Resistance
Motor
Product
Rev
<a_>DMTRES<r>
Syntax
Units
Aries
1.0
r = Ohm (measured line-to-line)
Ø.ØØ to 10Ø.ØØ : ±Ø.Ø1
Range
Ø.ØØ (DMTRES of Ø results in motor configuration
error)
Default
DMTRES:
<*>7.5Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Error and
E6–Resistance = Ø, and shuts down the drive.
The DMTREScommand sets the motor winding resistance. This resistance
value is measured at 25°C at the drive end of the motor cable (motor cable
included). This resistance is the phase-to-phase resistance measured at
terminals U to V, V to W, or W to U.
Warning — Disconnect the motor cable from the drive before attempting to
make this measurement. For best accuracy, and to avoid injury, this
measurement must be made with the motor cable disconnected from the
drive.
DMTRWC
Type
Motor Winding Thermal Resistance
Motor
Product
Rev
<a_>DMTRWC<r>
Syntax
Aries
1.0
Units
r = Degrees Celsius/Watt (°C/W)
Ø.ØØ to 16.ØØ : ±Ø.Ø1
Ø.5Ø
Range
Default
DMTRWC: <*>23.6Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
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DMTRWCspecifies the temperature rise of the motor winding above motor
case temperature per watt of winding power dissipation between the winding
and case. Motor heatsinking does not affect this value.
DMTSCL
Type
Torque/Force Scaling
Drive Configuration
Product
Rev
<a_>DMTSCL<r>
Syntax
Units
Aries
1.0
Rotary motor: r = Nm
Linear motor: r = N
Ø.Ø to 5ØØ.Ø (motor/drive dependent): ±Ø.1
Range
Ø
Default
DMTSCL: <*>2Ø.Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTSCLcommand scales the torque/force command input. It sets the
full-scale torque/force that will be produced from a 10-volt input command. It
controls the gain applied to the input. This can be used to scale the input to
match application needs. For example, if a torque/force sensor produces 2
volts per Newton-meter, the drive could be scaled to match this by using
DMTSCL5— this sets 10V = 5 N-m (0.5 N-m/Volt). DMTLIMmay limit
torque/force to less than this full-scale value.
Note: To configure the drive in torque/force mode so that a 10-volt
torque/force command produces the rated peak current of the drive (without
reference to motor parameters), enter for DMTSCLthe result of the following
calculation:
⎛
⎜
⎜
⎝
⎞
⎟
⎟
⎠
3 3
DMTSCL = TDIMAX
DMTKE
200π
Rotary Motors: V*/krpm
Linear Motors: V*/m/s
* peak value
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DMTSWT
Type
Motor temperature switch type
Motor configuration
Product Rev
Aries 2.10
<a_>DMTSWT<i>
Syntax
Units
i = motor temp switch type
0 (Normally closed switch)
Range
1 (Positive temperature coefficient thermistor)
2 (Normally open switch)
3 (Negative temperature coefficient thermistor)
DMTSWT0
Default
DMTSWT: <*>0
Response
See Also
DMTSWTsets the type of motor switch used. Values of 0 or 1 behave exactly
the same and are interchangeable. DMTSWT3specifies a negative
temperature coefficient thermistor. In this case TMTEMPreports the higher of
the motor thermal model value or the calculated thermistor temperature,
once the thermistor temperature is above 60 degrees C. The drive faults with
a motor temperature fault at a thermistor temp of 105 degrees C or the motor
thermal model setpoint (whichever is lower) when DMTSWTis set to 3.
The default value for this command is DMTSWT0and will work with both
positive temperature coefficient thermistors or normally closed switches.
DMTTCM
Type
Motor Thermal Time Constant
Motor
Product
Rev
<a_>DMTTCM<r>
r = minutes
Ø.Ø to 12Ø.Ø : ±Ø.1
Ø.Ø
Syntax
Aries
1.0
Units
Range
Default
DMTTCM: <*>3Ø.4
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTTCMcommand specifies the thermal time constant of the motor and
its mounting. The drive uses this value to help protect the motor from thermal
damage. It describes the length of time the motor takes to reach 63% of its
final temperature, given constant power. Note that the motor mounting
affects this measurement.
Continuous current ratings and published time constants for Parker motors
are specified when mounted to a 10" x 10" x ¼" aluminum plate in 25°C open
air. If your mounting surface provides heat-sinking or thermal mass
significantly different from this, a different value may be appropriate to your
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application. Note also that the time constant of the motor winding itself
(DMTTCW) is much faster than this; therefore, the rise in winding temperature
will initially be much faster than DMTTCMwould suggest.
DMTTCW
Type
Motor Winding Time Constant
Motor
Product
Rev
<a_>DMTTCW<r>
r = minutes
Ø.ØØ to 6Ø.ØØ : ±Ø.Ø1
Ø.ØØ
Syntax
Aries
1.0
Units
Range
Default
DMTTCW: <*>28.4Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMTTCWcommand specifies the time constant of the motor winding
alone. This is the time for the winding to reach 63% of its final temperature
rise above the rest of the motor, given constant power. Note that this is not
the time constant usually specified in motor data sheets (see DMTTCM); the
DMTTCWvalue is typically much faster.
DMTW
Type
Motor Rated Speed
Motor
Product
Rev
<a_>DMTW<r>
Syntax
Units
Aries
1.0
Rotary motor: r = revolutions/second
Linear motor: r = meters/second
Ø.Ø to 400.Ø : ±Ø.1
Range
Ø.Ø (DMTW of Ø results in motor configuration error)
Default
DMTW:
<*>15Ø.Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors EØ–Motor Configuration Warningand
E4–Rated Speed = Ø, and shuts down the drive.
The DMTWcommand specifies the rated speed of the motor. This is the lesser
of the following:
•
(Rotary motor) Motor mechanical limited speed
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•
•
(Rotary motor) Encoder limit of 5 MHz (pre-quadrature)
Linear motor speed limitations include encoder resolution and track
length.
•
The corner of the continuous speed/torque or speed/force curve
(the point where the continuous and peak torque/force curves
meet).
The DMTWvalue is used in conjunction with DMTICDto protect the motor from
thermal damage.
DMVLIM
Type
Velocity Limit
System
Product
Rev
<a_>DMVLIM<r>
Syntax
Units
Aries
1.0
Rotary motor: r = revolutions/second
Linear motor: r = meters/second
Ø.ØØ to 40Ø.ØØ : ±Ø.Ø1
125.ØØ
Range
Default
DMVLIM: <*>5Ø.ØØ
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
The DMVLIMcommand sets a limit that the commanded velocity cannot
exceed without affecting gains or scaling. This is typically used to protect
parts of the mechanical system.
If the velocity demand from the internal Aries control loops exceeds the limits
set by DMVLIM, the Aries invokes the “Override Mode”, in which the drive
software clamps the maximum velocity to the value set by DMVLIM.
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DMVSCL
Type
Velocity Scaling
Drive Configuration
<a_>DMVSCL<r>
Product
Rev
Syntax
Aries
2.0
Rotary motor: r = revolutions/second
Linear motor: r = meters/second
Units
Ø.ØØ to 4ØØ.ØØ (motor/drive dependent): ±Ø.Ø1
Range
4.ØØ
Default
DMVSCL: <*>1ØØ.Ø
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to 4.00—you must
manually set this parameter to a non-zero number.
The DMVSCLcommand scales the velocity command input. This command is
produced from a 10-volt input command. It controls the gain applied to the
input. This can be used to scale the input to match application needs. For
example, if an application requires a maximum speed of 10 Rev/Sec, then
the DMVSCLcould be set to 10. This would scale the input to 1Rev/Sec for
every volt applied to the input.
DNOTAD
Type
Notch Filter A Depth
Tuning
Product
Rev
<a_><!>DNOTAD<i>
n/a
Syntax
Aries
2.0
Units
Ø.ØØØØ - 1.ØØØØ
Ø.ØØØØ (depth is zero)
DNOTAD: *DNOTAD.5
Range
Default
Response
See Also
The DNOTADcommand sets the depth for the commanded torque/force notch
filter A. Setting this to zero (0) disables the filter. This command is useful in
adjusting the maximum allowable attenuation and phase shift through the
filter. The deeper the notch depth, the more attenuation and phase shift. In
general, the notch depth is increased until the resonance is diminished.
Increasing the depth further, might increase the phase shift to an
unacceptable level and decrease the overall system performance.
There are two cascaded notch filters labeled “A” and “B”. Both filters operate
in exactly the same way. The diagram below shows the topology of these
filters.
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Figure 44 Notch Filter Topology
The graphs below illustrate the transfer function for the magnitude and phase
of the notch filter command output torque/force vs. the notch filter command
input torque/force. In this example, the notch depths are set to .3, .6, and .9
(DNOTAD.3, DNOTAD.6, DNOTAD.9). The notch center frequency is set to
200 Hz (DNOTAF2ØØ) and the “Q” is set to 1 (DNOTAQ1).
Figure 45 Notch Filter Magnitudes
These filters operate in all DMODEsettings except Autorun (DMODE1).
DNOTAF
Type
Notch Filter A Frequency
Tuning
Product
Rev
<a_><!>DNOTAF<i>
i = Hz
Syntax
Aries
2.0
Units
Ø (disable), or 6Ø-1ØØØ
Ø (filter is disabled)
DNOTAF: *DNOTAF2ØØ
Range
Default
Response
See Also
The DNOTAFcommand sets the center frequency for the commanded
torque/force notch filter A. Setting this to 0 disables the filter. If setting a
value results in an internal calculation error, the last valid value is used, and
TE15is set.
There are two cascaded notch filters labeled “A” and “B”. Both filters operate
in exactly the same way. The graphs below illustrate the transfer function
(magnitude and phase) of the internal commanded torque/force vs. the user
commanded torque/force. In this example, the notch frequency is set to 150
Hz (DNOTAF15Ø) and the “Q” is set to 1 (DNOTAQ1).
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Figure 46 Notch Filter A
These filters operate in all DMODEsettings, except Autorun (DMODE1).
DNOTAQ
Type
Notch Filter A Quality Factor
Tuning
Product
Rev
<a_><!>DNOTAQ<r>
r = quality factor
Ø.5 to 2.5
Syntax
Aries
2.0
Units
Range
1
Default
DNOTAQ: *DNOTAQ1.5
Response
See Also
The DNOTAQcommand sets the quality factor (Q) for notch filter A. The
quality factor, or width of the frequency trough, determines how discrete the
filter is.
For information about the filter’s transfer function characteristics, see
DNOTAF.
DNOTBD
Type
Notch Filter B Depth
Tuning
Product
Rev
<a_><!>DNOTBD<i>
n/a
Syntax
Aries
2.0
Units
Ø.ØØØØ - 1.ØØØØ
.ØØØØ (depth is zero)
DNOTBD: *DNOTBD.5
Range
Default
Response
See Also
The DNOTBDcommand sets the depth for the commanded torque/force notch
filter B.
For information about the notch filter depth, see DNOTAD.
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DNOTBF
Type
Notch Filter B Frequency
Tuning
Product
Rev
<a_><!>DNOTBF<i>
i = Hz
Syntax
Aries
2.0
Units
Ø (disable), or 6Ø-1ØØØ
Ø (filter is disabled)
DNOTBF: *DNOTBF2ØØ
Range
Default
Response
See Also
The DNOTBFcommand sets the center frequency for notch filter B. Setting
this to 0 disables the filter. For a description of the filter’s transfer function
characteristics, refer to the DNOTAFcommand description.
DNOTBQ
Type
Notch Filter B Quality Factor
Tuning
Product
Rev
<a_><!>DNOTBQ<r>
r = quality factor
Ø.5 to 2.5
Syntax
Aries
2.0
Units
Range
1
Default
DNOTBQ: *DNOTBQ1.5
Response
See Also
The DNOTBQcommand sets the quality factor (Q) for notch filter B. The
quality factor, or width of the frequency trough, determines how discrete the
filter is.
For information about the filter’s transfer function characteristics, see
DNOTAF.
DNOTLD
Type
Notch Lead Filter Break Frequency
Tuning
Product
Rev
<a_><!>DNOTLD<i>
i = Hz
Syntax
Aries
2.0
Units
Ø (disable), or 8Ø-1ØØØ
Ø (filter is disabled)
DNOTLD: *DNOTLD2ØØ
Range
Default
Response
See Also
The DNOTLDcommand sets the break frequency of the lead filter. This filter
cannot be used alone, but must be used in conjunction with the DNOTLGlag
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filter. The DNOTLGlag filter must be configured before the DNOTLDlead filter
is configured.
The DNOTLDvalue must be less than or equal to 4 times the DNOTLG(notch
lag frequency) value; otherwise, the new DNOTLDvalue will be ignored (but
not overwritten), the configuration warning bit (E17) will be set, and the last
valid DNOTLDvalue will be used internally. This warning is cleared with the
In the graphs below, the transfer function is shown relating the internal
commanded torque/force vs. the user commanded torque/force. In this
example, the lag frequency was set first to 40 Hz (DNOTLG4Ø) and then the
lead filter was set to 160 Hz (DNOTLD).
Figure 47 Notch Lead Filter Break Frequency
DNOTLG
Type
Notch Lag Filter Break Frequency
Tuning
Product
Rev
<a_><!>DNOTLG<i>
i = Hz
Syntax
Aries
2.0
Units
Ø (disable), or 2Ø-1ØØØ
Ø (filter is disabled)
DNOTLG: *DNOTLG4ØØ
Range
Default
Response
See Also
The DNOTLGcommand sets the break frequency of the lag filter. This filter
can be used alone, or in conjunction with lead filter (DNOTLD) to improve the
phase response of the notch filters. In this case, the lag value (DNOTLG) must
be greater than or equal to ¼ of the lead value (DNOTLD), but not greater
than the DNOTLDvalue.
If DNOTLGis lower than ¼ the value of DNOTLD, the new DNOTLGvalue is
ignored (but not overwritten), the configuration warning bit (E17) is set, and
the last valid DNOTLGvalue is used internally. This warning is cleared with
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DPOLE
Type
Number of Motor Pole Pairs
Motor
Product
Rev
<a_>DPOLE<i>
Syntax
Units
Aries
1.0
i = pole pairs
1 to 2ØØ
Range
Ø (DPOLE of Ø results in motor configuration error)
DPOLE: <*>5Ø
Default
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number. Otherwise, the drive
reports the configuration errors E1–Motor Configuration Errorand
E5–DPOLE = Ø, and shuts down the drive.
The DPOLEcommand sets the number of motor pole
P
⎛ ⎞
pairs. The number of pole pairs is defined as the
number of poles (P), divided by 2 (or, P/2). The
electrical frequency of the current (ωe) is related to
the mechanical speed (ωm) of the motor by the pole
pairs. The equation (right) shows this relationship.
ω =
ω
⎜ ⎟
e
m
2
⎝ ⎠
Note: All linear motors, regardless of the number of stator poles, are
considered one pole-pair (DPOLE1) machines.
DPWM
Type
Drive PWM Frequency
Drive Configuration
Product
Rev
<a_>DPWM <i>
Syntax
Units
Aries
1.0
i = kHz
16 or 32 (16 only for models AR-20xE and AR-30xE)
16 (use the drive’s default frequency)
Range
Default
Response
See Also
DPWM:
<*>16
Note: This command does not take effect until you cycle power to the drive,
Use the DPWMcommand to select the drive’s PWM frequency. This value is
the internal PWM frequency as seen at the motor windings; the motor ripple
current is twice this frequency. In general, for a given drive power level, the
higher the switching frequency, the lower the motor ripple current heating
and the lower both the peak and continuous current ratings.
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DRES
Type
Drive Resolution
Drive configuration
<a_>DRES<i>
Product
Rev
Syntax
Units
Aries
2.10
i = Input Step Resolution
200 to 10737141823
4000
Range
Default
DRES:
<*>0
Response
See Also
and 7). Input steps will be scaled to the DRESvalue so DRESsteps on the
input would translate to one revolution of the motor. DRESis set to ERES
internally if DMPSCLis non-zero for backward compatibility with operating
system 2.0. DMPSCLshould be set to 0 (a new option in OS 2.10) to enable
DRESsupport.
Note: This command requires a reset to take effect. DMPSCLchanges are
immediate so it is possible to enable DRESsupport, then enable DMPSCL,
and have both features working at once.
DRIVE
Type
Drive Enable
Drive Configuration
<a_>DRIVE <b>
b = enable bit
1(enable) or Ø(disable)
Ø
Product
Rev
Syntax
Units
Aries
2.0
Range
Default
Response
See Also
DRIVE:
<*>Ø
The DRIVEcommand allows you to enable or disable (shut down) the drive.
If the hardware enable input is closed on power-up, the drive is automatically
enabled (generates a DRIVE1command). To disable the drive, either issue
the DRIVEØcommand or open the hardware enable interlock.
Conversely, if the hardware enable input is open on power-up, the drive is
disabled (DRIVEØ). To enable the drive, close the hardware enable input. To
verify the hardware enable input is open, query the ERRORcommand for E46
– Hardware Enable.
