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L1
L2
GND
L3
L1
OFF
F
U
1
F
U
2
460 V
H1
H3
230 V
H2
H1
H4
H3
H2
A1
B1
15
B2
B2
STOP
B3STOP STOP
1B1
15
Supply voltage
ON
H4
START
2
M
OL
3
16 18
B3
A2
16
18
Electrostatically
Shielded Transformer
F
U
5
Power
On
F
U
6
X1A
F
U
4
H
M
L
21
31 43
53
14
22
32 44
54
AC
1
Status
(N.O. or N.C.)
2
5
6
8
9
10
12
14 (+)
13 (–)
A1/+ 15 25 Z1 Z2
NONHAZARDOUS LOCATIONS
FIBER OPTIC
TRANSCEIVER
Supply voltage
FIBER OPTIC
PUSH BUTTON,
SELECTOR SWITCH,
LIMIT SWITCH, ETC.
A1
15
B2
B1 B3
15
H
16 18
B3
A2
16
18
CLASS 9005 TYPE FT
B1
B2
16 18 26 28 A2/–
L
M
Vs
2 Levels
FIBER OPTIC CABLE
ELECTRICAL
CONNECTIONS
1
3
5
L1 L2 L3
A1
BOUNDARY SEAL TO BE IN
ACCORDANCE WITH ARTICLE
501-5 OF THE NATIONAL
ELECTRICAL CODE
L2
A1 A2
A2
L3
3
L1
T1 T2 T3
L2
1CT
M
L1
CIRCUIT BREAKER
OR DISCONNECT SWITCH
FIBER OPTIC CABLE
L2
4
Optional
HAZARDOUS LOCATIONS
CLASS I GROUPS A, B, C & D
CLASS II GROUPS E, F & G
CLASS III
X2
Green
X1
M
2 Levels
13
X3
Orange
LOAD
Location
X2A
22
14
R
F
U
3
L1
21
13
START
Optional Connection
X1 115 V X2
AC
L2
START
T1
T2
M
MOTOR
3CT
M
L3
T3
SOLID STATE
OVERLOAD RELAY
1
TO 120 V
SEPARATE
CONTROL
MOTOR
STOP
2
T1
T1 T2 T3
2
4
6
Wiring Diagram Book
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T2
START
OT*
T3
M
M
* OT is a switch that opens
when an overtemperature
condition exists (Type MFO
and MGO only)
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TRADEMARKS
QWIK-STOP® and ALHPA-PAK® are registered trademarks of Square D.
NEC® is a registered trademark of the National Fire Protection Association.
COPYRIGHT NOTICE
© 1993 Square D. All rights reserved. This document may not be copied in whole or in part, or transferred to any other media, without the written permission of Square D.
PLEASE NOTE:
Electrical equipment should be serviced only by qualified electrical maintenance personnel, and this
document should not be viewed as sufficient instruction for those who are not otherwise qualified to
operate, service or maintain the equipment discussed. Although reasonable care has been taken to provide accurate and authoritative information in this document, no responsibility is assumed by
Square D for any consequences arising out of the use of this material.
