Omega Riding Toy LTU 101 User Manual

Where Do I Find Everything I Need for

Process Measurement and Control?

OMEGA…Of Course!

User’s Guide

TEMPERATURE

Ⅺ

Thermocouple, RTD & Thermistor Probes,

Connectors, Panels & Assemblies

Wire: Thermocouple, RTD & Thermistor

Calibrators & Ice Point References

Recorders, Controllers & Process Monitors

Infrared Pyrometers

Ⅺ

PRESSURE, STRAIN AND FORCE

Ⅺ

Transducers & Strain Gauges

Load Cells & Pressure Gauges

Displacement Transducers

Instrumentation & Accessories

“

FLOW/LEVEL

Ⅺ

Rotameters, Gas Mass Flowmeters & Flow Computers

Air Velocity Indicators

Turbine/Paddlewheel Systems

http://www.omega.com

e-mail: [email protected]

Totalizers & Batch Controllers

pH/CONDUCTIVITY

Ⅺ

pH Electrodes, Testers & Accessories

Benchtop/Laboratory Meters

Controllers, Calibrators, Simulators & Pumps

Industrial pH & Conductivity Equipment

DATA ACQUISITION

Ⅺ

Data Acquisition & Engineering Software

Communications-Based Acquisition Systems

Plug-in Cards for Apple, IBM & Compatibles

Datalogging Systems

Recorders, Printers & Plotters

HEATERS

Ⅺ

Heating Cable

NRTL/C

Cartridge & Strip Heaters

Immersion & Band Heaters

Flexible Heaters

LTU-101, LVU-150, LVC-152

LVC-100 & LVF-210 Series

Powered Level Switch

Laboratory Heaters

ENVIRONMENTAL

MONITORING AND CONTROL

Ⅺ

Metering & Control Instrumentation

Refractometers

Pumps & Tubing

Air, Soil & Water Monitors

Industrial Water & Wastewater Treatment

pH, Conductivity & Dissolved Oxygen Instruments

M-3949/0403

T h e s e p r o d u W c t A s R a N r e I N n G o t : d e s i g n e d f o r u s e i n , a n d s h o u l d n o t b e u s e d f o r , h u m a n a p p l i c a t i o n s .

a n , s d n i r e a t s n e o r v c e s t h e r i g h t t o a l t e r s p e c i f i c a t i o n s w i t h o u t n o t i c e .

w i t h o u t t h e p r i o

r e d o u r c e d t o a n y t r a e n l e s c l a t r t o e n d i , c m r e e p d r i o u d m u c c o o e r p d m i , e a d c , h i n e - r e a d

e r r o r s i t

T h e i n f o r m a t i o n c o n t a i n e d i n t h i s d o c u m e n t i s b e l i e v e d t o b e c o r r e c t , b u t O M E G A E n g i n e e r i n g , I n c . a c c e p t s n o l i a b i l i t y f o r a n y

a d d t h e C E m a r k t o e v e r y a p p r o p r i a t e d e v i c e u p o n c e r t i f i c a t i o n .

i s c o n s t a n t l y p u r s u i n g c e r t i f i c a t i o n o f i t s p r o d u c t s t o t h e E u r o p e a n N e w A p p r o a c h D i r e c t i v e s . O M E G A w i l l

I t i s t h e p o l i c y o f O M E G A t o c o m p l y w i t h a l l w o r l d w i d e s a f e t y a n d E M C / E M I r e g u l a t i o n s t h a t a p p l y

O M E G A i s a r e

. O M E G A

T h i s a f f o r d s o u

p s ’ o l i c y i s O t o M m E G a k A e r u n n i

e - m a i l : s a l e s @ o m e g a . f r

e - m a i l : s a l e s @ o m e g a . c o . u k

0 8 0 0 - 4 8 8 - 4 8 8

e e i n o U T l n l F i t r e d K i n g d o m :

r e l a t i v e t o t h e p r o d

R e p 3 a . i r i n s t r u c t i o n s

w a r r a n t y

M . o 2 d e l a n d s e r i a l n u

w a s P U R C H A S E D ,

P u r 1 c . h a s e O r d e r n u

e e i n o F T l r l a F n r c e : 0 8 0 0 4 6 6 3 4 2

A X : + 3 3 ( 0 ) 1 3 0 5 7 5 4 2 7 l : e + T 3 3 ( 0 ) 1 6 1 3 7 2 9 0 0

7 8 2 8 0 G u y a n c o u r t , F r a n c e

e u J a c 1 q 1 , u r e s C a r t i e r

r e l a t i v e t o t h e p r o d u c t .