Note: Issuing a DRIVE1command from a DRIVEØcondition will set the
position error to zero (TPER= Ø).
All of these “Fault Conditions” automatically cause a shut down (DRIVEØ), as
well as activate the “fault” output and open the dry contact relay (“RELAY
N.O.”):
•
Certain axis “fault” conditions – refer to the status bits denoted with
an asterisk (*) in the ERRORdescription.
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•
If operating in the FLTDSB1mode and the drive received a DRIVEØ
command or the hardware enable input was opened.
DTHERM
Type
Thermal Switch Checking
motor
Product
Rev
<a_>DTHERM<b>
b = enable bit
Ø(enable) or 1(disable)
Ø
Syntax
Aries
1.0
Units
Range
Default
DTHERM: *Ø
Response
See Also
The DTHERM command is used to disable drive faults when the motor
thermal switch opens. It is useful when no thermal switch is present on the
motor. Send the DTHERMØ command to re-enable thermal switch checking.
ECHO
Type
Communication Echo Enable
Communication Interface
Product
Rev
<a_>ECHO<b>
Syntax
Units
Aries
1.0
b = enable bit
Ø (disable) or 1 (enable)
1
Range
Default
Response
See Also
ECHO:
<*>1
The ECHOcommand enables/disables command echo. If using an RS-485
multi-drop, disable echo.
Note: The ECHOcommand has no obvious effect. You will always see the
characters that you type echoed on the screen. Only after you send a
command delimiter (carriage return or line feed) is a command line sent to
the Aries drive.
Maximum pre-quadrature encoder frequency
ENCFLT
Type
Drive configuration
Product
Rev
<a_>ENCFLT<i>
Syntax
Aries
3.0
None
Units
0 (1.02MHz ), 1 (2.67MHz) or 2(5MHz)
Range
0
Default
Response
See Also
ENCFLT: <*>0
None
For increased noise immunity, rotary motors have increased filtering on the
encoder input. The maximum input frequency in 1.02 MHz pre-quadrature for
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rotary motors by default. If a linear motor is configured, the drive sets a 2.67
MHz pre-quadrature maximum input encoder frequency by default.
The ENCFLTcommand increases the default maximum pre-quadrature
encoder frequency from 1.02 MHz to 2.67 MHz or 5 MHz. This allows users
to take advantage of the higher input frequency, if necessary, at the expense
of some noise immunity.
Note: This command does not take effect until you cycle power to the drive
or send the RESETcommand.
ENCOFF
Type
Encoder Offset
Motor configuration
<a_>ENCOFF<i>
i = encoder offset
-32768 to 32767
0
Product
Rev
Syntax
Units
Aries
1.0
Range
Default
ENCOFF:
<*>0
Response
See Also
The ENCOFFcommand specifies the encoder offset. All standard (non-smart)
Parker encoders have an encoder offset of 0 degrees. The smart encoders
store the encoder offset in the motor, which the drive reads (and stores in the
ENCOFF parameter) upon power-up. The offset can vary from
–180 degrees (corresponding to ENCOFF=-32768) to +180 degrees
(corresponding to ENCOFF= 32767).
Note: To convert from degrees to counts, just multiply the offset in degrees
by 182.044.
ENCPOL
Type
Encoder Polarity
Drive Configuration
Product
Rev
<a_>ENCPOL<b>
Syntax
Aries
2.0
b = polarity bit
Units
0 (normal polarity), 1 (reverse polarity)
Range
0
Default
Response
See Also
ENCPOL: <*>0
The ENCPOLcommand reverses the encoder counting direction.
You can reverse the encoder polarity if the encoder input is counting in the
wrong direction (for example, using a custom motor). This reverses the
encoder counting direction without having to change the actual wiring to the
encoder input.
Notes
•
This command does not take effect until you cycle power to the
drive or send the RESETcommand.
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•
To reverse the commanded direction of motion, make sure there is
a direct correlation between commanded direction and encoder
direction. You can then issue the CMDDIRcommand to reverse both
the commanded direction and the encoder direction.
For more information, see CMDDIR.
•
The ENCPOLcommand will not affect the encoder output. If
ENCPOL1is required on the drive for servo stability, the equivalent
command will also be required on the controller.
ERES
Type
Encoder Resolution
Encoder Configuration
<a_>ERES<i>
Product
Rev
Syntax
Units
Aries
1.0
Rotary motor: i = counts/revolution
Linear motor: i = counts/electrical pitch
32 to 1Ø73741823
Range
4ØØØ (4096 for Resolver option)
Default
ERES:
<*>4ØØØ
Response
See Also
Auto-Setup: When using a Parker motor and the Aries Support Tool, this
command is automatically set for the selected motor.
If you did not use the Aries Support Tool, are using non-Parker motors, or
sent an RFScommand to the drive, the parameter is set to zero (0)—you
must manually set this parameter to a non-zero number.
Use the EREScommand to establish the encoder resolution (post
quadrature) in counts/rev or counts/electrical pitch. (To set a linear motor’s
electrical pitch, refer to the DMEPITcommand).
The servo system's resolution is determined by the resolution of the encoder
used with the servo motor. The EREScommand establishes the number of
counts (post quadrature), per unit of travel. For example, Parker’s SM and
NeoMetric Series motors with the “E” encoder option use 1,000-line
encoders, and therefore have a 4,000 count/rev post-quadrature resolution
(requires ERES4ØØØ). If the encoder is mounted directly to the motor, the
Aries’ resolution (ERESvalue) must match the encoder's resolution to ensure
that the motor will move according to the programmed distance and velocity.
Resolutions for Parker Encoders
Servo axes
BE Series Servo Motors..........................BExxxxJ-xxxx: ERES8000
................................................................BExxxxL-xxxx: ERES20000
SE, SM, N, or J Series Servo Motors .....SE/SM/N/JxxxxD-xxxx: ERES2000
................................................................SE/SM/N/JxxxxE-xxxx: ERES4000
MPM Series.............................................MPMxxxxxxxxJMxx: ERES4000
................................................................MPMxxxxxxxxJNxx: ERES8000
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................................................................MPMxxxxxxxxJLxx: ERES10000
................................................................MPMxxxxxxxxJPxx: ERES12000
................................................................MPMxxxxxxxxJQxx: ERES20000
................................................................MPMxxxxxxxxJTxx: ERES24000
................................................................MPMxxxxxxxxJXxx: ERES4096
................................................................MPMxxxxxxxxJYxx: ERES8192
................................................................MPMxxxxxxxxJZxx: ERES16384
Note: Motors with the Smart Encoder option set ERES automatically.
Changing the ERES value may cause unpredictable motor responses.
Note: ERES is fixed at 4096 for Aries drives with Resolver option.
Daedal Positioning Tables (encoder options)
-E2...........................................................ERES42000
-E3...........................................................ERES84000
-E4...........................................................ERES420000
-E5...........................................................ERES8400
For linear servo motors, use the following equation to determine the proper
ERES, based on both the encoder resolution and the motor’s electrical (or
magnetic) pitch (DMEPIT).
DMEPIT (mm)
ERES =
mm
Encoder _ resolution (
count)
Example
Linear encoder resolution (post quad) is 1 μm and the electrical pitch is 42
mm (DMEPIT42). ERESis calculated as:
42 (mm)
ERES =
= 42000
1⋅10-3
mm
(
count)
ERROR
Type
Error-Checking Report-Back
Error Handling
<a_>ERROR
N/A
Product
Rev
Syntax
Aries
1.0
Units
Range
N/A
Default
Response
See Also
ERROR:
none
<*>NO ERRORS
The ERRORcommand gives a text-based status report of drive errors
(E25through E46) that currently prevent the drive from enabling.
To re-enable the drive correct the specified fault, then reset the drive or cycle
power to it.
Table 46 contains the possible errors appearing in the text-based report and
their descriptions.
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Error
Description
E25—Excessive Command
Voltage at Enable
The command voltage (at the ANI+ terminal) was
too high when the drive was enabled. Lower the
voltage at the ANI+ terminal. Try using the fault on
startup voltage. (FLTSTP)
E26—Drive Faulted
The drive is faulted.
E27—Bridge Hardware Fault
E28-Bridge Temperature Fault
Excessive current or short on the H-bridge.
Excessive current being commanded:
1. If the application is operating in the peak range,
limiting the peak current setting with DMTLIM can
limit the current commanded and lower the bridge
temperature. Default DMTLIM is 3 x continuous
current, perhaps lowering it to 2.5 x continuous
current or 2 x continuous current can help. This,
however, will limit the motor’s available torque,
which may increase position error and possibly
cause a position error fault.
2. Issue a DIFOLD 1 command. This command
enables the “current foldback” feature in the drive.
However, a drive in “foldback” mode can limit the
motor’s available torque, which may increase
position error and possibly cause a position error
fault.
3. Use a larger Aries amplifier, which would be
capable of higher current outputs.
E29—Drive Over-voltage
E3Ø—Drive Under-voltage
E31—Bridge Foldback
The bus voltage is too high (>410 VDC). Lower
the AC Mains voltage and check for excessive
regeneration power. (TVBUS)
The bus voltage is too low (<85 VDC) or there is
overly aggressive acceleration or deceleration.
Raise the AC Mains voltage. (TVBUS)
Drive current was limited to prevent overheating
(warning only). See DIFOLD.
E32—Power Regeneration Fault
E34—Drive Temperature Fault
Check the Regeneration resistor for a short.
Wait for the drive to cool down. (TDTEMP)
E35—Motor Thermal Model
Fault
The motor thermal model has determined the
motor is too hot. Wait for the motor to cool, and
then re-enable the drive. (TMTEMP)
E36—Motor Temperature Fault
Motor thermal switch has tripped. Wait for the
motor to cool, and then re-enable the drive.
(TMTEMP)
E37—Bad Hall State
A problem with the Hall sensors exists. Check the
Hall state wiring. (THALL)
E38-Feedback Failure
Feedback not present or the signal level is
incorrect. (TPE, THALL)
E39—Drive Disabled
E4Ø—PWM Not Active
The drive is disabled. (DRIVE)
The H-bridge is not switching.
The drive regenerated (warning only).
E41—Power Regeneration
Warning
E42-Shaft Power Limited
Warning
Shaft power is limited to the rated output to protect
the drive (warning only).
E43-Excessive Speed at
Enable
The motor was turning too fast when the drive was
enabled.
E44-Excessive Position Error
Commanded position. Actual Position is greater
than the value set by SMPER.
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Error
Description
E45-Excessive Velocity Error
Commanded velocity. Actual Velocity is greater
than the value set by SMVER.
E46-Hardware Enable
0 = Hardware Enable (Drive I/O Pin 1 and 21)
1 = No Hardware Enable
E47-Low Voltage Enable
E48-Control Power Active
E49-Alignment Error
No motor power was present when the drive was
enabled.
The drive is in Control power mode. No motor
power is present.
The ALIGNcommand did not complete
successfully. (TPE, THALL)
E50-Flash Error
A problem writing to non-volatile memory exists.
(RFS).
E51-Resolver Error
A problem determining the correct resolver angle
exists. Applies to Arxx-xR models only. Check the
resolver feedback wiring.
E52-Encoder Loss Fault
The drive determined there was loss of feedback.
Check the feedback wiring. (TPE, THALL)
Table 46 Error Status⎯Text Based Report
ERRORL
Type
Error Log Selection
Error Handling
Product
Rev
<a_>ERRORL<b><b>...<b><b> (32 bits)
b = enable bit
Syntax
Aries
1.0
Units
Ø (disable) or 1 (enable)
1111111111111111
Range
Default
Response
ERRORL:
<*>ØØØØ_ØØØØ_ØØØØ_ØØØØ
bit 15
bit Ø
See Also
Use the ERRORLcommand to choose the conditions that will be included in
the error log. When an error log bit is enabled (ERRORL11...11), the
operating system will respond to a specific execution error by making an
entry in the error log. Each bit corresponds to a different error condition (see
where “n” is the error bit number and “b” is either one (1) to enable or zero
(Ø) to disable.
Use the TERRLGcommand to view the error log. Use the CERRLGcommand
to clear the error log.
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Bit
0
Function
Enable/Disable (Hardware enable input or software DRIVEcommand)
Bridge Fault
1
2
No PWM output (H-bridge switching)
Over Voltage (DC bus)
3
4
Under Voltage (DC bus)
5
Startup Voltage (analog command voltage)
Drive Over Temperature
6
7
Motor Over Temperature (calculated by thermal model)
Motor Thermal Switch
8
9
Feedback Error
10
11
12
13-15
Hall Error
Motor Configuration Error
Regeneration Fault
Reserved
Table 47 Error Log⎯Enable/Disable
ESTORE
Type
Store smart encoder data
Motor configuration
Product Rev
Aries 1.0
<a_>ESTORE
Syntax
Units
N/A
N/A
0
Range
Default
<*>Storing
<*>Stored
Response
See Also
Motor configuration commands
The ESTOREcommand is used to store all relevant motor configuration data
to the smart encoder. If changes are made to the motor configuration (for
example, if the current loop gains are tuned higher for the application), you
can store the changes by typing ESTOREinto the terminal and pressing
Enter.
The drive responds with Storing, and then Stored once the parameters have
been stored. After a reset, the new values are read from the encoder.
Note: The ESTOREcommand stores the following parameters in the encoder:
DMTD, DMTIC, DMTIND, DMTINF, DMTJ, DMTKE, DMTLIM, DMTR,
DMTRES, DMTRWC, DMTSCL, DMTSWT, DMTTCW, DMTTWM, DMTW,
DMVLIM, DPOLE, DPWM, DTHERM, ENCOFF, ENCPOL, IGAIN,
INTLIM, PGAIN, P163.
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FLTDSB
Type
Fault on Drive Disable
Drive Configuration
<a_>FLTDSB<b>
Product
Rev
Syntax
Aries
1.0
b = enable bit
Units
Ø (disable) or 1 (enable)
Range
Default
Response
See Also
Use the FLTDSBcommand to enable/disable the Fault on Drive Disable
mode. If Fault on Drive Disable is enabled (FLTDSB1– default setting), and
the drive is disabled via the Enable input, fault output is activated and the
brake relay is opened.
FLTSTP
Type
Fault on Excessive Startup Voltage
Drive Configuration
<a_>FLTSTP<r>
Volts
Product
Rev
Syntax
Aries
1.0
Units
Ø to 1ØV
Range
1ØV
Default
Response
See Also
FLTSTP: <*>1
Use the FLTSTPcommand to set the threshold for the Fault on excessive
startup voltage. The default is 10.00V, so no command input will fault the
drive. If the threshold is set lower, a command voltage above this level, when
the drive is enabled, will fault the drive. To re-enable the drive without
causing a fault, command an input voltage below the set value.
IANI
Type
Invert Analog Input
Drive configuration
Product
Rev
<a_>IANI<b>
Syntax
Units
Aries
2.10
b = enable bit
0 (do-not invert analog input) or 1 (invert analog
input)
Range
0
Default
IANI <*>0
Response
See Also
Note: This command requires a reset to take effect
The IANIcommand inverts the polarity of the analog input to the drive. This
has the effect of reversing any torque or velocity command. It can be useful
when using custom wiring during initial setup of the drive.
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Sending an IANI1command inverts the input polarity. In addition, the
command TANIreflects this change.
IAUTO
Type
Automatically determine Current Loop Gains
Tuning
Product
Rev
<a_>IAUTO<b>
Syntax
Units
Aries
3.0
none
0 (disable) or 1 (enable)
1
Range
Default
Response
See Also
IAUTO:
<*>1
The IAUTOcommand allows the drive to automatically determine the current
loop gains according to the bandwidth set via the DIBWcommand, and the
motor parameters (Resistance and Inductance). This can give improved
current loop response compared to using the default gains set by the support
tool.
IGAIN
Type
Integral Gain
Tuning
Product
Rev
<a_>IGAIN
Syntax
Units
Aries
1.0
none
Ø.ØØ to 1ØØ.ØØ
1
Range
Default
Response
See Also
IGAIN:
<*>1.ØØ
The IGAINcommand sets the integral gain of the current loop. High gains
can emphasize resonance and system noise, adds to heating of both motor
and drive, and increases acoustic noise produced by the motor.
INPOS
Type
Enable In Position Output
Drive Configuration
Product
Rev
<a_>INPOS<b>
Syntax
Units
Aries
2.0
b = enable bit
Ø (disable) or 1(enable)
Ø
Range
Default
Response
See Also
INPOS:
<*>Ø
Use the INPOScommand to replace the Fault output with an In-Position
output when using the drive in step & direction modes (DMODES6and 7). If
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the In-Position output is enabled, the output will be active when the motor
satisfies the In-Position criteria (as specified by the INPOSDBand INPOSTM
commands). To restore the Fault Output functionality, use INPOSØ.
INPOSDB
Type
In-Position Deadband
Drive Configuration
<a_>INPOSDB<i>
i = deadband in counts
Ø-32767
Product
Rev
Syntax
Aries
2.0
Units
Range
Ø
Default
INPOSDB: <*>Ø
Response
See Also
Use the INPOSDBcommand to specify the deadband in encoder counts for
the In-Position command. For the ‘In-Position’ output to be classed active,
the position error (as specified by the TPERcommand) should be less than or
equal to this value.