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Table of Contents
Standard Elementary Diagram Symbols ..................... 1-3
NEMA and IEC Markings and Schematic Diagrams ...... 4
Control and Power Connection Table
4
Terminology ...................................................................... 5
Examples of Control Circuits .......................................... 6
2-Wire Control
6
3-Wire Control
6-9
Shunting Thermal Units During Starting Period
10
Overcurrent Protection for 3-Wire Control Circuits
11
AC Manual Starters and Manual Motor
Starting Switches ........................................................... 12
Class 2510
12
Class 2511 and 2512
13
2-Speed AC Manual Starters and
IEC Motor Protectors...................................................... 14
Class 2512 and 2520
14
GV1/GV3
14
Drum Switches................................................................ 15
Class 2601
15
DC Starters, Constant and Adjustable Speed.............. 16
Class 7135 and 7136
16
Reversing DC Starters, Constant and
Adjustable Speed ........................................................... 17
Class 7145 and 7146
17
Mechanically Latched Contactors ................................ 18
Class 8196
18
Medium Voltage Motor Controllers.......................... 18-25
Class 8198
18-25
Solid State Protective Relays ................................... 26-27
Class 8430
26-27
General Purpose Relays ................................................ 28
Class 8501
28
NEMA Control Relays..................................................... 29
Class 8501 and 9999
29
General Purpose Relays ................................................ 30
Class 8501
30
Sensing Relays............................................................... 30
RM2 LA1/LG1
30
IEC Relays.................................................................. 31-32
IEC D-Line Control Relays
31
Class 8501
32
Type P Contactors..................................................... 33-35
Class 8502
33-35
Class 8702
35
Type T Overload Relays............................................ 33-35
Class 9065
33-35
Type S AC Magnetic Contactors.............................. 36-40
Class 8502
36-40
IEC Contactors .......................................................... 41-42
IEC Contactors and Auxiliary Contact Blocks
41
Input Modules and Reversing Contactors
42
Type S AC Magnetic Starters ................................... 43-50
Class 8536
43-50
8538 and 8539
45,49
1-Phase, Size 00 to 3
43
2-Phase and 3-Phase, Size 00 to 5
44
3-Phase, Size 6
45
3-Phase, Size 7
46
3-Phase Additions and Special Features
47-50
Integral Self-Protected Starters ............................... 51-57
Integral 18 State of Auxiliary Contacts
51-52
Integral 32 and 63 State of Auxiliary Contacts
53-54
Wiring Diagrams
55-57
Type S AC Combination Magnetic Starters ............ 58-59
Class 8538 and 8539
58-59
3-Phase, Size 0-5
58
3-Phase Additions and Special Features
59
Reduced Voltage Controllers ................................... 60-66
Class 8606 Autotransformer Type
60-61
Class 8630 Wye-Delta Type
62-63
Class 8640 2-Step Part-Winding Type
64
Class 8647 Primary-Resistor Type
65
Class 8650 and 8651 Wound-Rotor Type
66
Solid State Reduced Voltage Starters .......................... 67
Class 8660 ALPHA PAK®, Type MD-MG
67
Solid State Reduced Voltage Controllers ............... 68-70
Class 8660 Type MH, MJ, MK and MM
68-70
®
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i
Table of Contents
Type S AC Reversing Magnetic Starters71-72
Class 873671-72
2- and 3-Pole71
3- and 4-Pole72
Pneumatic Timing Relays and Solid State
Industrial Timing Relays95-96
Class 905095-96
Timers97
Class 905097
Type S AC 2-Speed Magnetic Starters73-76
Class 881073-76
Special Control Circuits75-76
Transformer Disconnects98
Class 907098
Multispeed Motor Connections76-77
1- Phase76
3-Phase76-77
Enclosure Selection Guide99
Conductor Ampacity and Conduit Tables100-101
Programmable Lighting Controllers78
Class 886578
Wire Data102
AC Lighting Contactors79-81
Class 890379-81
Load Connections79
Control Circuit Connections80