R e p 3 a . i r i n s t r u c t i o n s a n d / o r s p e c i f i c p r o b l e m s

, a n d

M o 2 d . e l a n d s e r i a l n u m b e r o f t h e p r o d u c t , a n d

o f t h e r e p a i r

d r e r O n u m b e r . P t o 1 u r c h o a v s e r t h e C O S T

A F X : + 4 4 ( 0 ) 1 6 1 7 7 7 6 6 2 2

l : e + T 4 4 ( 0 ) 1 6 1 7 7 7 6 6 1

U n i t e d K i n g d o m

F r a n c e :

O M E G A :

f o l l o w i n g i n f o r m

R E T U R N S , p A l e R W a R s e A h N F a O T v R Y e t h e

M a n c h e s t e r M 4 4 5 B D

N o r t h b a n k , I r l a m

e c h n o l o g y C e R n i t v r e r B e n d T

O n e O m e g a D r i v e

l o w i n g i n f o r m a t i o n a v a i l a b l e B E F O R E c o n t a c t i n g

O M E G A f o r c u r r e n t r e p a i r c h a r g e s . H a v e t h e f o l -

e - m a i l : i n f o @ o m e g a s h o p . c z

e e : 0 8 o 0 T l 0 l - F 1 r - 6 6 3 4 2

4 2 + 0 : X ( 0 A ) F 5 9 6 3

4 2 + 0 : l ( e 0 T ) 5 9 6 3 1

c o n s u A l t I R S R , E P

A R R A N N T Y O N F - W O R

1 1 1 1

1 8 9 9

t o p r e v e n t b r e a k

T h e p u r c h a s e r i s r e s p o n a s n i b y l e c o f o r r r e s s h p i p o p n i d n

Y S ) . T D h E e L a A s s i g n e d A

t i f i e d

I S O 9 0 0 2 C e r

U n i t e d K i n g d o m :

´ , C z e c h R e p u b l i c

F r y s t a t s k a 1 8 4 / 4 6 , 7 3 3 0 1 K a r v i n a

C z e c h R e p u b l i c :

V O I D P R O C E S S I N G

T M A E R N T ( I N V O I R C D E E D R E T P O

A I N A N A U T H O R I Z E D R E T U R N ( A R )

’ S C U S T O M E R S E R

N U M B E R F R O M

e - m a i l : i n f o @ o m e g a . d e

e e i n o G T l e l r F m r a n y : 0 8 0 0 6 3 9 7 6 7 8

A F X : + 4 9 ( 0 ) 7 0 5 6 9 3 9 8 - 2 9

l : e + T 4 9 ( 0 ) 7 0 5 6 9 3 9 8 - 0

o n n , G e r m D a n e y c k e n p f r

D a i m l e r s t r a s s e 2 6 , D - 7 5 3 9 2

A N Y P R O D U C R T E ( T S U ) R T N O I N O G M E G

e - m a i l : s a l e s @ o m e g a e n g . n l

e e i n o B T l e l n F e r l u x : 0 8 0 0 0 9 9 3 3 4 4

D i r e c t a l l w a r r a

I N / Q U I R I E S

R E T U R N R E Q U E S T S

A X : + 3 1 ( 0 ) 2 0 6 4 3 4 6 4 3 l : e + T 3 1 ( 0 ) 2 0 3 4 7 2 1 2 1

s u c h a m a n n e r

h o l d O M E G A h a

T h e N e t h e r l a n d s

P o s t b u s 8 0 3 4 , 1

B e n e l u x :