INPOSTM
Type
In-Position timeout value
Drive Configuration
<a_>INPOSTM<i>
i = ms
Product
Rev
Syntax
Aries
2.0
Units
1-1ØØØØ
Range
1
Default
INPOSTM: <*>1
Response
See Also
Use the INPOSTMcommand to specify the time in ms before the In-Position
output becomes active when the In-Position deadband criteria is met. The
drive must not receive any incoming steps during this time in order for the
In-Position output to become active.
System Load-to System Load-to-Rotor/Forcer
Inertia/Mass Ratio
LJRAT
Tuning
Type
Product
Rev
<a_>LJRAT<i>
Syntax
Units
Aries
2.0
Load to Rotor Inertia Ratio
Ø.Ø – 1ØØ.Ø
Ø.Ø
Range
Default
Response
See Also
LJRAT:
<*>Ø.ØØ
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(position mode). The LJRATcommand sets the system’s load-to-rotor inertia
ratio (rotary motors) or load-to-forcer mass ratio (linear motors). The ratio is
expressed in the following equation:
•
Rotary Motors— LJRAT= load inertia / motor rotor inertia
(Total system inertia = load inertia + motor rotor inertia)
•
Linear Motors— LJRAT= load mass / forcer mass
(Total system mass = load mass + forcer mass)
OHALL
Type
Hall-Only Commutation
Drive configuration
Product Rev
Aries 2.10
<a_>OHALL<i>
Syntax
Units
i = Hall commutation type
0 (sinusoidal commutation)
1 (trapezoidal commutation)
2 (DC Brushed motor commutation)
3 (Z-channel commutation – Smart Encoder only)
4 (Hall-less startup)
Range
0
Default
OHALL:
<*>0
Response
See Also
Note: This command requires a reset to take effect.
The OHALLcommand sets the commutation type. Use OHALL1to set
trapezoidal commutation and OHALL2for DC brushed motors. DC brushed
motors should be wired to motor phases U&W, if they are used. The default
is OHALL0(sinusoidal encoder commutation once the first hall transition has
occurred).
When using OHALL 1, turn off feedback auto-detection by setting SFBto 2.
There are application limitations to observe when using OHALL4 (Hall-less
commutation startup). When the Aries drive is enabled with OHALL4set, the
motor is moved slightly in open-loop mode and encoder position is monitored
to determine the rotor’s position in relation to the stator (or forcer/coil in
relation to the magnet track for linear motors). For this reason, OHALL4 will
not work in vertical applications or applications with heavy loads and/or high
frictional loads. If the motor has trouble turning smoothly with the drive in
“auto run” mode (DMODE1), that is a good indication that OHALL4 will be
unsuccessful.
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OUTBD
Type
Output Brake Delay
Output
Product
Rev
<a_>OUTBD<i>
milliseconds
Ø-1ØØØØ
Syntax
Aries
1.0
Units
Range
Ø
Default
Response
See Also
OUTBD:
none
<*>25Ø
The OUTBDcommand specifies the amount of time that the brake relay will
remain asserted after the current is applied to the motor windings when the
drive is enabled. This allows torque to build up in the motor while the fault
output is still high. This is important in vertical applications where the motor
must be able to support the load before the brake is released.
P163
Type
Hall direction P163
Drive configuration
Product
Rev
<a_>P163<i>
Syntax
Units
Aries
1.0
i = hall direction
0 (Halls count 623154623… as encoder counts +ve)
1 (Halls count 326451326… as encoder counts +ve)
Range
0
Default
P163:
<*>0
Response
See Also
Note: This command does not take effect until you cycle power to the drive,
or send the RESETcommand
The P163 command determines the order the Hall sensors count as the
encoder counts in a +ve direction. The default, P163=0, specifies that as the
encoder counts in a +ve direction that the Hall sensors count 6,2,3,1,5,4,6,…
P163=1 specifies that the hall sensors count in the opposite direction as the
encoder counts in the +ve direction.
This command has the same effect as swapping hall wires A and B to the
drive.
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PGAIN
Type
Proportional Gain
Tuning
Product
Rev
<a_>PGAIN<r>
None
Syntax
Units
Aries
1.0
Ø.ØØ to 2ØØ.ØØ
2Ø.ØØ
Range
Default
Response
See Also
PGAIN: <*>2Ø.ØØ
The PGAIN command sets the proportional gain of the current loop. High
gains can emphasize resonance and system noise, adds to heating of both
motor and drive, and increases acoustic noise produced by the motor.
PSET
Type
Establish Absolute Position
Tuning
Product
Rev
<a_>PSET<r>
Syntax
Units
Aries
2.0
None
-2,147,483,648 to +2,147,483,647
N/A
Range
Default
Response
See Also
PSET:
N/A
Use the PSETcommand to offset the current absolute position to establish an
absolute position reference. All PSETvalues entered are in counts.
The PSETcommand will define the present commanded position (TPC) to be
the absolute position entered.
Example
PSETØ
; Wherever the present actual or commanded position
; happens to be, consider that position to have an
; absolute position of zero.
RESET
Type
Reset
Communication Interface
Product
Rev
<a_>RESET
Syntax
Units
Aries
1.0
N/A
N/A
Range
N/A
Default
Response
See Also
RESET: (Displays power applied message)
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The RESETcommand affects the Aries drive the same as cycling power, or
activating the hardware Reset inputs (pins 18 and 23 on the DRIVE I/O
connector). The drive’s parameters are retained in non-volatile memory.
Note: After sending the RESETcommand to the Aries, wait until you see the
power-applied message before communicating with the Aries.
RFS
Return to Factory Settings
Drive Configuration
Type
Product
Rev
<a_>RFS
N/A
Syntax
Units
Aries
1.0
N/A
Range
Default
Response
See Also
N/A
N/A
The RFScommand returns all settings to factory default, with the exception
of the TDHRSvalue. A RESETcommand is automatically sent following this
command; therefore, no prompt will be returned.
When is the RFSevent finished? The RFSprocess can take several
seconds. When RFSis finished, the drive transmits the power-applied
message.
Recommendation: When finished configuring the drive using the Aries
Support Tool, save the configuration file to your personal computer’s (PC)
hard drive for safekeeping. If, after executing the RFScommand, you need to
restore the previous configuration, re-download the configuration file and
program files to your drive. (Remember to reset the drive to invoke new
configuration settings).
SFB
Type
Set Feedback Type
Drive configuration
Product
Rev
<a_>SFB<i>
Syntax
Units
Aries
1.0
i = feedback source
0 (unknown)
Range
1 (OS 1.0,2.0: Standard Encoder OS2.10 or greater:
Auto-Detect)
2 (OS 2.10 or greater: specify Standard Encoder)
3 (OS 3.10 or greater: Resolver option identified)
5 (OS 2.10 or greater: specify Smart Encoder)
6 (OS 2.10 or greater: reserved for absolute encoder)
1
Default
SFB:
<*>5
Response
See Also
In operating systems 2.0 or earlier, the SFBvalue reflected the type of motor
that the drive auto-detected. In operating system 2.10 and beyond, you also
can set a feedback type with the SFBcommand.
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SFB1sets auto-detect mode and is the default setting. In auto-detect mode
the SFBcommand reports the detected drive-type upon power-up. If SFBis
set to a value other than 1, the drive assumes that type of encoder is
attached and does not try to auto-detect the feedback type.
In operating system 3.10 and beyond, the Aries Resolver option will report an
SFB value of 3. Changing the value will not affect the drive operation and it
will return to 3 on power-up.
SGI
Servo Gain Integral
Tuning
Type
Product
Rev
<a_>SGI<i>
i = gain value
Ø.ØØ to 1ØØØ.ØØ
Ø.ØØ
Syntax
Units
Aries
2.0
Range
Default
Response
See Also
SGI:
<*>Ø.ØØ
(position mode). Use the Integral Gain (SGI) command to set the gain of the
integral term in the control algorithm. The primary function of the integral gain
is to reduce or eliminate final position error (e.g., due to friction, gravity, etc.)
and improve system accuracy during motion. If a position error exists
(commanded position not equal to actual position—see TPERcommand), this
control signal will ramp up until it is high enough to overcome the friction and
drive the motor toward its commanded position. If acceptable position
accuracy is achieved with proportional gain (SGP), then the integral gain
(SGI) need not be used.
If the integral gain is set too high relative to the other gains, the system may
become oscillatory or unstable. The integral gain can also cause excessive
position overshoot and oscillation if an appreciable position error has
persisted long enough during the transient period (time taken to reach the
position setpoint); this effect can be reduced by using the SGILIMcommand
to limit the integral term windup.
SGILIM
Type
Integral Windup Limit
Tuning
Product
Rev
<a_>SGILIM<i>
i = Limit value
Ø to 32767
1
Syntax
Units
Aries
2.0
Range
Default
Response
See Also
SGILIM: <*>1
(position mode). If integral control (SGI) is used and an appreciable position
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error has persisted long enough during the transient period (time taken to
reach the setpoint), the control signal generated by the integral action can
end up too high and saturate to the maximum level of the drive's analog
control signal output. This phenomenon is called integrator windup
After windup occurs, it will take a while before the integrator output returns to
a level within the limit of the controller's output. Such a delay causes
excessive position overshoot and oscillation. Therefore, the integral windup
limit (SGILIM) command is provided for you to set the absolute limit of the
integral and, in essence, turn off the integral action as soon as it reaches the
limit; thus, position overshoot and oscillation can be reduced.
SGP
Type
Servo Gain Proportional
Tuning
Product
Rev
<a_>SGP<i>
i = gain value
Ø.ØØ to 1Ø0Ø.ØØ
Ø.6Ø
Syntax
Units
Aries
2.0
Range
Default
Response
See Also
SGP:
<*>Ø.6Ø
(position mode). SGPallows you to set the gain of the proportional term in the
servo control algorithm. The output of the proportional term is proportional to
the difference between the commanded position and the actual position read
from the feedback device. The primary function of the proportional term is to
stabilize the system and speed up the response. It can also be used to
reduce the steady state position error.
When the proportional gain (SGP) is used alone (i.e., the other gain terms are
set to zero), setting this gain too high can cause the system to become
oscillatory, under damped, or even unstable.
SGV
Type
Servo Gain Velocity
Tuning
Product
Rev
<a_>SGV<i>
i = gain value
Ø.ØØ to 1ØØØ.ØØ
1.4Ø
Syntax
Units
Aries
2.0
Range
Default
Response
See Also
SGV:
<*>1.4Ø
(position mode). SGVallows you to control the velocity feedback gain in the
servo algorithm. Using velocity feedback, the controller's output signal is
made proportional to the velocity, or rate of change, of the feedback device
position. Since it acts on the rate of change of the position, the action of this
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term is to anticipate position error and correct it before it becomes too large.
This increases damping and tends to make the system more stable.
If this term is too large, the response will be slowed to the point that the
system is over-damped.
Since the feedback device signal has finite resolution, the velocity accuracy
has a limit. Therefore, if the velocity feedback gain (SGV) is too high, the
errors due to the finite resolution are magnified and a noisy, or chattering,
response may be observed.
SGVF
Type
Velocity Feedforward Gain
Tuning
Product
Rev
<a_><!>SGVF<i>
Syntax
Units
Aries
2.0
N/A
Ø-5ØØ
1ØØ
Range
Default
Response
See Also
SGVF:
*SGVF1ØØ
Use the SGVFcommand to set the velocity feedforward gain. Velocity
feedforward control improves position tracking performance when the system
is commanded to move at constant velocity. The velocity tracking error is
mainly attributed to viscous friction.
The SGVFvalue is multiplied by the commanded velocity calculated by the
Aries drive’s move profile routine to produce an estimated torque command
that gets added to the servo control signal. The value is normalized to the
current setting of both the motor and load viscous damping terms (DMTD) as
shown in the equation below.
Estimated velocity torque = DMTD ⋅ velocity command
14243
SGVF value =100%
Setting SGVFto one (1) theoretically produces zero (0) following errors during
the constant velocity portion of a move profile. This assumes that the drive or
motor are not being current limited, the values for viscous damping are
accurate and the models used for analysis are correct. The value of SGVF
can be adjusted from zero to as high as five (5) times (SGVF5) the theoretical
value.
Example
SGVF2
; Set velocity feedforward to 200% of theoretical value
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SHALL
Type
Hall Sensor Configuration
Drive Configuration
<a_>SHALL<i>
Product
Rev
Syntax
Units
Aries
1.0
i = control option number
Ø (do not invert) or 1 (invert)
Ø
Range
Default
Response
See Also
SHALL:
<*>Ø
Note: This command does not take effect until you cycle power to the drive,
The SHALLcommand controls the logic sense of the Hall sensors. To invert
the sensors, use the SHALL1command. To check the present value of the
Hall sensors, use the THALLcommand.
SMAV
Type
Maximum Acceleration in Velocity Mode
Tuning
Product
Rev
<a_>SMAV<i>
Syntax
Units
Aries
2.0
i = Acceleration in rev/sec2
Ø.ØØ to 1ØØØØ.ØØ
1ØØ.ØØ
Range
Default
Response
See Also
SMAV:
<*>1ØØ.ØØ
control the maximum acceleration permitted in velocity mode. Use this
command to protect the mechanical systems from overly aggressive velocity
changes. This command is scaled by the (ERES) command.
SMPER
Type
Maximum Allowable Position Error
Servo
Product
Rev
<a_>SMPER<i>
Syntax
Aries
2.0
i = Feedback device steps
Ø to 2,147,483,647
4ØØØ
Units
Range
Default
Response
See Also
SMPER: <*>4ØØØ
you to set the maximum position error allowed before an error condition
occurs. The position error, monitored once per system update period, is the
difference between the commanded position and the actual position as read
by the feedback device selected with the last SFBcommand. When the
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position error exceeds the value entered by the SMPERcommand, an error
condition is latched (ERRORbit #44) and the Aries drive issues a shutdown
and sets its analog output command to zero volts. The DRIVE1command re-
enables the drive, clears ERRORbit #44, and sets the commanded position
(TPC) equal to the actual feedback device position (TPE) – incremental
devices will be zeroed.
If the SMPERvalue is set to zero (SMPERØ), the position error condition is not
monitored, allowing the position error to accumulate without causing a fault.
When SMPERis set to a non-zero value, the maximum position error acts as
the servo system fault monitor; if the system becomes unstable or loses
position feedback, the drive detects the resulting position error, shuts down
the drive, and sets an error status bit.
SMVER
Type
Maximum Allowable Velocity Error
Servo
Product
Rev
<a_>SMVER<i>
i = Rev/Sec
Ø.ØØ to 4ØØ.ØØ
Ø.ØØ
Syntax
Aries
2.0
Units
Range
Default
Response
See Also
SMVER: <*>Ø.ØØ
the maximum velocity error allowed before an error condition occurs. The
velocity error is the difference between the commanded velocity (TVEL) and
estimated actual velocity (TVELA). If the error exceeds this value, a fault will
result in which the drive is shut down (DRIVEØ) and ERROR bit #45 is set.
The DRIVE1command re-enables the drive, clears ERRORbit #45, and sets
TVELequal to TVELA.
You can check the actual velocity error with the TVERcommand.
If the SMVERvalue is set to zero (SMVERØ), the velocity error condition is not
monitored, allowing the velocity error to accumulate without causing a fault.
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STATUS
Type
Status (full-text report)
Transfer
Product
Rev
<a_>STATUS
Syntax
Aries
1.0
N/A
Units
N/A
Range
N/A
Default
Response
STATUS: <*>GENERAL:
<*>
<*>
<*>
OS Revision: Aries Revision 1.Ø
Power Level: 75ØW
Control Power: INACTIVE
<*>MOTOR:
<*>
<*>
<*>
<*>
Motor Name: SM232AE
Motor Type: ROTARY
Feedback Type: SMART ENCODER
Motor Temp: 4ØC
<*>DRIVE
<*>
<*>
<*>
<*>
<*>
Drive: DISABLED
PWM Frequency: 16 kHz
Feedback Resolution: 8ØØØ
Drive Temperature: 35C
Bus Voltage: 85V
See Also
The STATUScommand provides full-text report of the current drive status. It
includes general features such as the OS Revision and Control power mode.
Control power mode is active when TVBUS is less than 85 VDC. Additionally,
it includes motor parameters and drive status.
TANI
Type
Transfer Analog Input Voltage
Transfer
<a_>TANI
Volts
Product
Rev
Syntax
Units
Aries
1.0
-1ØV to +1ØV
N/A
Range
Default
Response
See Also
TANI:
<*>-4.34
The TANIcommand returns the voltage level present at the ANI analog
input. The value reported with the TANIcommand is measured in volts.
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TCI
Transfer Commanded Current
Transfer
<a_>TCI
Amps
Type
Product
Rev
Syntax
Units
Aries
1.0
N/A
Range
Default
Response
See Also
N/A
TCI:
<*>5.ØØ
The TCIcommand reports the commanded motor current in amps (peak of
sine).