Panelboard Type Wiring81
Electrical Formulas103-104
Electronic Motor Brakes81-82
Class 8922 QWIK-STOP®81-82
List of Tables
Table 1
Standard Elementary Diagram Symbols 1
Table 2
NEMA and IEC Terminal Markings 4
Table 3
NEMA and IEC Controller Markings and
Elementary Diagrams 4
Fiber Optic Transceivers82
Class 900582
Table 4
Control and Power Connections for
Across-the-Line Starters, 600 V or less4
Table 5
Motor Lead Connections 64
Photoelectric and Inductive Proximity Switches83
Class 900683
Table 6
Enclosures for Non-Hazardous Locations 99
Table 7
Enclosures for Hazardous Locations 99
Table 8
Conductor Ampacity100
Table 9
Ampacity Correction Factors 101
Table 10
Adjustment Factors 101
Table 11
Ratings for 120/240 V, 3-Wire,
Single-Phase Dwelling Services101
Table 12
AWG and Metric Wire Data 102
Table 13
Electrical Formulas for Amperes,
Horsepower, Kilowatts and KVA 103
Table 14
Ratings for 3-Phase, Single-Speed,
Full-Voltage Magnetic Controllers
for Nonplugglng and Nonjogging Duty 103
Table 15
Ratings for 3-Phase, Single-Speed,
Full-Voltage Magnetic Controllers for PlugStop, Plug-Reverse or Jogging Duty 104
Table 16
Power Conversions 104
Duplex Motor Controllers82
Class 894182
Photoelectric and Proximity Sensors84-89
XS, XSC, XSF and XSD84
XS and XTA85
SG, ST and XUB86
XUM, XUH, XUG, XUL and XUJ87
XUE, XUR, XUD, XUG and XUE S88
XUV89
Limit Switches and Safety Interlocks90-92
Class 900791
XCK and MS92
Pressure Switches and Transducers93
Class 9012, 9013, 9022 and 902593
Level Sensors and Electric Alternators94
Class 9034 and 903994
®
ii
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Standard Elementary Diagram Symbols
The diagram symbols in Table 1 are used by Square D and, where applicable, conform to NEMA (National Electrical Manufacturers Association)
standards.
Table 1
Standard Elementary Diagram Symbols
SWITCHES
Disconnect
Circuit Interrupter
SELECTORS
Circuit Breakers
w/ Thermal OL
Circuit Breakers
w/ Magnetic OL
2-Position Selector Switch
J
K
A1
A2
J
K
A1
A2
Pressure &
Vacuum Switches
N.O.
N.C.
Liquid Level Switches
N.O.
Temperature
Actuated Switches
N.O.
N.C.
N.C.
3-Position Selector Switch
K
L
J
A1
A2
J
Limit Switches
N.O.
Speed (Plugging)
N.C.
F
F
Anti-Plug
A1
F
A2
K
L
2-Position Selector Push Button
Held Closed
A
Held Open
R
Flow Switches
N.O.
N.C.
R
N.O.
1
2
3
4
Selector
Position
Foot Switches
A
N.C.
B
B
Push
Button
Contacts
1-2 3-4
Free
Depressed
Free
Depressed
= contact closed
PUSH BUTTONS – MOMENTARY CONTACT
N.O.
N.C.
N.O. & N.C.
(double circuit)
Mushroom
Head
Wobble
Stick
PUSH BUTTONS – MAINTAINED
CONTACT
2 Single
Circuits
Illuminated
1 Double
Circuit
R
PILOT LIGHTS
Non Push-to-Test
INSTANT OPERATING CONTACTS
Push-to-Test
w/ Blowout
N.O.
N.C.
w/o Blowout
N.O.
N.C.
TIMED CONTACTS
Contact action retarded after coil is:
Energized
Deenergized
N.O.T.C.
A
N.C.T.O.
N.O.T.O.
N.C.T.C.
G
(indicate color by letter)
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1
Standard Elementary Diagram Symbols
Table 1
Standard Elementary Diagram Symbols (cont'd)
TRANSFORMERS
INDUCTORS
Iron Core
Auto
Air Core
Iron Core
Air Core
OVERLOAD RELAYS
Thermal
Current
Dual Voltage
AC MOTORS
Single Phase
Magnetic
3-Phase
Squirrel Cage
2-Phase, 4-Wire
Wound Rotor
DC MOTORS
Armature
Shunt Field
(show 4 loops)
Series Field
(show 3 loops)
Commutating or
Compensating Field
(show 2 loops)
WIRING
Not Connected
Connected
Power
Control
Terminal
CAPACITORS
Fixed
Ground
Mechanical
Connection
Mechanical
Interlock
Connection
RESISTORS
Adjustable
Fixed
Heating
Element
Adjustable,
by Fixed Taps
Rheostat,
Potentiometer or
Adjustable Taps
RES
H
RES
RES
SEMICONDUCTORS
Diode or Half
Wave Rectifier
Tunnel
Diode
Full Wave
Rectifier
NPN
Transistor
C
AC
+
DC
Zener
Diode
DC
B
Bidirectional
Breakdown Diode
Triac
PNP
Transistor
UJT,
N Base
C
SCR
Gate Turn-Of
Thyristor
A
B2
G
E
AC
2
Photosensitive
Cell
E
B1
E
UJT,
P Base
B2
E
B
PUT
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B1
K
Standard Elementary Diagram Symbols
Table 1
Standard Elementary Diagram Symbols (cont'd)
OTHER COMPONENTS
Bell
Annunciator
Buzzer
Horn, Alarm,
Siren,etc.