A m s t e l v 1 e 8 e 0 n L A

, p u r c h a s e r w i l l i n d e m n i f y O M E G A a n d D / I S C L A I M E A R R l R a n A g N u T a Y g e , a n i n d , o a u d r d b i t a i o s n i c a l W l y

G e r m a n y / A u s t r i a :

, O M E G A a s s u m e s n o r e s p o n s i b i l i t y a s s e t f o r t h

m e d i c a l a p p l i c a

a p p l i c a t i o n s o r u

C o m p o n e n t ” u n

C O N D I T I O N S : E

n o e v e n t s h a l l

o t h e r w i s e , s h a

S e r v i c i n g E u r o p e :

C A B L E : O M E G A

i n f o @ o m e g a . c o m . m x

e - m a i l : e s p a n o l @ o m e g a . c o 1 m / - 8 0 0 - U S A - W H E N

T E L E X : 9 9 6 4 0 4 E A S Y L I N K : 6 2 9 6 8 9 3 4

E n g i n e e r i n g S e r v i c e : 1 - 8 0 0 - 8 7 2 - 9 4 3 6

C u s t o m e r S e r v i c e : 1 - 8 0 0 - 6 2 2 - 2 3 7 8

S a l e s S e r v i c e : 1 - 8 0 0 - 8 2 6 - 6 3 4 2

, n e g l i g e n c e , i n d e m n i f i c a t i o n , s t r i c t l i a b , i w l i h t y e t o o h r r e d r e b r a s e d o n

p u r c h a s e r s e t

A F X : ( 0 0 1 ) 2 0 3 - 3 5 9 - 7 8 0 7

1 / - 8 0 0 - 6 2 2 - B E S T

1 / - 8 0 0 - T C - O M E G A

: T h e r e m e d i e s o f T I A O N O F L I A B I L I T Y

I C T U R L A A P R P U R P O S E

A R W R A N T I E S I N

o l : ( 0 0 1 ) 2 E 0 n 3 - 3 E 5 s 9 p - a 7 n 8 0 3

A B I L I T Y A N D F I T N E S S F O A R R A R A N T Y O F M E R C H A N T

M e x i c o :

a n d C U a S n A a d a :

T O F T I T L E , A N D A L L I M P L I E D

A R R A N T I E S O R R E P R E S E N T

T S O E V E R , E X P R E S S O F O R A N I M Y P K L I N E D D ,

s p e c i f i e d a n d

F o r i m m e d i a t e t e c h n i c a ^Il ^{O T}o ^{N A}r ^Sa p p l i c a t i o n a s s i s t a n c e :

e i t h e r v e r b a l

t h a t r e s u l t f r o

e - m a i l : i n f o @ o m e g a . c o m

A F X : ( 2 0 3 ) 3 5 9 - 7 7 0 0

e l T : ( 2 0 3 ) 3 5 9 - 1 6 6 0

e - m a i l : i n f o @ o m e g a . c a

A F X : ( 5 1 4 ) 8 5 6 - 6 8 8 6

e l T : ( 5 1 4 ) 8 5 6 - 6 9 2 8

L a v a l ( Q u e b e c ) H 7 L

9 7 6 B e r

n e i t h e r a s s u m

, O M E G A

O M E G A i s p l e

C o m p o n e n t s w h

t i o n ; i m p r o p e r s

s h o w s e v i d e n c e

c s ’ o n t r o l .

d C T 0 6 9 S 0 t a 7 m - 0 f 0 o 4 r 7

O n e O m e g a D r i v e , B o x 4 0 4 7

I S O 9 0 U 0 1 S A C : e r

5 A 1 , C a n a d a

A R R A N T Y i s V O I D i f t h e u r n i z i e t d s h m o w o d s i f e i c v a i d t i e

l i m i t e d t o m i s h a

g a r

, o r u n a u t h o -

, i n c l u d i n g b u t n o t

t i f i e d

C a n a d a :