TDHRS
Type
Transfer Operating Hours
Transfer
Product
Rev
<a_>TDHRS
Syntax
Units
Aries
1.0
Lifetime operating hours
(resolution is hours)
Hour counter rolls over at 536854528 hours
N/A
Range
Default
TDHRS:
<*>16
Response
See Also
The TDHRScommand reports the lifetime number of hours that the Aries
drive has had power applied (AC mains or Control power).
TDICNT
Type
Transfer Continuous Current Rating
Transfer
Product
Rev
<a_>TDICNT
Amps rms
Syntax
Aries
1.0
Units
Drive Dependant
N/A
Range
Default
Response
See Also
TDICNT: <*>1Ø
The TDICNTcommand reports the continuous current rating of the drive in
amps rms.
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TDIMAX
Type
Transfer Maximum Current Rating
Transfer
<a_>TDIMAX
Amps rms
N/A
Product
Rev
Syntax
Aries
1.0
Units
Range
N/A
Default
Response
See Also
TDIMAX: <*>1Ø
The TDIMAXcommand reports the maximum current rating of the drive in
amps rms.
TDMIN
Type
Transfer Operating Minutes
Transfer
<a_>TDMIN
Minutes
Ø to 59
N/A
Product
Rev
Syntax
Units
Aries
1.0
Range
Default
Response
See Also
TDMIN:
<*>35
The TDMINcommand reports the minutes portion of the lifetime operating
hours that the Aries drive has had power applied (AC Mains or Control
power).
TDSEC
Type
Transfer Operating Milliseconds
Transfer
<a_>TDSEC
Milliseconds
Ø to 59999
N/A
Product
Rev
Syntax
Units
Aries
1.0
Range
Default
Response
See Also
TDSEC:
<*>35678
The TDSECcommand reports the milliseconds portion of the lifetime
operating hours that the Aries drive has had power applied (AC Mains or
Control power).
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TDTEMP
Type
Transfer Drive Temperature
Transfer
Product
Rev
<a_>TDTEMP
Degrees Celsius
N/A
Syntax
Aries
1.0
Units
Range
N/A
Default
Response
See Also
TDTEMP: <*>5Ø
The TDTEMPreports the measured temperature (internal) of the drive.
TERRLG
Type
Transfer Error Log
Transfer
Product
Rev
<a_>TERRLG
Syntax
Aries
1.0
N/A
Units
N/A
Range
N/A
Default
Response
TERRLG: <*>Operating hours: 1Ø5.25
<*>Power on Time: 5hrs 1Ø min 45.35 s
<*>Drive Temp: 35C
<*>Motor Temp: 85C
<*>Bus voltage: 163V
<*>Command Voltage: 5.35V
<*>Active Errors: E26-Drive Faulted
E27-Bridge Hardware Fault
<*>[Power Cycle]
See Also
The error log is updated every time an error occurs or the power is cycled.
The TERRLGcommand displays the last ten error conditions or power cycles.
The command displays them in order of earliest to latest, and returns a text-
based status report. When each error is logged, the following parameters are
saved:
•
•
•
•
•
•
•
Operating Hours (TDHRS, TDMIN, TDSEC)
Power-on Time
Drive Temperature (TDTEMP)
Motor Temperature (TMTEMP)
Bus Voltage (TVBUS)
Command Voltage (TANI)
Active Errors (ERROR)
The CERRLGcommand erases the stored contents of the error log. Clearing
the error log is a helpful diagnostic tool; it allows you to start the diagnostic
process when the error log is in a known state so that you can check the
error log in response to subsequent events.
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THALL
Type
Transfer Hall Sensor Values
Transfer
<a_>THALL
N/A
Product
Rev
Syntax
Units
Aries
1.0
1 to 6 (Ø or 7 is a fault condition)
N/A
Range
Default
Response
See Also
THALL:
<*>6
Encoder Motors: The THALLcommand reports the present Hall sensor
value. There are six distinct Hall states, from 1 to 6. Rotating the motor shaft
clockwise, the Hall state order should be 6, 2, 3, 1, 5, 4, 6, 2, 3, 1, 5, 4, 6…
THALLvalues Øand 7are invalid and will fault the drive, and report E37–Bad
Hall State.
For a complete description on how to troubleshoot Hall sensors, especially
for non-Parker Hannifin motors, see Hall Sensor
Note: For auto-configured “smart encoders”, the THALLonly reports the
initial hall state of the encoder when power is applied.
TIDAC
Type
Transfer D Quadrature Current
Transfer
<a_>TCI
Amps
Product
Rev
Syntax
Units
Aries
3.10
N/A
Range
N/A
Default
Response
See Also
TCI:
<*>5.ØØ
The TIDACcommand reports the actual “d” quadrature motor current in
amps (peak of sine).
TIQAC
Type
Transfer Q Quadrature Current
Transfer
<a_>TCI
Amps
Product
Rev
Syntax
Units
Aries
3.10
N/A
Range
N/A
Default
Response
See Also
TCI:
<*>5.ØØ
The TIQACcommand reports the actual “q” quadrature motor current in
amps (peak of sine).
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TMTEMP
Type
Transfer Motor Temperature
Transfer
Product
Rev
<a_>TMTEMP
Degrees Celsius
N/A
Syntax
Aries
1.0
Units
Range
N/A
Default
TMTEMP: <*>45
Response
See Also
The TMTEMPreports the predicted temperature of the motor winding for
Parker motors. The temperature is estimated using the winding and motor
time constants, the rated continuous current, and the winding thermal
resistance. The motor will fault (and the drive reports E35–Motor Thermal
Model Fault)at an estimated winding temperature of 125°C, assuming
the ambient temperature is 40°C.
In OS 2.10, If DMTSWTequals 3, and the thermal temperature is greater than
60°C, TMTEMPreports the higher of the motor model thermistor temperature
or the NTC thermistor temperature.
If you are using a non-Parker motor, the TMTEMPvalue depends on
parameters you supply for DMTRWC, DMTTCMand DMTTCW.
TOUT
Type
Transfer Output Status
Transfer
Product
Rev
<a_>TOUT
Syntax
Units
Aries
1.0
N/A
Ø (inactive) or 1 (active)
N/A
Range
Default
Response
See Also
TOUT:
none
<*>ØØØØ_ØØØØ_ØØØØ_ØØ11
The TOUTcommand returns the present status of the brake relay (bit 1) and
fault output (bit 0). Bits 2 through 15 are reserved. The return of one (1)
indicates the relevant output is active and a zero (Ø) indicates it is inactive.
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TPC
Transfer Position Commanded
Transfer
Type
Product
Rev
<a_>TPC
Syntax
Units
Aries
2.0
Encoder counts
-2147483648 to +2147483647
N/A
Range
Default
Response
See Also
TPC:
<*> Ø
(position mode). This command allows you to display the commanded
position.
Note: The reported value is measured in commanded counts (AKA: “motor
counts”).
TPE
Transfer Position of Encoder
Transfer
Type
Product
Rev
<a_>TPE
Syntax
Units
Aries
1.0
Encoder counts
-2147483648 to +2147483647
N/A
Range
Default
Response
See Also
TPE:
<*> Ø
The TPEcommand reports the present feedback device position, based on
the encoder resolution (ERES).
TPER
Type
Transfer Position Error of Encoder
Transfer
Product
Rev
<a_>TPER
Syntax
Units
Aries
2.0
Encoder counts
-2147483648 to +2147483647
N/A
Range
Default
Response
See Also
TPER:
<*> Ø
command reports the present position error. The error is reported in
feedback device counts and is based on the encoder resolution (ERES). The
position error is calculated every 62.5 µs.
Note: When the drive is set to DMODE6or DMODE7, the position error is the
difference between the commanded position and the actual position read by
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the feedback device. TPERdoes not apply in DMODE2(torque/force control
mode) and in DMODE4(velocity control mode); TPERreports zero in these
modes.
TREV
Type
Transfer Revision Level
Transfer
<a_>TREV
N/A
Product
Rev
Syntax
Units
Aries
1.0
N/A
Range
N/A
Default
Response
See Also
TREV:
<*>Aries OS Revision 1.Ø
The Transfer Revision Level (TREV) command reports the software revision
of the Aries firmware.
The Aries Resolver option reflects the Resolver feedback capability by
stating ‘Aries Resolver’ in the software revision reportback instead of ‘Aries’.
Updating the drive’s operating system: The operating system file is
located in the “Support & Downloads” section on the Parker Hannifin Motion
TSSPD
Type
Transfer PWM Update Period
Transfer
<a_>TSSPD
Microseconds
N/A
Product
Rev
Syntax
Units
Aries
1.0
Range
N/A
Default
Response
See Also
TSSPD:
<*>62.5Ø
The TSSPDcommand reports the current PWM update period in
microseconds. This is not the current loop update rate, which is fixed at 62.5
μs.
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TTRQ
Type
Transfer Commanded Torque/Force
Transfer
Product
Rev
<a_>TTRQ
Syntax
Units
Aries
1.0
Newton Meters (Rotary) or Newtons (Linear)
-DMTLIM TO +DMTLIM ± Ø.Ø1
N/A
Range
Default
Response
See Also
TTRQ:
<*>1.2Ø
The TTRQcommand reports the commanded motor torque/force.
TTRQA
Type
Transfer Actual Torque/Force
Transfer
Product
Rev
<a_>TTRQA
Syntax
Units
Aries
1.0
Newton Meters (Rotary) or Newtons (Linear)
Rotary motor: Ø.Ø to 5ØØ.Ø (motor/drive dependent):
±Ø.1
Range
Linear motor: DMEPIT (electrical pitch) dependent
N/A
Default
TTRQA:
<*>1.2Ø
Response
See Also
The TTRQAcommand reports the calculated torque/force, based on the
motor’s current and the motor’s Ke. The measured motor’s Ke value may
vary by ±10%; Therefore, the TTRQAmay vary by ±10% of the actual torque
at the motor.
TVBUS
Type
Transfer Bus Voltage
Transfer
<a_>TVBUS
Volts
Product
Rev
Syntax
Units
Aries
1.0
N/A
Range
N/A
Default
Response
See Also
<*>17Ø.45
The TVBUScommand reports the DC bus voltage available from the drive in
Volts.
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TVEL
Type
Transfer Current Commanded Velocity
Transfer
Product
Rev
<a_>TVEL
Syntax
Units
Aries
2.0
Revolutions per second or meters per second
N/A
N/A
Range
Default
Response
See Also
TVEL:
<*> 1.55
(position mode).
In velocity mode (DMODE4), TVELreports the commanded ±10V value from
the user before any internal limits are checked.
In position mode (DMODE6-7), TVELreports the internal velocity command
and is limited by DMVLIM.
TVELA
Type
Transfer Current Actual Velocity
Transfer
Product
Rev
<a_>TVELA
Syntax
Units
Aries
1.0
Revolutions per second or meters per second
N/A
Range
N/A
Default
Response
See Also
TVELA: <*> 1.55
The TVELAcommand reports the velocity as derived from the feedback
device. The sign determines the direction of motion.
Rotary Motors—Positive values represent
clockwise motion and negative values represent
counter-clockwise motion (assuming CMDDIR = Ø,
and that you connected the feedback device
according to instructions provided in “Chapter 2
Figure 48 Clockwise/
Counter-clockwise rotation
Installation”).
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TVER
Type
Transfer Current Commanded Velocity Error
Transfer
Product
Rev
<a_>TVER
Syntax
Units
Aries
2.0
Revolutions per second or meters per second
N/A
N/A
Range
Default
Response
See Also
TVER:
<*> 1.55
In velocity mode (DMODE4), TVELreports the commanded ±10V value from
the user before any internal limits are checked.
In position mode (DMODE6-7), TVELreports the internal velocity command
and is limited by DMVLIM.
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Chapter 7 Troubleshooting
CHAPTER SEVEN
Troubleshooting
IN THIS CHAPTER
LEDs ........................................................................................................158
Smart Encoders.......................................................................................163
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Troubleshooting Guidelines
If your system is not functioning properly, try the following steps.
First Troubleshooting Steps (verify LEDs)
•
Is the Right LED illuminated?
If not, look for problems with AC power. Check the AC power source.
Also check connections at the L1, L2, and terminals of the motor
mains connector, and at the C1 and C2 terminals of the control mains
connector).
•
Is the Right LED illuminated red?
Try to enable the drive by connecting ±5–24 VDC to pin 1 (+), and
common (GND) to pin 21 (–) of the DRIVE I/O connector. The right LED
should turn green.
•
Cycle power to the drive (this clears most faults). As the drive
powers up, watch the right LED.
Does the LED color change from off to red? Power is reaching the drive,
but the drive is not enabling.
Does the LED change from off to green? The drive is powered up and
enabled—power is not a problem.
•
Remove all connections to the drive (DRIVE I/O, MOTOR, MOTOR
FEEDBACK, and R+/R–), leaving Mains power (L1, L2, and
terminals) connected. Apply power to the drive.
Does the Right LED change from off to red? Then a short exists in the
disconnected cables.
•
Check Mains wiring and feedback connections.
If these steps do not solve your problem, follow the general troubleshooting
procedure outlined below.
General Troubleshooting Procedure
•
•
•
•
Launch the Aries Support Tool
Verify the RS-232/485 communications are functioning correctly.
In the Aries Support Tool, look to the Status Panel to identify
problems with the drive.
•
Check for non-Drive problems (problems with other parts of the
system)
Detailed procedures for each of these topics are given in the rest of this
chapter.
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LEDs⎯Drive Status Indicators
Normal Operation
LED–Left
LED–Right
Green
What it means
Off
Power on, enabled
Yellow
Green
Power on, regeneration active
Power on, disabled–No Fault
Power on, boot process
Waiting for OS download
OS download in process
Off
Red
Yellow
Off
Off
Red (flashing)
Red (flashing)
Yellow (flashing)
Table 22 LED Status Indicator-Normal Operation
Internal Drive Faults
LED–Left
LED–Right
What it means
Yellows
Red
Control power
mode active
Yellow & 1 Green (flashing)
Yellow & 2 Green (flashing)
Yellow & 3 Green (flashing)
Yellow & 4 Green (flashing)
Yellow & 5 Green (flashing)
Red
Red
Red
Red
Red
Bridge Fault
Feedback Fault
Thermal Fault
Other Fault
Encoder Loss
Table 23 LED Status Indicator-Internal Drive Fault
Establish Communications & Verify Drive
Configuration
If you cannot enable the drive, and examining LED conditions has not solved
your problem, then launch the Aries Support Tool and establish
communications with the drive. (For detailed instructions on establishing
If you are unable to establish communications, see “RS-232/485
Save the Configuration File
Because further troubleshooting steps can change the drive configuration,
upload the current drive configuration file, and save it to your personal
computer. This ensures you have a backup copy of the drive configuration.
To save a backup configuration file, use the Aries Support Tool.
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Reconfigure the Drive
To verify proper configuration, you may wish to reconfigure the drive. Pay
particular attention to selecting proper configuration settings for the motor
that you have installed, as motor configuration problems can cause a variety
of errors. Download the new configuration to the drive; the changes take
effect after you send the RESETcommand or cycle power.
RS-232/485 Communication Problems
If you cannot establish RS-232 or RS-485 communications, the next sections
give instructions for procedures to help isolate problems.
RS-232
RS-485 *
Rx, Tx, Gnd
2-wire plus ground
(Talk+, Talk–, Gnd)
9600 baud
8 data bits
1 stop bit
No parity
9600 baud
8 data bits
1 stop bit
No parity
Full-duplex
Half-duplex
* Twisted pair cabling recommended
(e.g. Belden 9842)
Table 48 Terminal Emulator Configuration for RS-232/485 Communication
Ensure the RS-232 or RS-485 wiring is connected prior to powering up the
Aries drive. When applying power, the drive will detect either RS-232 or RS-
485 and configure accordingly.
Testing the COM Port
Using the Aries Support Tool, you can test COM port connections.
►
Under Communications, select the COM port and then click Test.
RS-232 communications might require that you use a null modem cable.
For information about connecting to the COM port, see “Establishing
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Error
Resolution
Invalid COM port number
Select a different COM port
Unable to open COM port No COM port has been specified, or the
COM port is being used by other software.
Select a different COM port.
No response from Aries
drive
Power is not supplied to the drive, the drive
is not powered up, the power connection is
mis-wired, or the RS-232/485 cable is mis-
wired.
Check the drive to verify that the power
supply is connected, wired correctly. Then
apply power to the drive. Verify the wiring on
the RS-232/485 cable.
Incorrect response from
Aries drive
A different drive or serial device might be
connected to the selected COM port.
Verify that an Aries drive is connected to the
selected COM port.
OS needs to be
downloaded
Download the operating system to the Aries
drive.
Cycle power and
download OS
The Aries drive has encountered an error
while downloading an operating system.
Cycle power to the drive and download the
operating system again.
Table 49 Communications Port Errors and Resolutions
Error Messages
If the drive will not enable, you can view full-text reports of the drive
configuration (EØ through E24) and drive errors (E25 through E46). In a
terminal emulator, type CONFIGor ERROR, depending which information you
want to view.