Meter (indicate
type by letters)
VM
+
Battery
–
Fuse
Meter Shunt
Thermocouple
SUPPLEMENTARY CONTACT SYMBOLS
SPST, N.O.
Single Break
Double Break
SPST, N.C.
Single Break
Double Break
SPDT
Single Break
Double Break
DPST, 2 N.O.
Single Break
Double Break
DPST, 2 N.C.
Single Break
Double Break
DPDT
Single Break
Double Break
IEC SYMBOLS
Push Buttons
N.C.
N.O.
Coil
Aux. Contacts
N.O. N.C.
Contactor
Breakers
STATIC SWITCHING CONTROL
Limit Switch, N.O., Static Control
Static switching control is a method of switching electrical circuits without the use of contacts,
primarily by solid state devices. To indicate static switching control, use the symbols shown in this
table, enclosing them in a diamond as shown.
TERMS
SPST:
SPDT:
DPST:
DPDT:
Single Pole, Single Throw
Single Pole, Double Throw
Double Pole, Single Throw
Double Pole, Double Throw
N.O.:
N.C.:
T.O.:
T.C.:
Normally Open
Normally Closed
Timed Open
Timed Closed
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PUT:
SCR:
Triac:
UJT:
Programmable Unijunction Transistor
Silicon Controlled Rectifier
Bidirectional Triode Thyristor
Unijunction Transistor
3
NEMA and IEC Markings and Schematic Diagrams
Control and Power Connection Table
Table 2
NEMA and IEC Terminal Markings
NEMA
L1
L2
L3
T1
T2
T3
No standard
designation
No specific
marking
Alphanumeric, corresponding
to incoming line and motor
terminal designations
Control Terminals
Power Terminals
Coil Terminals
IEC
1
3
5
2
4
6
A1
14
A1 A3
A1 B1
A2 B2
22
Single digit numeric,
odd for supply lines,
even for load connections
2-digit numeric, 1st
designates sequence,
2nd designates function
(1-2 for N.C., 3-4 for N.O.)
Power Terminals
Control Terminals
Table 3
A1
A2
A2 A3
A2
One
Winding
Tapped
Winding
Tapped
Winding
Two
Windings
Coil Terminals
NEMA and IEC Controller Markings and Elementary Diagrams
NEMA
3
1/L1
L2
L1
L3
L2
START
1
2
T1
T2
STOP
2
3
M
OL
T3
Typical Controller Markings
Typical Elementary Diagram
IEC
A1
1
3
5
13
21
A2
2
4
6
14
22
11 STOP 12 23 START
Table 4
96
Typical Elementary Diagram
Control and Power Connections for Across-the-Line Starters, 600 V or less
(From NEMA standard ICS 2-321A.60)
Line Markings
Ground, when used
Motor Running
Overcurrent,
units in:
1 element
2 element
3 element
Control Circuit Connected to
For Reversing, Interchange
Lines
4
A2 95
24
23
Typical Controller Markings
24 A1
1-Phase
2-Phase, 4-Wire
3-Phase
L1, L2
L1, L3: Phase 1
L2, L4: Phase 2
L1, L2, L3
L1 is always ungrounded
—
L2
L1
—
—
—
L1, L4
—
—
—
L1, L2, L3
L1, L2
L1, L3
L1, L2
—
L1, L3
L1, L3
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Terminology
WIRING DIAGRAM
A wiring diagram shows, as closely as possible, the actual
location of all component parts of the device. The open
terminals (marked by an open circle) and arrows represent
connections made by the user.