A R R W s ’ A N T Y d O o e M s E n G o A t a p p l y t o

e x a m i n a t i o n b y

t h A m e r i c a v : i c i S n e g r N o r

D e p a r t m e n t w i l l

s C ’ u s t o m e r S e r v i c e

I f t h e u n i t m a l f

i n f o @ o m e g a . c o m

. o m e g w a w . c o w m

O M E G A n e t

c s ’ u s t o m e r O s M r e E c G e i A v e m a x i m

t o c o v e r h a n d l i n g a n d s h i p p i n g t i m o e n . e T h ( 1 i s ) e y n e s a u r r e p t s o r t o h t h d a e u t c n t o r w m a a r l r a

r r a a n t W y s ’ a d d s a n a d d i t i o n a l o n e ( 1 ) m o n f r t o h m g r d a a c t e e p o e f r 1 p i o 3 u d r m c h o o a n d s e t o h . f O s M E G A

O M E G A E N G I N

e - m a i l I n t e r n e t

e c i v r e S e n i L - n O _®

S A U

D / I S C L A I M E A R R W R A N T Y

I N

M A D

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DIMENSIONS

Step Two

Vibration Level Switch, LTU-101 series

3/4" NPT (3/4" Rp)

3/4" NPT (3/4" G)

10’ Cable (3m)

2.3"(57mm)

3.0"(76mm)

4.7"(120mm)

Ultrasonic Level Switch, LVU-150 series

3/4" NPT (3/4" Rp)

3/4" NPT (3/4" G)

3/4" NPT (3/4" Rp)

10’ Cable (3m)

0.7"

2.1"(54mm)

2.8"(71mm)

4.5"(114mm)

(19mm)

1.3"(32mm)

3.0"(76mm)

SuperGuard RF Capacitance Level Switch, LVC-152 series

3/4" NPT (3/4" Rp)

3/4" NPT (3/4" G)

10’ Cable (3m)

2.6"(67mm)

3.3"(83mm)

5.0"(127mm)

Intrusive RF Capacitance Level Switch, LVC-100 series

3/4" NPT (3/4" Rp)

3/4" NPT (3/4" G)

3/4" NPT (3/4" Rp)

10’ Cable (3m)

2.1"(54mm)

2.8"(70mm)

0.7"

(19mm)

1.3"(32mm)

4.5"(114mm)

3.0"(76mm)

Optic Leak Detection Switch, LVF-210 series

3/4" NPT (3/4" Rp)

3/4" NPT (3/4" G)

10’ Cable (3m)

0.7"

2.1"(54mm)

2.8"(71mm)

4.5"(114mm)

(19mm)

1.3"(32mm)

3.0"(76mm)

* all dimensions are Nominal

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SAFETY PRECAUTIONS

INTRODUCTION

Step Three

Step Four

About this Manual:

Vibration Switch:

PLEASE READ THE ENTIRE MANUAL PRIOR TO

INSTALLING OR USING THIS PRODUCT. This manual

includes information on all models of Omega’s powered level

switches: LTU-101 series, LVU-150 series, LVC-152 series, LVC-

100 series and LVF-210 series. Please refer to the part number

located on the switch label to verify the exact model which you

have purchased.

The Tuning Fork vibration switch operates at a nominal frequency of

400 Hz. As the switch becomes immersed in a liquid or slurry, a cor-

responding frequency shift occurs. When the measured frequency

shift reaches the set point value, the switch changes state indicating

the presence of a liquid or slurry medium.

Do not squeeze the forks together. Doing so could damage or

break the sensor and void the warranty.

User’s Responsibility for Safety:

When powering up the LTU-101 series, the start-up procedure

requires the switch to cycle through a wet condition for 1/2 second in

order to determine an initial resonance.

Omega manufactures a wide range of liquid level sensors and tech-

nologies. While each of these sensors is designed to operate in a

wide variety of applications, it is the user’s responsibility to select

a sensor model that is appropriate for the application, install it

properly, perform tests of the installed system, and maintain all

components. The failure to do so could result in property damage

or serious injury.

Ultrasonic Switch:

The Ultrasonic level switch generates a 1.5 MHz ultrasonic wave

from a miniature piezoelectric transducer located on one side of the

gap in its sensing tip. Another piezo transducer located on the other

side of the gap acts as a microphone, picking up the sound. When liq-

uid enters the gap in the sensing tip, the audio level changes.