You can also view the errors using the Aries Support Tool software.
►
In the Menu, select Status Panel. You can view the errors under Bit
Status.
The following is a list of Error messages and a brief corrective action:
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Error
Resolution
EØ—Motor Configuration
Warning
The motor rating is too high for the drive, and the
drive is using its own limits for safety reasons.
E1—Motor Configuration Error
One of the motor parameters is set to zero (0).
Look at the additional errors to find which
parameters are set at zero (0). Refer to your
motor specifications for the correct value.
E3—Max Inductance = Ø
This parameter is set to zero (0). To correct the
error, you must set a non-zero (0) value. Refer to
your motor specifications for the correct value.
(DMTIND)
E4—Rated Speed = Ø
E5—DPOLE = Ø
(DPOLE)
E6—Resistance = Ø
E7—Ke = Ø
This parameter is set to zero (0). To correct the
error, you must set a non-zero value. Refer to
your motor specifications for the correct value.
(DMTRES)
(DMKE)
E8—Continuous Current = Ø
E9—Peak Current = Ø
(DMTIC)
(DMTIP)
E1Ø—Continuous Current Too
High
The continuous current of the motor is higher than
the continuous current rating of the drive. Use the
continuous current rating for the drive.
E11—Torque Rating Too High
for Drive
The motor’s torque rating is too high for the power
level of the drive. Use the drive’s torque rating.
E12—Peak Current Too High
The peak current of the motor is higher than the
peak current rating of the drive. Use the drive’s
value for peak current.
E13 - Inertia = Ø
This parameter is set to zero (0). The drive will not
enable Velocity or Position Modes. To correct the
error, you must set to a non-zero value. Refer to
your motor specifications for the correct value.
(DMTJ)
E14 – Damping = Ø
This parameter is set to zero (0). The drive will not
enable Velocity or Position Modes. To correct the
error, you must set to a non-zero value. Refer to
your motor specifications for the correct value.
(DMTD)
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Error
Resolution
E15 – Notch filter Calc
Error.
The notch filter settings caused an internal
calculation error. The last valid value was used.
Try different values for the notch filter parameters.
(DNOTAF, DNOTAQ, DNOTBF, DNOTBQ)
E16 – Lead < Lag Freq
E17 – Lead ≥ 4* Lag Freq
E18 – Lag Freq < 2Ø Hz
E19–E24
The lead filter setting (DNOTLD) must be greater
than or equal to the lag filter setting. (DNOTLG)
The lead filter setting (DNOTLD) must be less than
or equal to 4 times the lag filter setting. (DNOTLG)
The lag filter setting (DNOTLG) must be greater
than or equal to 20 Hz.
RESERVED
E25—Excessive Command
Voltage at Enable
The command voltage (at the ANI+ terminal) was
too high when the drive was enabled. Lower the
voltage at the ANI+ terminal. Try using the fault on
startup voltage. (FLTSTP)
E26—Drive Faulted
The drive is faulted.
E27—Bridge Hardware Fault
E28-Bridge Temperature Fault
Excessive current or short on the H-bridge.
Excessive current being commanded:
1. If the application is operating in the peak range,
limiting the peak current setting with DMTLIM can
limit the current commanded and lower the bridge
temperature. Default DMTLIM is 3 x continuous
current, perhaps lowering it to 2.5 x continuous
current or 2 x continuous current can help. This,
however, will limit the motor’s available torque,
which may increase position error and possibly
cause a position error fault.
2. Issue a DIFOLD 1 command. This command
enables the “current foldback” feature in the drive.
However, a drive in “foldback” mode can limit the
motor’s available torque, which may increase
position error and possibly cause a position error
fault.
3. Use a larger Aries amplifier, which would be
capable of higher current outputs.
E29—Drive Over-voltage
E3Ø—Drive Under-voltage
E31—Bridge Foldback
The bus voltage is too high (>410 VDC). Lower
the AC Mains voltage and check for excessive
regeneration power. (TVBUS)
The bus voltage is too low (<85 VDC) or there is
overly aggressive acceleration or deceleration.
Raise the AC Mains voltage. (TVBUS)
Drive current was limited to prevent overheating
(warning only). See DIFOLD.
E32—Power Regeneration Fault
E34—Drive Temperature Fault
Check the Regeneration resistor for a short.
Wait for the drive to cool down. (TDTEMP)
E35—Motor Thermal Model
Fault
The motor thermal model has determined the
motor is too hot. Wait for the motor to cool, and
then re-enable the drive. (TMTEMP)
E36—Motor Temperature Fault
Motor thermal switch has tripped. Wait for the
motor to cool, and then re-enable the drive.
(TMTEMP)
E37—Bad Hall State
A problem with the Hall sensors exists. Check the
Hall state wiring. (THALL)
E38-Feedback Failure
Feedback not present or the signal level is
incorrect. (TPE, THALL)
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Error
Resolution
E39—Drive Disabled
The drive is disabled. (DRIVE)
E4Ø—PWM Not Active
The H-bridge is not switching.
E41—Power Regeneration
Warning
The drive regenerated (warning only).
E42-Shaft Power Limited
Warning
Shaft power is limited to the rated output to protect
the drive (warning only).
E43-Excessive Speed at
Enable
The motor was turning too fast when the drive was
enabled.
E44-Excessive Position Error
E45-Excessive Velocity Error
E46-Hardware Enable
Commanded position. Actual Position is greater
than the value set by SMPER.
Commanded velocity. Actual Velocity is greater
than the value set by SMVER.
0 = Hardware Enable (Drive I/O Pin 1 and 21)
1 = No Hardware Enable
E47-Low Voltage Enable
E48-Control Power Active
E49-Alignment Error
No motor power was present when the drive was
enabled.
The drive is in Control power mode. No motor
power is present.
The ALIGNcommand did not complete
successfully. (TPE, THALL)
E50-Flash Error
A problem writing to non-volatile memory exists.
(RFS).
E51-Resolver Error
A problem determining the correct resolver angle
exists. Applies to Arxx-xR models only. Check the
resolver feedback wiring.
E52-Encoder Loss Fault
The drive determined there was loss of feedback.
Check the feedback wiring. (TPE, THALL)
Table 50 Error Messages
Smart Encoders
Several drive related parameters may need additional configuration: CMDDIR,
DCMDZ, and ADDR.
If the Aries drive does not initialize correctly when connected to a Smart
Encoder (Parker motors only) , check the following:
1. Verify the motor phases are wired correctly. Incorrectly wired motor
phases can produce any combination of the following symptoms in the
motor: runs backwards; produces low torque, or gets warm.
2. Check that the feedback cables are wired correctly.
3. Apply power to the Aries drive.
a. Send the SFB command. It should report 5. If the response is not
<*>5, then check the feedback cable (if using a non-Parker cable,
check that it is correctly wired). If the cable is correctly wired and
connected, the problem might be the encoder.
b. Send the THALL command. It should report a number in the range
of 1-6, which indicates the phase wires are connected correctly. If
the response is Øor 7, a fault exists. Check the motor phase wiring
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c. Send the TPE command and turn the motor shaft. Verify the
encoder is counting in the correct direction. Turning the shaft
clockwise results in positive encoder counts. If not, check the
encoder feedback wires and reset the drive.
Note: The CMDDIRis fixed for smart encoders. To invert the direction, use
IANI1; however, for the ACR9000 do not use IANI1.
Hall Sensor Configuration/Troubleshooting
This section can help resolve a “Bad Hall State” error. Use the
Troubleshooting Checklist (below) to determine the cause of the error.
This section will assist you in resolving a Hall fault (ERRORbit E37-Bad
Hall State). Several problems can cause a Hall fault. The following list will
help identify these problems.
Troubleshooting Checklist
1. Does THALLreport either 0 or 7?
If yes, see Problem 1 or 2, below.
2. Does THALLchange if you move the motor by hand?
If no, see Problem 2, below.
3. Does THALLhave six distinct Hall states from 1 to 6? (No numerical
order is necessary.)
If no, see Problem 2, below.
4. Does THALLreport the six distinct Hall states n times as the rotor turns
one revolution, where n is equal to the number of pole-pairs (DPOLE)?
(Linear motors: n = pitch)
If no, see Problem 2 or 3, below.
5. Does THALLreport the Hall state sequence [1, 5, 4, 6, 2, 3, 1...] as the
motor turns clockwise? (Clockwise means TPEis increasing when
CMDDIRset to zero (0); it is also the direction the motor turns in
DMODE1.)
If no, see Problem 4, below.
6. Does ERRORreport a Hall fault each time the drive is enabled (DRIVE1),
even though the Hall state sequence is correct?
If yes, see Problem 4, below.
7. Does the Hall fault occur irregularly?
If yes, see Problem 5 or 6 below.
Possible Problems
1. No Hall states are seen by the drive.
2. The cable is not connected, or is connected incorrectly (mis-wired).
3. DPOLEor DMEPITis not set correctly.
4. Either the motor wires or the Hall wires are connected incorrectly.
Use Procedure 1 to fix this problem by changing the motor wires.
Use Procedure 2 to fix this problem by changing the Hall wires.
5. The Hall wires or the encoder wires may have loose connections,
causing intermittent faults.
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6. Noise induced on the Hall signals from routing the motor feedback cable
next to high-voltage cables (for example, strapped to motor power
cables).
Procedure 1
Use this procedure to connect your motor wires to the Aries.
1. With the motor’s feedback cable connected to the Aries drive, randomly
connect two motor power wires and slowly apply a positive voltage with
respect to the third.
Note: A variable low voltage (5 to 24V) current limiting (less than
continuous current rating of motor) power supply is preferred.
Warning — This procedure could damage the motor. Slowly increase the
voltage until the motor moves. Do not exceed the rated current.
Safety Warning — High-performance motion control equipment is capable
of producing rapid movement and very high forces. Unexpected motion may
occur especially during the development of controller programs. KEEP WELL
CLEAR of any machinery driven by stepper or servo motors. Never touch
any part of the equipment while it is in operation.
2. If THALLreports a 1,, 2, or 4, change SHALLfrom either 0 to 1 or from 1
to 0. After you change SHALL, reset the drive.
3. Repeat step 1 until THALLreports a value of 6.
4. The wire on the negative voltage or ground is motor wire W. The two
wires at the positive voltage are U and V.
Now there are two possibilities:
a. Connect the motor wires to the terminals. Operate the drive in
DMODE1. If the motor does not turn in the clockwise direction,
exchange motor wires U and V. Verify that the CMDDIRcommand
is set to zero (0).
b. Put positive voltage on motor wire W together with either U or V
and put negative voltage or ground on the remaining wire. If THALL
reports a value of 3, the wire at the negative voltage is V. If THALL
reports a value of 5, the wire at the negative voltage is U.
Figure 49 Hall Connection Diagram
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Procedure 2
Use this procedure to connect your Hall wires to the Aries.
1. First operate the drive in DMODE1and verify that the motor turns
clockwise. If not, swap any two motor wires.
2. Remove the motor power leads, leaving the feedback cable connected
to the Aries drive. Connect motor power wires U and V and slowly apply
a positive voltage with respect to W.
Note: A variable low voltage (5-24V) current limiting (less than
continuous current rating of motor) power supply is preferred.
Warning — This procedure could damage the motor. Slowly increase the
voltage until the motor moves. Do not exceed the rated current.
Safety Warning — High-performance motion control equipment is capable
of producing rapid movement and very high forces. Unexpected motion may
occur especially during the development of controller programs. KEEP WELL
CLEAR of any machinery driven by stepper or servo motors. Never touch
any part of the equipment while it is in operation.
3. If THALLreports a value of 1, 2 or 4, change SHALLfrom either 0 to 1 or
from 1 to 0. After you change SHALL, reset the drive.
4. Change the Hall wires until THALLreports a value of 6.
5. Connect motor wires U and W and slowly apply a positive voltage with
respect to V.
6. If THALLdoes not report a value of 3, change Hall wires B and C.
If THALLreports a value of 3, the wires are connected correctly.
Table 51 summarizes phase voltages and their corresponding Hall states.
Starting with SHALLØand the phase voltages as shown, the THALL
command should report the Hall states that match the “Correct” column. If
instead THALLreports Hall states that match the “Use SHALL1” column,
enter SHALL1and reset the drive. The Hall states should now match the
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Phase
V
Hall State
Correct
Use SHALL1
U
W
–
–
–
+
+
+
–
+
+
+
–
–
+
+
–
–
–
+
1
5
4
6
2
3
6
2
3
1
5
4
Table 51 Configuring Hall Sensors
Figure 50 illustrates the alignment of phases U, V, and W with Halls 1, 2, and
3 as viewed from the front of the shaft. The illustration assumes the following:
•
•
•
•
Hall signals that are High equal TRUE signals.
Hall 1 is the least significant bit (LSB).
Hall 3 is the most significant bit (MSB).
There is one hall cycle and one electrical cycle per pole pair on the
motor.
Figure 50 Motor Terminal Voltages (back EMF) and Hall Sensor Signals
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Appendix A Additional Specifications
APPENDIX A
Additional
Specifications
IN THIS CHAPTER
Amplifier...................................................................................................169
Feedback.................................................................................................169
Protective Circuits....................................................................................170
Cables......................................................................................................173
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Amplifier
Control Power: all models....................120/240 VAC Single Phase
Mains Control Power
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, and AR-13xx ...........................Single Phase AC Input,
120/240 VAC
16 or 32 kHz switching frequency
(motor dependant), pulse-width
modulated (PWM) with 3-phase
motor output
Current Loop Update Rate......................62.5 μs
Velocity and Position Loop......................250 μs
AR-20xE and AR-30xE ...........................Single or Three Phase AC Input
(AR-30xE is three phase only)
240 VAC
16 kHz switching frequency,
pulse-width modulated (PWM) with
3-phase motor output
Current Loop Update Rate......................62.5 μs
Velocity and Position Loop......................250 μs
Feedback
Encoder...................................................Differential Quadrature Encoder
Encoder Accuracy...................................±1 encoder count;
encoder dependent
Resolver..................................................Single Speed
Resolver Accuracy..................................±11 arc minutes
(12-bit A to D)
Resolver Excitation .................................10 KHz
Transformation Ratio ..............................0.5
Maximum Pulse
Input/Output Frequency ..........................5 MHz (5V TTL Only)
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Protective Circuits
Short Circuit Protection
The Aries drive has an internal circuit that protects it from short circuits
between one motor terminal to another (phase to phase), or from any motor
terminal to earth.
Short Circuit Fault—Cause .....................Phase-to-phase short circuit
Phase-to-earth short circuit
Results of Fault.......................................Power to motor is turned off
Fault output is activated
LED Left
LED Right
Yellow &
1 Green (blinking)
Red
Table 52 LED Short Circuit Fault
Resetting the fault
To clear the latched fault, choose one of the following methods:
►
►
Cycle power to the Aries drive.
–or–
Open the Aries Support Tool. Then select Operating System Update
from the menu and click Reset Drive.
Drive Over-Temperature Protection
The Aries drive’s over-temperature circuit monitors the drive’s internal
temperature. If the sensors exceed the threshold temperature, the drive
issues an over-temperature fault.
Threshold Temperature
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, and AR-13xx ...........................80°C (176°F)
AR-20xE and AR-30xE ...........................90°C (194°F)
Results of Fault.......................................Power to motor is turned off
Fault output is activated
LED Left
LED Right
Yellow &
3 Green (blinking)
Red
Table 53 LED Drive Over-Temperature Fault
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Resetting the fault
After the internal temperature has dropped below the values shown in Table
54, you can clear the latched fault. There are two methods available:
►
Model
Reset Temperature
AR-01xx, AR-02xx, AR-04xx,
75°C (167°F)
AR-08xx, and AR-13xx
AR-20xE and AR-30xE
85°C (185°F)
Table 54 Reset Temperature Values
Under-Voltage Protection
The Aries drive’s under voltage protection circuit monitors AC input voltage. If
the voltage falls below a specific value while the drive is operating, the drive
issues an under-voltage fault and turns off power to the motor output
terminals (MOTOR connector). This allows the motor to freewheel to a stop.
Warning — When an under-voltage protection fault occurs, the drive
disables power to its motor output terminals on the Motor connector. This
cuts all control to the motor and allows the load to freewheel to a stop.
Threshold Voltage
AR-01xx, AR-02xx, AR-04xx,
AR-08xx, and AR-13xx ...........................Voltage below 70 VAC trips fault
AR-20xE and AR-30xE ...........................Voltage below 160 VAC trips fault
Results of Fault.......................................Power to motor is turned off
Fault output is activated
LED Left
LED Right
Yellow
Red
Table 55 LED Under-Voltage Fault
Resetting the fault
To clear the latched fault, choose one of the following methods:
►
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Over-Voltage Protection
The Aries drive’s over-voltage circuit protects the drive from excessive
regeneration. If the voltage on the motor output terminals rises above the
threshold voltage, the drive issues an over-voltage fault and turns off power
to the motor output terminals (Motor connector). This allows the motor to
freewheel to a stop.