Proper Installation and Handling:

Because this is an electrically operated device, only properly-

trained staff should install and/or repair this product. Use a proper

sealant with all installations. Never overtighten the sensor within

the fitting, beyond a maximum of 80 inch-pounds torque. Always

check for leaks prior to system start-up.

The sensor should be installed so that the liquid will drip out of

the gap when the sensor becomes dry.

Optic Switch:

Material Compatibility:

The Optic Leak Detector use principles of optical refraction to detect

the presence or absence of fluid. A pulsed infrared light beam is inter-

nally generated by a light emitting diode and aimed at the slanted

optical tip of the sensor. If the tip is dry, the light beam bounces at a

90 degree angle to a receiving photo transistor, indicating a dry con-

dition. If the tip is immersed in liquid, the light beam will refract out

into the liquid instead of being reflected to the photo transistor, indi-

cating a wet condition.

The LVU-150, LVC-100 and LVF-210 series sensors are available

in two different wetted materials. Models LVU-150/-152, LVC-

101/-103 and LVF-210/-212 are made of Polypropylene(PP).

Models LVU-151/-153, LVC-102/-104 and LVF-211/-213 are

made of Perfluoroalkoxy(PFA), also known by the trade name

Teflon. The LTU-101 series is made of PP with the forks made of

Ryton (40% glass filled) and the LVC-152 series is made of PP.

Make sure that the model you have selected is compatible with the

application liquid. To determine the chemical compatibility

between the sensor and its application liquids, refer to an industry

reference.

The Optic Leak Detector can not detect the presence or

absence of specular application liquids that reflect light (such

as milk), or viscous liquids (such as paint) that form a coating

on the sensor tip.

Wiring and Electrical:

The supply voltage used to power the sensor should never exceed

a maximum of 36 volts DC. Electrical wiring of the sensor should

be performed in accordance with all applicable national, state, and

local codes.

SuperGuard Capacitance Switch:

The SuperGuard level switch generates a pulse-wave radio frequency

signal from the capacitance electrode located in the sensing tip of

each sensor. When liquid comes into contact with the sensing tip, the

capacitance as measured by the sensor changes based on the dielec-

tric constant of the liquid. The guard circuit rejects the negative

effects of coating buildup on the probe by eliminating the coating sig-

nal path between the active and reference electrodes.

Flammable, Explosive and Hazardous Applications:

DO NOT USE THE LTU-101, LVU-150, LVC-152, LVC-100 OR

LVF-210 SERIES GENERAL PURPOSE SWITCH IN HAZ-

ARDOUS LOCATIONS.

Intrusive RF Capacitance Switch:

WARNING

The Intrusive RF Capacitance level switch generates a 300 kHz pulse-

wave radio frequency signal from the capacitance electrode located in

the sensing tip of each sensor. When liquid comes into contact with

the sensing tip, the capacitance as measured by the sensor changes

based on the dielectric constant of the liquid.

The rating for the relay is 120 VAC/60 VDC @ 1A. For CE

rated applications, the relay rating is 60 VAC/60 VDC @ 1A.

Omega’s powered level switches are not recommended for use

with electrically charged application liquids. For most reliable

operation, the liquid being measured may need to be electrical-

ly grounded.

The sensor’s operation may vary based on the dielectric prop-

erties of various application liquids. The LVC-152 series &

LVC-100 series sensor is factory-calibrated to be used with liq-

uids with a dielectric value between 20 and 80.

Liquids with a dielectric constant less than 20 will not

be detected by an LVC-152 series & LVC-100 series sen-

sor, as factory calibrated.

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INSTALLATION

ELECTRICAL

Step Five

Step Six

Supply Voltage:

Through Wall Installation:

The supply voltage to the powered level switch should never exceed

a maximum of 36 VDC. Omega controllers have a built-in 13.5 VDC

power supply which provides power to all of Omega’s electrically

powered sensors. Alternative controllers and power supplies, with a

minimum output of 12 VDC up to a maximum output of 36 VDC,

may also be used with the powered level switch.

Omega’s powered level switches may be installed through the top,

side or bottom of a tank wall. The sensor has male 3/4" NPT threads

on either side of a 15/16" wrench flat. This enables the user to select

the sensor’s mounting orientation, installed outside of the tank in, or

inside of the tank out.

Required Cable Length:

Determine the length of cable required between the powered level

switch and its point of termination. Allow enough slack to ensure the

easy installation, removal and/or maintenance of the sensor. The

cable length may be extended up to a maximum of 1000 feet, using a

well-insulated, 14 to 20 gauge shielded four conductor cable.

Wire Stripping:

Using a 10 gauge wire stripper, carefully remove the outer layer of

insulation from the last 1-1/4" of the sensor's cable. Unwrap and dis-

card the exposed foil shield from around the signal wires, leaving the

drain wire attached if desired. With a 20 gauge wire stripper, remove

the last 1/4" of the colored insulation from the signal wires.

Multi-Point Installation:

Omega’s LVM-10 series mounting system is an in-tank fitting which

enables users to install up to four OMEGA sensors of any technology,

to any depth, along the entire length of track. LVM-10 series may be

installed through the top wall of any tank using a standard 2" NPT

tank adapter. If no tank top installation is available, Omega's side

mount bracket, LVM-30, enables LVM-10 series to be installed

directly to the side wall of a tank.

Signal Outputs (Current sensing):

The standard method used by Omega controllers; this technology uses

only two wires (Red and Black). The sensor draws 5 mA when it is dry,

and 19 mA when wet. NC/NO status must be set by the controller. The

White and Green wires are not used.

Single-Point Installation:

Omega’s LVM-50 series mounting system is an in-tank fitting which

enables users to install one OMEGA sensor, of any technology, to a

specific depth. The Omega sensor may be installed onto the 3/4" NPT

adapter at the end of the LVM-50 series. LVM-50 series may be

installed through the top wall of any tank using a standard 2" NPT

tank adapter. Omega's side mount bracket, model LVM-30, may also

be used if top wall installation is not available.

Signal Output (Relay switching):

Allows the sensor to switch a small load on or off directly, using an

internal 1A relay (60 VAC/60 VDC). Omega’s powered level switch-

es features 4 wires (red, black, white and green) and a shield wire. The

NO/NC status is set by the polarity of the voltage feeding the red and

black wires. The green wire is the common for the relay and the white

wire is the NO or NC, depending on the polarity of red and black.

Normally Open Wiring:

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WIRING

Step Seven

Step Eight

Wiring to a Omega Controller:

LVCN-110 Series Controller

(4 or 20 mA signal output)

Wiring the Relay Output:

The relay output can be wired as a dry contact to a VDC or VAC

power source. Powered level switch does require 12 - 36 VDC power

to operate the sensor and switch the relay. All illustrations below

identify a Dry switch state as the normal position of the relay.

Switching a Normally Open DC Load:

The Red wire connects to Positive (+) of the power supply and the

Black wire connects to Negative (-). The LOAD can be attached to

either the Green or White wires. Complete the circuit by either con-

necting the Green to (+) VDC power or White to (-) VDC power (see

illustration below).

[Dry Condition]

LCVN-120/-130/-140 Series Controller

(4 or 20 mA signal output)

[+]

RED

GRN

SHLD

WHT

BLK

LOAD

Sensor

(NO)

[-]

Switching a Normally Closed DC Load:

The Black wire connects to Positive (+) of the power supply and the

Red wire connects to Negative (-). The LOAD can be attached to

either the Green or White wires. Complete the circuit by either con-

necting the Green to (+) VDC power or White to (-) VDC power (see

illustration below).

[Dry Condition]

[+]

BLK

GRN

SHLD

WHT

RED

Sensor

(NC)

LOAD

[-]

Switching a Normally Open AC Load:

The Red wire connects to Positive (+) of the DC power supply and the

Black wire connects to Negative (-). The LOAD can be attached to

the Green wire and the Hot of the VAC power. Connect the White to

the Neutral of the VAC power (see illustration below).