Warning — When an over-voltage protection fault occurs, the drive disables
power to its motor output terminals on the Motor connector. This cuts all
control to the motor and allows the load to freewheel.
Threshold Voltage
All Models................................................410 VDC
Results of Fault.......................................Power to motor is turned OFF
Fault output is activated
LED Left
LED Right
Yellow
& 4 Green (blinking)
Red
Table 56 LED Over-Voltage Fault
Resetting the fault
To clear the latched fault, choose one of the following methods:
►
Warning — Over-voltage protection monitors only the motor output terminals
(DC motor bus). It does not protect against an over voltage on the AC input
terminals, which can permanently damage the drive.
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Current Foldback
The Aries drive’s current foldback circuit helps to protect the drive from
damage due to prolonged high currents.
predict the number of seconds until foldback will occur. For example, the
figure shows that at the Aries drive’s peak current rating (250% of
continuous), foldback will occur after six seconds. After operating at the
drive’s peak current, the drive will reduce the drive current to 80% of the
drive’s continuous rating for 60 seconds. This is to ensure the drive’s
average continuous current rating is not exceeded.
Figure 51 Time until current foldback occurs
Cables
EMC Ready Cables
Many Parker cables are EMC installation ready. If installed according to
instructions provided under “A Highly-Immune, Low-Emission Installation –
European Compliance, and are thus an integral part of a CE system solution.
EMC cables add RF screening and bonding to reduce emissions, increase
immunity, and provide high integrity safety Earth bonding. They also help to
reduce problems in high electrical noise environments.
Non-EMC Cables
Parker also offers non-EMC cables, for applications where CE compliance is
not required, and where ambient electrical noise does not cause problems.
Because these cables are either unshielded, or contain simple foil shielding
terminated by a drain wire, they do not provide significant shielding of
electrical noise at high frequencies.
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Appendix B External Power-Dump Resistor Selection
APPENDIX B
External Power-Dump
Resistor Selection
IN THIS CHAPTER
Resistor Specifications ............................................................................181
Resistor Specifications ............................................................................187
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External Power-Dump Resistor Selection
Deceleration generates excess kinetic and potential energy. You can remove
the energy through regeneration—a process where the motor acts as
generator. Regeneration allows you to transfer the excess energy from the
motor and load back to the power supply.
When the drive and assorted losses cannot remove all the stored kinetic
energy, you must connect an external power-dump resistor. Connecting an
external power-dump resistor to the Aries drive helps dissipate the excess
kinetic and potential energy.
While the Aries drive contains circuitry to control an external power dump
resistor, resistor selection depends on the requirements of your particular
application.
There are two methods for selecting the appropriate external power-dump
resistor:
•
Parker drive and motor combinations.
•
relevant formulas to determine the needs of your particular
application.
Note: Both methods assume regeneration occurs during a trapezoidal move.
Important — It is possible to overload an Aries drive or the combination of
an Aries drive and power dump resistor.
If at the end of the calculations you find the required resistor is less than
allowed for your specific Aries model, or requires a watt rating greater than
the rated resistors available, do not use the Aries drive in your application.
Aries drive models AR-01xx, AR-02xx, AR-04xx, AR-08xx, and AR-13xx,
require external resistance values of 22 Ohms or greater.
Aries drive models AR-20xE and AR-30xE require external resistance values
of 8 Ohms or greater
Simplified Resistor Selection
Many applications do not require a power-dump resistor because the drive
can absorb or dissipate the regenerative deceleration energy. However, if a
drive faults from over-voltage during a deceleration event, an external power
dump resistor is probably required.
Table 57 contains recommended power-dump resistors for specific Aries
drive and Parker Hannifin motor combinations. The recommendations are
based on the calculations presented in the section titled “Calculating
Resistance—Rotary Motors”. These recommendations assume a worst-case
load-to-rotor inertia ratio of 10 to 1, maximum duty cycle and maximum
deceleration from maximum velocity for that specific motor/drive pairing.
These are recommendations only—while not optimized for your particular
application, they will work in most situations.
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Drive
AC
Voltage
Motor
Resistor
Rating
Resistor
rating
Isotek Part Number
(Resistance
—Ohms)
(Continuous
Power—
Watts)
120
240
SM162Z
BE164B
100
100
BRK-100R-10-L2, 4
See note1
AR-01xx
SM162Z
SM161A
SM162A
SM230A
SM231A
SM232A
BE230D
See note1
See note1
See note1
120
See note1
AR-02xx
AR-04xx
AR-08xx
47
47
200
200
BRM-47R0-10-L2, 4
BRM-47R0-10-L2, 4
See note1
240
240
BE231D
See note1
SM233A
BE232D
47
200
BRM-47R0-10-L2, 4
See note1
BE233D
See note1
BE233F
See note1
BE230F
See note1
120
240
BE231F
See note1
BE232F
See note1
BE341F
See note1
BE342H
See note1
NO702F
NO703F
NO704F
BE344L
22
22
22
22
22
22
8
300
BRQ-22R0-10-L2, 4
BRQ-22R0-10-L2, 4
BRQ-22R0-10-L2, 4
BRQ-22R0-10-L2,3,4
BRQ-22R0-10-L2,3,4
BRQ-22R0-10-L2,3,4
IRP20008R0J2, 4
IRP30008R0J2, 4
IRP30008R0J2, 4
IRP60008R0J2, 4
IRP60008R0J2, 4
IRP60008R0J2, 4
300
300
300
AR-13xx
AR-20xE
AR-30xE
240
240
240
MPM1141ASG
SMN1002S2F-KPN
1141BSG
1142BSG
1421BSG
1142ASG
1143ASG
1901BSG
300
300
800
8
1100
1100
1800
1800
1800
8
8
8
8
1. External power dump resistor not needed. However, higher operating voltage, higher load to rotor inertia
ratio, and higher duty cycles can increase the need.
2. Higher friction loads, lower speeds, lower deceleration rates, lower load to rotor inertia ratio, and lower duty
cycles can decrease the need for this resistor.
3. Minimum resistance allowed for AR-13 is 22 Ohms, therefore the maximum deceleration rate and/or duty
cycle may need to be reduced.
4. Isotek resistor or equivalent
Table 57 Simplified Selection of External Power-Dump Resistor
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Calculating Resistance—Rotary Motors
Because there are different types of motion profiles and application specific
conditions, you may need to modify the results to suit your particular
application. To keep it simple, the formulas assume a trapezoidal move
profile, in which the deceleration event is a single constant deceleration to
zero (0) velocity. For other motion profiles, you can modify the basic
concepts presented below.
Calculating the amount of energy to dissipate requires the motion profile
parameters, and the motor, drive, and load information. While significantly
more information is required, the calculations help tailor the size of power-
dump resistor to your application.
This is a multi-step process:
1. Calculate the motor’s kinetic energy.
2. Calculate the motor’s potential energy—vertical applications only.
3. Calculate the energy that can be absorbed by the drive capacitors
4. Calculate energy dissipated in the motor winding resistance
5. Calculate energy dissipated in load
6. Using the results from the previous four calculations, calculate the
amount of energy to dissipate through an external power-dump resistor.
With that result, you can then calculate the resistor necessary to dissipate
the excess energy.
Total Kinetic Energy
A body in motion produces energy. To stop motion, that energy must be
absorbed or dissipated elsewhere.
That energy can be defined in terms of inertia and velocity.
JM + JL
ω 2
)
1
2
EK =
Where
EK = rotational kinetic energy (Joules)
JM = rotor inertia in kilogram meter squared (kg⋅m2)
JL =
load inertia in kilogram meter squared (kg⋅m2)
ω =
rotational speed in radians per sec (1 revolution/sec =
2⋅π⋅radians/sec)
Total Potential Energy
A body at rest stores energy relative to the position of the body. When the
body moves, the potential energy is released and translated into kinetic
energy.
For purely horizontal applications, potential energy is negligible and therefore
not necessary for inclusion in your calculations. However, for vertical
applications, potential energy can greatly affect the selection of power dump
resistor. Regardless whether the incline is gentle or steep, it is important to
calculate the potential energy that must be absorbed or dissipated
elsewhere.
Appendix B External Power-Dump Resistor Selection 177
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Ep = mgh
Where
Ep = potential energy (Joules)
m = mass of forcer and load (kg)
g =
gravitational constant (9.81 m/s2)
h =
vertical height change during deceleration (m)
Energy Absorbed by Drive Capacitors
The Aries drive’s capacitors can store energy. With motor deceleration, the
drive capacitors absorb some of the kinetic and potential energy. While the
capacitors absorb energy, the bus voltage increases. Later, the capacitors
release that potential energy in subsequent accelerations, or into typical drive
losses.
If too much energy is absorbed by the capacitors, the Aries drive faults from
over-voltage. Under these circumstances, an external power dump resistor is
required.
That ability to absorb energy can be defined in terms of capacitance and
voltage.
1
2
2
EC = C(VTRIP −VNOM
)
2
Where
EC = energy that can be absorbed by the drive capacitors (Joules)
C = drive capacitance (Farads)
VTRIP = power dump trip DC voltage (400 VDC for Aries drives)
VNOM = nominal DC motor voltage (typically AC mains voltage at
; for
2
example, 120 VAC *
= 170 VDC)
2
Fortunately, for a given drive the capacitance and voltages are fixed. Table
58 provides the needed information and results from the above calculation.
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Capacitance
(uF)
VTRIP
(VDC)
EC (120 VAC)
Joules
EC (240 VAC)
Joules
Drive
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
440
400
28
9
660
400
400
400
400
400
400
43
14
19
24
35
50
50
880
57
1100
1590
2240
2240
72
104
N/A
N/A
When the voltage drops below 385 VDC, the Aries drive stops dissipating power through the
power dump resistor.
Table 58 Drive Capacitor Absorption
Energy Dissipated in Motor Winding Resistance
Some energy is dissipated in the motor windings. Because the energy is
converted to wasted heat in the motor, it is referred to as copper losses.
The energy during deceleration can be derived from the inertia, deceleration
rate, motor resistance, and motor torque constant. If some of the parameters
are not known, the energy dissipated in the motor windings (EW) can
conservatively be assumed zero (0).
This is based on current and motor winding resistance.
2
⎛
⎞
(
JM + JL
⋅ω
)
1
1
2
⎜
⎜
⎟
⎟
EW = I RM ⋅tD = ⋅
⋅ RM ⋅tD
2
2
kT ⋅tD
⎝
⎠
Where
EW = energy dissipated in the motor windings (Joules) – copper losses
I = current through the windings (Ampsrms
RM = line to line motor resistance (Ohms)
tD = deceleration time (Seconds)
JM = rotor inertia (kg⋅m2)
)
JL =
load inertia (kg⋅m2)
kT =
motor torque constant (Nm/Amprms)
ω =
rotational speed in radians per sec (1 revolution/sec =
2⋅π⋅radians/sec)
Appendix B External Power-Dump Resistor Selection 179
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Energy Dissipated in Load
The load dissipates energy through friction losses, viscous damping, and
other motor/load related losses. These losses are known as load losses. If
some of the parameters are not known, the energy dissipated in the load (EL)
can conservatively be assumed zero (0).
This can be derived from the torque required during the constant velocity
portion of the move profile, either measured or calculated.
1
EL = Tω ⋅tD
2
Where
EL = energy dissipated by the load (Joules) – load losses
T =
torque at constant velocity (Nm)
ω =
rotational speed in radians per sec (1 revolution/sec =
2⋅π⋅radians/sec)
tD =
deceleration time (Seconds)
Energy to Dissipate in the External Power-Dump
Resistor
To stop a motor, kinetic and potential energy must go somewhere. Through
the previous calculations, you have determined the total kinetic and potential
energy, and the energy lost to various paths.
From the total kinetic and potential energy, subtract the energy dissipated
through the drive capacitors, motor windings, and load loss. If the copper
losses (EW) or load losses (EL) are not easily determined, you can
conservatively assume they are zero (0).
The resulting sum represents the power for dissipation in an external power
dump resistor.
ER = EK + EP − EC − EW − EL
Where
ER = energy to be dissipated in the external resistor (Joules)
EK = rotational kinetic energy (Joules)
EP =
potential energy (Joules)
EC = energy that can be absorbed by the drive capacitors (Joules)
EW = energy dissipated in the motor windings (Joules) – copper losses
EL = energy dissipated by the load (Joules) – load losses
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Resistor Specifications⎯Rotary Motors
Having determined the amount of energy to dump (ER), you can then
calculate the resistor specifications.
•
•
•
Maximum resistance
Peak dissipation
Average dissipation
Maximum Resistance
This calculation determines the maximum value of resistance needed for the
external power-dump resistor. We recommend that you select a lower value
resistance, typically in the 22 to 100 ohm range.
Important — It is possible to overload an Aries drive or the combination of an Aries drive and
power dump resistor.
If at the end of the calculations you find the required resistor is less than allowed for your
specific Aries model, or requires a watt rating greater than the rated resistors available, do not
use the Aries drive in your application.
Aries drive models AR-01xx, AR-02xx, AR-04xx, AR-08xx, and AR-13xx, require external
resistance values of 22 Ohms or greater.
Aries drive models AR-20xE and AR-30xE require external resistance values of 8 Ohms or
greater
VTRIP ⋅kT ⋅tD
V
I
RR =
=
(
JM + JL ⋅ω
)
Where
RR = maximum external power dump resistance (Ohms)
V =
voltage across the resistor (VTRIP
)
I =
current through the resistor (drive current required to decelerate
the load)(Ampsrms
VTRIP = power dump trip DC voltage (400 volts for Aries drives)
kT = motor torque constant (Nm/Amprms
JM = rotor inertia (kg⋅m2)
)
)
JL =
tD =
ω =
load inertia (kg⋅m2)
deceleration time (Seconds)
rotational speed in radians per sec (1 revolution/sec =
2⋅π⋅radians/sec)
Appendix B External Power-Dump Resistor Selection 181
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Peak Dissipation
During a single deceleration, all the calculated power-dump energy (ER) must
dissipate in the external resistor. The external power-dump resistor then
slowly dissipates that energy as heat. This peak power must not exceed the
capabilities of the resistor, which is typically 10 times the average power
rating.
ER
P
=
PEAK
tD
Where
PEAK= peak power into the external power dump resistor (Watts)
ER = energy to be dissipated in the external resistor (Joules)
tD = deceleration time (Seconds)
P
Average Dissipation
Repetitive moves need to dump the energy each time the deceleration
occurs. The duty cycle of this repetition determines the average power the
resistor must dissipate. This average power must not exceed the capabilities
of the resistor.
Power resistors are rated based on ideal heatsink and airflow conditions, and
are therefore often over-rated by the manufacturers. To ensure the average
energy dissipation of the resistor exceeds the average power dump for the
application, the regenerative power should never exceed 50% of the
resistor’s average power rating.
tD
P = P
⋅
AVG
PEAK
tC
Where
P
AVG = average power into the external power dump resistor (Watts)
PEAK =peak power into the external power dump resistor (Watts)
P
tD =
deceleration time (Seconds)
tC =
cycle time or time between each deceleration event (Seconds)
Important — Under normal operation the external power-dump resistor
could operate in excess of 200 °C. Keep the resistor away from thermally
sensitive components, such as cables or plastic hardware.
Proper installation may require the use of thermal compound and proper
thermal connection to a heat absorbing metal surface.
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Calculating Resistance—Linear Motors
That energy can be defined in terms of mass and velocity.
M F + M L
v2
)
1
2
EK =
Where
EK = rotational kinetic energy (Joules)
MF = mass of forcer in kilograms (kg)
ML = mass of load in kilograms (kg)
v =
velocity in meters per second (m/s)
Appendix B External Power-Dump Resistor Selection 183
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vertical height change during deceleration (m)
2
= 170 VDC)
Fortunately, for a given drive the capacitance and voltages are fixed. Table
calculation.
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Capacitance
(uF)
VTRIP
(VDC)
EC (120 VAC)
Joules
EC (240 VAC)
Joules
Drive
AR-01xx
AR-02xx
AR-04xx
AR-08xx
AR-13xx
AR-20xE
AR-30xE
440
400
28
9
660
400
400
400
400
400
400
43
14
19
24
35
50
50
880
57
1100
1590
2240
2240
72
104
N/A
N/A
When the voltage drops below 385 VDC, the Aries drive stops dissipating power through the
power dump resistor.
Table 59 Drive Capacitor Absorption
Energy Dissipated in Motor Winding Resistance
Some energy is dissipated in the motor windings. Because the energy is
converted to wasted heat in the motor, it is referred to as copper losses.
The energy during deceleration can be derived from the mass, deceleration
rate, motor resistance, and motor force constant. If some of the parameters
are not known, the energy dissipated in the motor windings (EW) can
conservatively be assumed zero (0).
This is based on current and motor winding resistance.