[Dry Condition]

[+]

[AC Power]

[-]

RED

GRN

SHLD

WHT

BLK

LOAD

Sensor

(NO)

Switching a Normally Closed AC Load:

The Black wire connects to Positive (+) of the DC power supply and

the Red wire connects to Negative (-). The LOAD can be attached to

the Green wire and the Hot of the VAC power. Connect the White to

the Neutral of the VAC power (see illustration below).

[Dry Condition]

[+]

BLK

GRN

SHLD

WHT

RED

LOAD

Sensor

(NC)

[AC Power]

[-]

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WIRING

MAINTENANCE

Step Nine

Step Ten

Wiring as a P-Channel or N-Channel output:

The powered level switch can be substituted for either a P-Channel

(PNP, sourcing) output or a N-Channel (NPN, sinking) output.

General:

The powered level switch requires no periodic maintenance except

cleaning as required. It is the responsibility of the user to determine

the appropriate maintenance schedule, based on the specific charac-

teristics of the application liquids.

Normally Open DC Load as a P-Channel Output:

To wire as a NO P-Channel output, follow the directions below. The

Red wire connects to Positive (+) of the power supply and the Black

wire connects to Negative (-). The Green wire is jumpered to the Red

wire while the White wire is connected to the LOAD. Jumper the

LOAD back to the Negative (-) to complete the circuit.

Cleaning Procedure:

1. Power: Make Sure that all power to the sensor, controller and/or

power supply is completely disconnected.

2. Sensor Removal: In all through-wall installations, make sure

that the tank is drained well below the sensor prior to removal.

Carefully, remove the sensor from the installation.

[Dry Condition]

[+]

[-]

RED

GRN

SHLD

WHT

BLK

3. Cleaning the Sensor: Use a soft bristle brush and mild deter-

gent, carefully wash the powered level switch. Do not use harsh

abrasives such as steel wool or sandpaper, which might damage

the surface sensor. Do not use incompatible solvents which may

damage the sensor's PP, PFA, PVDF or Ryton plastic body.

Sensor

(NO)

LOAD

4. Sensor Installation: Follow the appropriate steps of installa-

Normally Closed DC Load as a P-Channel Output:

tion as outlined in the installation section of this manual.

To wire as a NC P-Channel output, follow the directions below. The

Black wire connects to Positive (+) of the power supply and the Red

wire connects to Negative (-). The Green wire is jumpered to the

Black wire while the White wire is connected to the LOAD. Jumper

the LOAD back to the Negative (-) to complete the circuit.

Testing the installation:

1. Power: Turn on power to the controller and/or power supply.

2. Immersing the switch: Immerse the sensing tip in its applica-

tion liquid, by filling the tank up to the switches point of actua-

tion. An alternate method of immersing the switch during prelim-

inary testing is to hold a cup filled with application liquid up to

the switch's tip.

[Dry Condition]

[+]

[-]

BLK

GRN

SHLD

WHT

RED

Sensor

(NC)

3. Test: With the switch being fluctuated between wet and dry

states, the switch indicator light in the controller should turn on

and off. If the controller doesn't have an input indicator, use a volt-

meter or ammeter to ensure that the switch produces the correct

signal.

LOAD

Normally Open DC Load as a N-Channel Output:

To wire as a NO N-Channel output, follow the directions below. The

Red wire connects to Positive (+) of the power supply and the Black

wire connects to Negative (-). The White wire is jumpered to the

Black wire while the Green wire is connected to the LOAD. Jumper

the LOAD back to the Positive (+) to complete the circuit.

4. Point of actuation: Observe the point at which the rising or

falling fluid level causes the switch to change state, and adjust the

installation of the switch if necessary.

[Dry Condition]

[+]

[-]

RED

GRN

SHLD

WHT

BLK

LOAD

Sensor

(NO)

Normally Closed DC Load as a N-Channel Output:

To wire as a NC N-Channel output, follow the directions below. The

Black wire connects to Positive (+) of the power supply and the Red

wire connects to Negative (-). The White wire is jumpered to the Red

wire while the White wire is connected to the LOAD. Jumper the

LOAD back to the Positive (+) to complete the circuit.

[Dry Condition]

[+]

[-]

BLK

GRN

SHLD

WHT

RED

Sensor

(NC)

LOAD

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