2
⎛
⎞
(
M F + M L ⋅v
)
1
1
2
EW = I 2 RM ⋅tD =
⋅
⋅ RM ⋅tD
⎜
⎜
⎟
⎟
2
kF ⋅tD
⎝
⎠
Where
EW = energy dissipated in the motor windings (Joules) – copper losses
I = current through the windings (Ampsrms
RM = line to line motor resistance (Ohms)
tD = deceleration time (Seconds)
)
MF = mass of forcer in kilograms (kg)
ML = mass of load in kilograms (kg)
kF =
motor force constant (N/Amprms)
Appendix B External Power-Dump Resistor Selection 185
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Energy Dissipated in Load
The load dissipates energy through friction losses, viscous damping, and
other motor/load related losses. These losses are known as load losses. If
some of the parameters are not known, the energy dissipated in the load (EL)
can conservatively be assumed zero (0).
This can be derived from the force required during the constant velocity
portion of the move profile, either measured or calculated.
1
EL = F ⋅v ⋅tD
2
Where
EL = energy dissipated by the load (Joules) – load losses
F =
v =
tD =
force at constant velocity in Newtons (N)
velocity in meters per second (m/s)
deceleration time (Seconds)
energy dissipated by the load (Joules) – load losses
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Resistor Specifications⎯Linear Motors
VTRIP ⋅kF ⋅tD
V
I
RR =
=
(
MF + ML ⋅v
)
Where
RR = maximum external power dump resistance (Ohms)
V =
voltage across the resistor (VTRIP
)
I =
current through the resistor (drive current required to decelerate
the load)(Ampsrms
TRIP = power dump trip DC voltage (400 volts for Aries drives)
kF = motor force constant (N/Amprms
)
V
)
MF = mass of forcer in kilograms (kg)
ML = load mass in kilograms (kg)
tD =
deceleration time (Seconds)
velocity in meters per second (m/s)
v =
Appendix B External Power-Dump Resistor Selection 187
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thermal connection to a heat absorbing metal surface.
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Appendix C Regulatory Compliance–UL and CE
APPENDIX C
Regulatory Compliance
UL and CE
IN THIS CHAPTER
Installing the Aries Drive..........................................................................191
Regulatory Agencies................................................................................200
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System Installation Overview
This appendix contains information related to installation methods and
practices that can be used to aid the systems integrator or machine builder in
designing a compliant installation, meeting the needs of global regulatory
agencies.
The installation overview is divided in to two sections—“Safety” and
“Electromagnetic Compatibility (or EMC)”.
It is recommended that the installer read this entire overview, prior to taking
any action, as some of the required installation methods can be leveraged
across both Safety and EMC installations.
Although Aries drives are technically considered motion control components
and are therefore not within the scope of the European union’s CE
(Conformité Européenne) directives, Parker has taken the initiative to provide
its customers with easy to integrate motion control products that meet global
requirements.
The following constitutes what is typically required to install Aries drives into
a CE compliant system. Additional installation measures may be required at
some locations. The machine builder has ultimate responsibility for machine
compliance.
General Safety Considerations
These products are intended for installation according to the appropriate
safety procedures including those laid down by the local supply authority
regulations. The recommendations provided are based on the requirements
of the Low Voltage Directive and specifically on EN61010. Remember, never
compromise safety to achieve EMC compliance. Therefore, in the event of a
conflict between safety regulations and the following EMC recommendations,
safety regulations always take precedence.
General EMC Considerations
The Aries product is a motion control component and as such will be built in
to another machine that will in turn be required to comply with the relevant
directives of the marketplace.
It is important to remember that for specific installations, the full protection
requirements of the EMC directive 89/336/EEC need to be met before the
system is taken in to service. This must be verified either by inspection or by
testing. The following EMC installation recommendations are intended to
assist in ensuring that the requirements of the EMC directive are met. It may
be necessary to take additional measures in certain circumstances and at
specific locations.
It should be stressed that although these recommendations are based on the
expertise acquired during the design and development of the Aries products,
and on tests carried out on similar products, it is impossible for Parker to
guarantee compliance of any particular installation. This will be strongly
influenced by the physical and electrical details of the installation and the
performance of other system components. Nevertheless, it is important to
follow all the installation recommendations if an adequate level of compliance
is to be achieved.
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Installing the Aries Drive
Only qualified, skilled electrical technicians familiar with local safety
requirements should install this product. For service, the drive must be
returned to an authorized service center. There are no user serviceable parts
inside the chassis. In certain circumstances, opening the cover may void the
product warranty.
The Aries drive is a vented product. To prevent material spilling into the
drive, mount it under an overhang or in a suitable enclosure.
Aries products are made available under “Restricted Distribution” for use in
the “Second Environment” as described in EN 61800-3 1996, page 9. This
means only those individuals familiar with the EMC requirements of power
drive systems should install this product and that this product is designed for
connection to mains distribution networks other than low-voltage networks,
which may supply domestic premises. The drives can tolerate atmospheric
pollution degree 2, which means only dry, non-conductive pollution is
acceptable.
Aries drives have been shown to meet the requirements of both the
European LVD & EMC directives when installed according to the
recommendations given within this section. It is recommended the drive be
installed in an enclosure to protect it from atmospheric and industrial process
contaminants and to prevent operator access while it has power applied.
Metal equipment cabinets are ideally suited for housing the equipment since
they can provide operator protection, EMC screening, and can be fitted with
interlocks arranged to remove all hazardous motor and drive power when the
cabinet door is opened. Do not arrange interlocks to open circuit the motor
phase connections while the system is still powered, as this could cause
damage to the drive.
Precautions
During installation, take the normal precautions against damage caused by
electrostatic discharges. Wear earth wrist straps. A switch or circuit breaker
must be included in the installation, which must be clearly marked as the
disconnecting device and should be within easy reach of the machine
operator.
The Aries Drive has exposed high voltage terminals. In order to comply with
the safety requirements pertaining to European Compliance, and other
authorities, the drive must be mounted in such a way as to restrict access to
these terminals during normal operation.
A Safe Installation – Meeting the Requirements of the Low
Voltage Directive (LVD)
In order to comply with the requirements of the European Union’s Low
Voltage Directive, the following installation measures must be taken.
•
Mains fuses must be installed on all mains input lines carrying
operating current. For more information, see “Motor Power Fuse
•
Drive Protective Earth Conductor must be connected directly to a
reliable system safety Earth point. Total resistance from Drive’s
Protective Conductor Terminal to a Reliable System Safety Earth
Appendix C Regulatory Compliance – UL and CE 191
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must not exceed 0.1 Ohm, and must be capable of carrying 25A of
Fault Current.
•
•
Motor safety earth conductor (for motor voltages greater than or
equal to 75 volts) must be connected to the drive’s Motor Earth
terminal, marked with
.
The drive must be installed in a manner that prevents operator
access to hazardous live terminals during normal operation.
Additional safety measures may be required within your particular market,
please consult you local regulatory agency for additional requirements.
A Highly-Immune, Low-Emission Installation – Meeting the
Requirements of the Electromagnetic Compatibility (EMC)
Directive
The following information was compiled to aid the machine builder or
systems integrator in gaining EMC compliance. For effective control of
Conducted and Radiated Emissions, along with maximizing the Aries Drive’s
inherent noise immunity, the following recommendations should be followed.
A drawing of a typical EMC installation is shown below.
•
Mount the Drive and all components to a clean (not painted),
earthed, metal panel.
Important!
To reduce the risk of electrical noise entering your system you must
properly earth ground the enclosure, and remove all paint and other
non-conductive surface coatings from the panel mounting surface and
RF earth bonding locations.
If you mount the Aries drive in an equipment cabinet, terminate cable
braids (screens) at the entrance of the enclosure. This can be easily
accomplished using the “additional EMC installation hardware” shown
below.
The only exception is for the motor braid, which must return to the
drive’s R-Clamp (located on the bottom of the Aries drive. Do not return
the motor braid to any other location, its function is to return high-
frequency chopping current back to the drive. This may require
mounting the connector on a sub-panel insulated from the main cabinet,
or using a connector having an insulated internal screen from the
connector housing.
The shields of all other cables that enter or exit the enclosure must be
RF bonded to the enclosure entrance point using an R-Clamp, bulkhead
clamshell clamp, or other 360° bonding technique. This ensures that no
stray noise will enter or exit the enclosure. The following drawing
illustrates 360° bonding techniques.
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Figure 52 360° Bonding Techniques
All braid termination connections must remain secure. For small
diameter cables, it may be necessary to fold back the braid to increase
the effective diameter of the cable so that R-Clamps are secure.
Within the cabinet itself, all the motor cables should lie in the same
trunking as far as possible. Keep the cables separate from any low-level
control signal cables. This applies particularly where the control cables
are unscreened and run close to the drive.
There must be no break in the 360° coverage that the screen provides
around the cable conductors.
A steel equipment cabinet will screen radiated emissions provided all
panels are bonded to a central earth point. Separate earth circuits are
commonly used within equipment cabinets to minimize the interaction
between independent circuits. A circuit switching large currents and
sharing a common earth return with another low-level signal circuit could
conduct electrical noise into the low level circuit, thereby possibly
interfering with its operation. For this reason, so called ‘dirty earth’ and
‘clean earth’ circuits may be formed within the same cabinet, but all
such circuits will eventually need to be returned to the cabinet’s main
star earth point.
Mount the individual drives and EMC filter on a metal earth plane. The
earth plane will have its own individual star point earth that should be
hard wired (using an insulated copper conductor) back to the cabinet’s
‘clean earth’ connection point.
Panel mounting can provide a similar measure of EMC performance if
strict attention is paid to cable screen termination and cable layout.
Again, the machine builders primary focus should be on ensuring
operators are kept safe from all hazards.
•
Install a Mains filter. Aries drives require an EMC mains supply filter
to meet EMC emission requirements. It is recommended that the
drive is mounted on a conductive panel which is shared with the
EMC filters. If the panel has a paint finish, it will be necessary to
Appendix C Regulatory Compliance – UL and CE 193
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remove the paint in certain areas to ensure filters and drive make a
good large-area metal to metal contact between filter case and
panel.
You must install a filter on both the Motor power mains and Control
the correct filter for your specific application.
Control Power
Control power is 1 Amp, maximum. Any of the following filters works with all
models of the drive.
Filter
Manufacturer
Corcom
6EP1 (160937-5)
10EP1 (160937-7)1,
Corcom
FN2070-10/06
Schaffner
1. Available from Parker:
10 Amp filter—part number 47-016140-01
16 Amp filter—part number 47-017900-01
Table 60 Control Power Filter Selection
Mains Motor Power
Filter
Continuous
Current
AR-
01xx
AR-
02xx
AR-
04xx
AR-
08xx
AR-
13xx
AR-
20xE
AR-
30xE
(Amps)
6EP1 (160937-5)1
10EP1 (160937-7)1, 3
FN2070-10/062
FN2070-12/06
FN2070-16/062, 3
16FCD101
5 at 240 VAC
8 at 240 VAC
10 at 240 VAC
12 at 240 VAC
16 at 240 VAC
16 at 240 VAC
25 at 240 VAC
×
×
×
×
×
×
×
×
x
x
x
x
×
×
×
×
×
×
×
×
x
x
25FCD101
x
Product with applicable mains filter denoted by “×”
1. Corcom (a division of Tyco Electronics)
2. Schaffner
3. Available from Parker:
10 Amp filter—part number 47-016140-01
16 Amp filter—part number 47-017900-01
Table 61 Mains Motor Power Filter Selection
•
Install Transient suppressors.
Single Phase Input
You must install varistors or other voltage surge limiting devices in order
to meet the requirements of EN61000-4-5. Place a Littelfuse
V275LA2ØC, or an equivalent varistor, from line to line and from lines to
earth before the mains filter, as shown in the EMC Installation drawings.
(Intersil, General Electric, and Littelfuse manufacture equivalent
varistors.)
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Three Phase Input
Control Power – You must install varistors or other voltage surge limiting
devices in order to meet the requirements of EN61000-4-5. Level 3
Voltage Surge (1000V line-to-line, 2000V line-to-earth) protection can
be achieved by placing a Littelfuse V275LA20C, or an equivalent
varistors from line-to-line and from line-to-earth before the mains filter as
Mains Motor Power – The three-phase AC power Aries drives (models
AR-20xE and AR-30xE) are designed to meet Level 3 Voltage Surge
(1000V line-to-line, 2000V line-to-earth) without the need for external
voltage surge limiting devices. If a higher level of mains surge immunity
is required, external voltage sure limiting devices, such as varistors, can
be installed before the mains filter. Figure 54 Typical LVD/EMC
Note: Intersil, General Electric, and Littelfuse manufacture equivalent
varistors.
•
Use an EMC-ready motor or a motor that has demonstrated
acceptable EMC performance.
Motors with shielded cabling or pipe thread style cabling options allow
the easiest integration into machines required to bear the CE mark for
EMC.
Note: Motors may bear the CE mark. This mark indicates the motor
meets the requirements of construction and safety—not EMC
compliance.
•
Use shielded cabling with braided and bonded headshells.
Parker EMC cabling—requires no additional cable preparation.
All motor connections must be made using a high quality braided-screen
cable. Cables using a metalized plastic bandage for an earth screen are
unsuitable and in fact provide very little screening. Care must be taken
when terminating the cable screen, the screen itself is comparatively
fragile; bending it round a tight radius can seriously affect the screening
performance. The selected cable must have a temperature rating which
is adequate for the expected operating temperature of the motor case.
All cables must maintain high integrity 360 degree shielding. Parker CE
cables are fully shielded and provide the required screening. When you
install limit switches and other inputs/outputs, you must observe these
noise immunity procedures and practices.
•
Route cables as shown in Figure 53 Typical LVD/EMC Installation,
Route high power cables (motor and mains) at right angles to low power
cables (communications and inputs/outputs). Never route high and low
power cables parallel to each other.
Mount filters close to the drive and keep the supply wiring as short as
practical. Attempt to layout the wiring in a way that minimizes cross
coupling between filtered and non-filtered conductors. This means
avoiding running wires from the output of a filter close to those
connected to its input. Where you wish to minimize the cross coupling
between wires avoid running them side-by-side one another, if they
Appendix C Regulatory Compliance – UL and CE 195
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must cross, cross them at 90° to each other. Keep wiring supported and
close to cabinet metalwork.
•
Cables may require the use of ferrite core suppressors.
Some installations may require that you take additional EMC measures.
To further increase product immunity and reduce product emissions,
you may add clip-on ferrite absorbers to all cables. Parker recommends
ferrites with at least 200 ohm impedance at 100 MHz, such as the
following:
Steward Ferrite
Fair-Rite
Part number 28A2024
Part number 0443164151
Note:
These ferrites are available from Parker Hannifin, part number 47-015956-01.
For larger diameter cables (up to 0.722 in O.D.), Fair-Rite part number
0444176451 is recommended.
•
Your Installation may require additional EMC installation hardware
(as shown in illustrations).
The following clamp kits are available from Parker:
Clamp Type
Parker Part Number
R-Clamp Kit (10 per) for models
AR-02xx to AR-13xx
R CLAMP KIT
R-Clamp Kit (10 per) for models
AR-20xE and AR-30xE
R LARGE CLAMP KIT
CLAMSHELL KIT
Clamshell Clamp Kit (2 per)
for all models
Table 62 Enclosure Mounting Clamps
Note: The Control power input also requires a mains power line filter,
varistors, and fuses in order to comply with the relevant CE directives.
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Panel Installation, AR-02xx to AR-13xx
Figure 53 Typical LVD/EMC Installation, AR-02xx to AR-13xx
Warning — This product has been developed for industrial environments.
Due to exposed high voltage terminals, this product must not be accessible
to users while under normal operation.
Appendix C Regulatory Compliance – UL and CE 197
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Panel Installation, AR-20xE & AR-30xE
Aries models AR-20xE and AR-30xE require 240 VAC input power and
three-phase wiring.
Figure 54 Typical LVD/EMC Installation, AR-20xE & AR-30xE
Warning — This product has been developed for industrial environments.
Due to exposed high voltage terminals, this product must not be accessible
to users while under normal operation.
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Regulatory Agencies
The Aries family of products is designed to meet the requirements of global
regulatory agencies.
Aries products have shown compliance with the regulatory agencies in the
following list. The list also shows additional steps users must take to ensure
compliance.
Agency
UL,
Additional Steps User Must Take
Mains fuses
CE (LVD)
Mains fuses; earth connection for drive and motor (if
applicable), proper installation
CE (EMC)
Varistors, mains filter, EMC cabling, EMC ready motor,
proper installation
Table 63 Regulatory Agencies
Standards of Compliance
UL
508C
CE for LVD
72/23/EEC
BS EN 61010-1
(1993) including
Amendment A2.
Safety requirements for electrical
equipment for measurement,
control, and laboratory use. Part
1. General Requirements.
CE for EMC
89/336/EEC
BS EN 61800-3
(1997) including
Amendment A11
Adjustable speed electric power
drive systems Part 3. EMC
product standard including
specific test methods.
BS EN 50081-2
(1994)
Generic emission standard Part
2. Industrial Environment.
Electromagnetic
compatibility
BS EN 61000-6-2
(1999)
Immunity for industrial
environments.
Electromagnetic
compatibility Part 6-2:
Generic Standards
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Appendix E VM26 Expansion Module
A P P E N D I X E
VM26 Expansion
Module
IN THIS CHAPTER
Overview..................................................................................................204
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Overview
The VM26 expansion module provides screw-terminal connections for the
Drive I/O connectors on the Aries drive. The VM26 comes with a 2-foot cable
(609.6 mm) that provides easy connection between the VM26 module and
the drive’s 26-pin I/O connectors. The VM26 expansion module is ordered
separately (part number “VM26-PM”).
Notes
•
•
The VM26 module ships with DIN-rail mounting clips installed.
The overall cabinet depth with cable-bend radius is 5 inches (127 mm).
Figure 57 VM26 Breakout Module
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Index
120/240 VAC power input ..................................39, 47
absolute position, establishing
connector
brake relay......................................................... 50
effect on position report (TPE) ...........................151
accuracy ...............................................................169
address
multiple units (ADDR)..........................................95
encoder ..................................................................96
align encoder (ALIGN) .............................................96
amplifier ...............................................................169
analog input
control input power............................................. 47
drive I/O ............................................................ 66
locations of......................................................... 37
mains................................................................. 40
motor................................................................. 44
motor feedback .................................................. 62
motor feedback, resolver..................................... 65
motor output power............................................ 43
output power...................................................... 44
regeneration....................................................... 54
continuous current
ANI ........................................................... See ANI
analog input center deadband (ANICDB)...................97
ANI
check input voltage (TANI) ................................145
input resolution........................................... 71, 166
voltage status (TANI) ........................................145
wiring.................................................................69
auto-configure, smart encoder ......................... 33, 163
autorun........................................................... 72, 104
binary value identifier (b).........................................94
brake
brake relay .........................................................50
non-Parker motors ..............................................52
output delay (OUTBD) .......................................137
Parker motors .....................................................51
bus voltage, report (TVBUS)...................................153
cables
EMC .................................................................173
non-EMC...........................................................173
routing ....................................................... 31, 192
carriage return, command delimiters ........................94
case sensitivity........................................................94
CE
EMC ..................................................... 9, 190, 200
LVD...................................................... 9, 191, 200
center deadband (ANICDB)......................................97
change summary....................................12, 13, 14, 15
characters
derating, motor (DMTICD)................................. 106
motor (DMTIC)................................................. 106
control input power................................................. 40
connection ......................................................... 47
supply................................................................ 46
cooling
cabinet..........................................................23–27
drive .................................................................. 22
current foldback
enable/disable (DIFOLD)............................102, 173
overview .......................................................... 173
damping
servo
motor .......................................................... 105
DC link inductor ...................................................... 45
deadband (ANICDB)................................................ 97
debugging tools
error log (TERRLG) ........................................... 148
default command settings ....................................... 92
restore (RFS).................................................... 139
delimiters
command........................................................... 94
comment............................................................ 94
direction of rotation (CMDDIR) ................................ 98
drive
command delimiters ............................................94
comment delimiter ..............................................94
field separators ...................................................94
limit per line........................................................94
neutral (spaces)..................................................94
COM port........................................................ 75, 159
command offset (DCMDZ)......................................101
commands
command description format................................92
command-to-product compatibility .......................92
default settings ...................................................92
delimiters............................................................94
syntax ................................................................92
comment delimiters.................................................94
communication interface
bus voltage, status of (TVBUS).......................... 153
command offset, zero (DCMDZ)......................... 101
drive enable (DRIVE) ........................................ 125
incoming pulse scaling (DMPSCL)....................... 104
operating modes (DMODE)................................ 103
position error (SMPER)...................................... 143
temperature, status report (TDTEMP) ................ 148
velocity error (SMVER) ...................................... 144
resolution............................................................. 125
drive cooling........................................................... 22
drive dimensions..........................................28, 29, 30
drive dimensions, panel layout..........................31, 199
Drive Enable (DRIVE)............................................ 125
drive resolution (DRES) ......................................... 125
echo, communication ............................................ 126
echo enable ......................................................126
communications
RS-232/485.........................................................74
configuration
electrical pitch (DMEPIT)
....................................... 103
EMC................................................................33, 200
EMC installation .............................................197, 198
enable input
errors (CONFIG)..................................................99
warnings (CONFIG) .............................................99
error checking (ERROR) .................................... 129
wiring ................................................................ 69
configuration error, motor (DMTR) .........................
112
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encoder
auto-configure (smart)................................. 33, 163
inrush current......................................................... 42
installation
LVD/EMC...................................................197, 198
installation category................................................ 22
installation, overview....................................35, 36, 37
jumper wires, pre-installed ................................ 35, 37
lead/lag filters
lag................................................................... 123
lead ................................................................. 122
LEDs ...............................................................56, 158
line feed, command delimiters ................................. 94
linear motor pitch (DMEPIT) .................................. 103
LVD.............................................................9, 33, 200
LVD installation..............................................197, 198
mass, forcer ......................................................... 109
memory
input resolution (ERES)......................................128
position commanded (TPC)................................151
position report (TPE) .........................................151
position report error (TPER)...............................151
resolution (ERES) ..............................................128
encoder offset.......................................................127
environment............................................................22
epitch (DMEPIT)....................................................103
error
clear log (CERRLG)..............................................98
display log contents (TERRLG) ...........................148
error checking enable (ERROR)..........................129
error log setup (ERRORL) ..................................131
error messages ........................................... 159–63
European Conformance Statement ............................ 9
External DC link inductor..........................................45
factory default settings, restore (RFS).....................139
faults
after a reset (RESET)........................................ 138
return to factory settings (RFS) ......................... 139
motor
ambient temperature (DMTAMB) ....................... 105
auto-configure.................................................. 112
brake ................................................................. 50
configuration error (DMTR, CONFIG).................. 112
connector........................................................... 59
continuous current (DMTIC) .............................. 106
continuous current derating (DMTICD)............... 106
damping........................................................... 105
drift, minimizing (DCMDZ)................................. 101
full wave rectifiers............................................... 51
fuses, input power........................................ 41, 42
input power.................................................. 39, 40
linear motor pitch (DMEPIT).............................. 103
output power...................................................... 43
output power, connection.................................... 44
peak current (DMTIP) ....................................... 108
pole pairs (DPOLE)............................................ 124
rated speed (DMTW)......................................... 117
rotor inertia...................................................... 109
selection recorded (DMTR)................................ 112
temperature report (TMTEMP)........................... 150
thermal time constant (DMTTCM) ...................... 116
voltage constant (Ke) (DMTKE).......................... 110
winding resistance (DMTRES)............................ 114
winding temperature, max. (DMTMAX)............... 112
winding thermal resistance (DMTRWC) .............. 114
winding time constant (DMTTCW)...................... 117
motor inductance
max (DMTIND)................................................. 107
min (DMTINF) .................................................. 108
motor temperature switch type (DMTSWT)............. 116
multiple drives........................................................ 48
multiple unit address............................................... 95
multiple unit wiring ................................................. 76
neutral characters................................................... 94
notch filter A
depth............................................................... 119
frequency......................................................... 120
quality factor.................................................... 121
notch filter B
fault on drive disable (FLTDSB)..........................133
fault on excessive startup voltage (FLTSTP)........133
motor configuration error (DMTR, CONFIG) .. 98, 112
thermal switch (DTHERM)..................................126
feedback...............................................................169
filters, AC mains....................................................194
foldback................................................................102
foldback (DIFOLD).................................................173
force
actual, status (TTRQA) ......................................153
commanded, status (TTRQ)...............................153
limit (DMTLIM)..................................................111
scaling (DMTSCL)..............................................115
forcer
mass ................................................................109
fuses ................................................................41, 42
gains
current loop, auto (IAUTO) ................................134
integral (IGAIN) ................................................134
integral (SGI)....................................................140
integral (SGILIM) ..............................................140
notch filter A depth (DNOTAD)...........................119
notch filter A frequency (DNOTAF) .....................120
notch filter A quality factor (DNOTAQ)................121
notch filter B depth (DNOTBD)...........................121
notch filter B frequency (DNOTBF) .....................122
notch filter B quality factor (DNOTBQ)................122
notch lag filter break freq (DNOTLG) ..................123
notch lead filter break freq (DNOTLD) ................122
proportional (PGAIN).........................................138
proportional (SGP).............................................141
set current loop bandwidth (DIBW) ....................101
System Load-to-Rotor Inertia Ratio (LJRAT)........135
torque/force limit (DMTLIM)...............................111
velocity (SGV) ...................................................141
velocity feedforward (SGVF)...............................142
velocity limit (DMVLIM)......................................118
hall sensor
check sensor values (THALL) .............................149
configuration/inversion (SHALL) .........................143
troubleshooting.................................................164
hexadecimal value identifier (h)................................94
Incoming Pulse Scaling (DMPSCL) ..........................104
inductance
motor max (DMTIND)........................................107
motor min (DMTINF).........................................108
input resolution, analog .........................................169
depth............................................................... 121
frequency......................................................... 122
quality factor.................................................... 122
notch lag filter break frequency ............................. 123
notch lead filter break frequency............................ 122
offset
zero command offset (DCMDZ).......................... 101
offset, encoder (ENCOFF)...................................... 127
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operating hours, report (TDHRS)............................146
RS-232
communications.................................................. 75
dongle ............................................................... 77
wiring ................................................................ 74
RS-232/485
connector........................................................... 74
troubleshooting ................................................ 159
wiring .......................................................... 74, 75
RS-485
communications.................................................. 75
dongle ............................................................... 77
multi-drop network ............................................. 76
wiring .......................................................... 74, 75
scaling
operating hours, report (TDMIN)............................147
operating hours, report (TDSEC) ............................147
operating modes, drive (DMODE) ...........................103
operating system revision (TREV)...........................152
output power ..........................................................43
outputs
status (TOUT)...................................................150
override mode.......................................................119
over-temperature limits..........................................170
over-voltage protection..........................................172
peak current, motor (DMTIP) .................................108
performance .........................................................169
pole pairs, motor (DPOLE) .....................................124
pollution degree ......................................................22
position
actual (TPE)......................................................151
actual error(TPC)...............................................151
commanded (TPC) ............................................151
encoder (TPE)...................................................151
encoder error (TPER).........................................151
tracking ............................................................142
power dissipation .............................................. 23–27
power supply
connection..........................................................40
fuses ............................................................41, 42
input power .................................35, 37, 39, 40, 46
power-dump resistor
calculating for linear motor ................................183
calculating for rotary motor................................177
selection................................................... 175, 176
product revision (command implementation).............92
product revision (TREV).........................................152
program
comments...........................................................94
reset, effect of ..................................................138
protection
current foldback (DIFOLD)......................... 102, 173
drive over-temperature......................................170
over-voltage......................................................172
short circuit.......................................................170
under-voltage ...................................................171
PWM frequency (dpwm) ........................................169
PWM frequency (DPWM)........................................124
PWM update period (TSSPD)..................................152
rated speed, motor (DMTW) ..................................117
regeneration .................................... 54, 172, 175, 176
regulatory agencies ...............................................200
relay
force command................................................. 115
torque command (DMTSCL) .............................. 115
velocity command............................................. 119
velocity command (DMVSCL)............................. 119
servo
position tracking ............................................... 142
servo tuning
actual position.................................................... 80
auto-tuning ........................................................ 90
closed loop......................................................... 79
commanded position........................................... 80
current loop gains, auto .................................... 134
inertia ratio (LJRAT).......................................... 135
integral feedback................................................ 83
integral gain (IGAIN)......................................... 134
integral gain (SGI)............................................ 140
integral gain limit (SGILIM) ............................... 140
measuring performance ...................................... 82
notch filter A depth (DNOTAD) .......................... 119
notch filter A frequency (DNOTAF)..................... 120
notch filter A quality factor (DNOTAQ) ............... 121
notch filter B depth (DNOTBD) .......................... 121
notch filter B frequency (DNOTBF)..................... 122
notch filter B quality factor (DNOTBQ) ............... 122
notch lag filter break freq (DNOTLG).................. 123
notch lead filter break freq (DNOTLD)................ 122
open loop........................................................... 79
overv
iew ............................................................ 79
position error (SMPER)...................................... 143
position respones................................................ 81
position variables................................................ 80
proportional feedback ......................................... 83
proportional gain (PGAIN) ................................. 138
proportional gain (SGP)..................................... 141
set current loop bandwidth................................ 101
stability.............................................................. 81
torque/force limit (DMTLIM).............................. 111
tuning example................................................... 86
velocity error (SMVER) ...................................... 144
velocity feedback................................................ 83
velocity feedforward gain (SGVF)....................... 142
velocity gain (SGV) ........................................... 141
velocity limit (DMVLIM) ..................................... 118
windup............................................................... 84
servo update ........................................................ 169
ship kit................................................................... 19
short circuit protection .......................................... 170
software revision level (TREV) ............................... 152
space (neutral character)......................................... 94
brake relay .........................................................50
relay, brake
operation............................................................53
output delay (OUTBD) .......................................137
output status (TOUT) ........................................150
specification........................................................53
reset,drive (RESET) ...............................................138
resistor, power-dump............. See power-dump resistor
resolution
encoder (ERES).................................................128
encoder input (ERES) ........................................128
resolver ................................................................169
return to factory settings (RFS) ..............................139
revision level, operating system (TREV) ..................152
revision of this manual............................12, 13, 14, 15
rotor inertia, motor................................................109
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specifications
drive temperature (TDTEMP)............................. 148
error log (TERRLG) ........................................... 148
hall sensor values (THALL) ................................ 149
maximum current rating (TDIMAX) .................... 147
motor temperature (TMTEMP)........................... 150
operating hours (TDHRS) .................................. 146
operating milliseconds (TDSEC) ......................... 147
operating minutes (TDMIN)............................... 147
output status (TOUT)........................................ 150
position commanded (TPC) ............................... 151
position of encoder (TPE).................................. 151
position of encoder error (TPER)........................ 151
PWM update period (TSSPD) ............................. 152
q quadrature current (TCI)................................ 149
revision level (TREV)......................................... 152
transient suppressors............................................ 194
troubleshooting..................................................... 156
configuration (CONFIG)....................................... 99
ERROR command (ERROR) ............................... 129
error log (TERRLG) ........................................... 148
error messages............................................159–63
general ............................................................ 157
hall sensors...............................................149, 164
LEDs................................................................ 157
tuning ............................................... See servo tuning
UL200
under-voltage protection ....................................... 171
units of measurement ............................................. 92
linear motors.................................................... 103
varistors............................................................... 194
velocity
actual (feedback device) (TVELA) ...................... 154
actual commanded (feedback device) (TVEL) ..... 154
error (feedback device) (TVER).......................... 155
feedforward gain (SGVF)................................... 142
limit (DMVLIM) ................................................. 118
scaling (DMVSCL) ............................................. 119
Velocity mode
additional specifications.....................................169
drive I/O connector .............................................66
input power connector.........................................57
mains connector..................................................57
motor connector..................................................59
motor feedback connector .............................62, 66
motor feedback, resolver .....................................65
standards..........................................................9, 200
status
commanded position (TPC)................................151
commanded velocity, feedback device (TVEL).....154
encoder position (TPE) ......................................151
encoder position error (TPC)..............................151
error log (TERRLG)............................................148
full text report (STATUS) ...................................145
outputs (TOUT).................................................150
software revision level (TREV)............................152
velocity, feedback device (TVELA)......................154
velocity, feedback device error (TVER)................155
voltage input for ANI (TANI)..............................145
switch type, motor (DMTSWT) ...............................116
motor ...................................................................116
syntax, command........................................ 92, 93, 94
technical support...................................................... 2
temperature............................................................23
drive status (TDTEMP).......................................148
environment .......................................................22
limits ................................................................170
motor status (TMTEMP).....................................150
motor winding (DMTMAX)..................................112
motor—ambient (DTAMB)..................................105
thermal switch (DTHERM)......................................126
thermal time constant, motor (DMTTCM)................116
torque
actual, status (TTRQA) ......................................153
commanded, status (TTRQ)...............................153
limit (DMTLIM)..................................................111
scaling (DMTSCL)..............................................115
tranformation ratio ................................................169
transfer
actual torque/force (TTRQA)..............................153
actual velocity (TVELA)......................................154
analog input voltage, ANI (TANI) .......................
bus voltage (TVBUS) .........................................153
commanded current (TCI) .................................146
commanded torque/force (TTRQ).......................153
commanded velocity (TVEL)...............................154
commanded velocity error (TVER)......................155
continuous current rating (TDICNT)....................146
d quadrature current (TCI) ................................149
maximum acceleration (SMAV) .......................... 143
voltage
AC input............................................................. 39
ANI input (TANI) .............................................. 145
constant (Ke) of motor (DMTKE)........................ 110
weight.................................................................... 30
winding
resistance, motor (DMTRES).............................. 114
temperature, max. (DMTMAX)........................... 112
thermal resistance, motor (DMTRWC) ................ 114
time constant, motor (DMTTCW) ....................... 117
zero command offset (DCMDZ).............................. 101
145
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