Since wiring connections and terminal markings are
shown, this type of diagram is helpful when wiring the
device or tracing wires when troubleshooting. Bold lines
denote the power circuit and thin lines are used to show the
control circuit. Black wires are conventionally used in
power circuits and red wire in control circuits for AC
magnetic equipment.
A wiring diagram is limited in its ability to completely convey
the controller’s sequence of operation. The elementary
diagram is used where an illustration of the circuit in its
simplest form is desired.
ELEMENTARY DIAGRAM
An elementary diagram is a simplified circuit illustration.
Devices and components are not shown in their actual
positions. All control circuit components are shown as
directly as possible, between a pair of vertical lines
representing the control power supply. Components are
arranged to show the sequence of operation of the devices
and how the device operates. The effect of operating
various auxiliary contacts and control devices can be
readily seen. This helps in troubleshooting, particularly with
the more complex controllers.
This form of electrical diagram is sometimes referred to as
a “schematic” or “line” diagram.
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5
Examples of Control Circuits
2- and 3-Wire Control
Elementary Diagrams
Low Voltage Release and Low Voltage Protection are the basic control circuits encountered in motor control applications. The simplest schemes
are shown below. Other variations shown in this section may appear more complicated, but can always be resolved into these two basic
schemes.
Note: The control circuits shown in this section may not include overcurrent protective devices required by applicable electrical codes. See page
11 for examples of control circuit overcurrent protective devices and their use.
Low Voltage Release:
2-Wire Control
FIG. 1
Low Voltage Protection:
3-Wire Control
L1
L2
M
3
1
FIG. 2
OL
L1
1
L2
STOP
START
M
3
2
OL
M
PILOT DEVICE SUCH AS
LIMIT SWITCH,
PRESSURE SWITCH, ETC.
Low voltage release is a 2-wire control scheme using a
maintained contact pilot device in series with the starter coil.
This scheme is used when a starter is required to function
automatically without the attention of an operator. If a power
failure occurs while the contacts of the pilot device are closed,
the starter will drop out. When power is restored, the starter
will automatically pickup through the closed contacts of the
pilot device.
The term “2-wire” control is derived from the fact that in the
basic circuit, only two wires are required to connect the pilot
device to the starter.
Low voltage protection is a 3-wire control scheme using
momentary contact push buttons or similar pilot devices to
energize the starter coil.
This scheme is designed to prevent the unexpected starting of
motors, which could result in injury to machine operators or
damage to the driven machinery. The starter is energized by
pressing the Start button. An auxiliary holding circuit contact on
the starter forms a parallel circuit around the Start button
contacts, holding the starter in after the button is released. If a
power failure occurs, the starter will drop out and will open the
holding circuit contact. When power is restored, the Start button
must be operated again before the motor will restart.
The term “3-wire” control is derived from the fact that in the
basic circuit, at least three wires are required to connect the
pilot devices to the starter.
2-Wire Control:
Maintained Contact Hand-OFF-Auto Selector Switch
FIG. 3
L1
L2
A1
A2
3-Wire Control:
Momentary Contact Multiple Push Button Station
FIG. 4
L1
L2
START
I
I
HAND OFF AUTO
A1
3A
M
OL
1 STOP STOP STOP
START
2
M
3
OL
START
1A
2A
A2
M
2-WIRE CONTROL DEVICE
A Hand-Off-Auto selector switch is used on 2-wire control
applications where it is desirable to operate the starter manually
as well as automatically. The starter coil is manually energized
when the switch is turned to the Hand position and is
automatically energized by the pilot device when the switch is
in the Auto position.
6
When a motor must be started and stopped from more than one
location, any number of Start and Stop push buttons may be
wired together. It is also possible to use only one Start-Stop
station and have several Stop buttons at different locations to
serve as an emergency stop.
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Examples of Control Circuits
3-Wire Control
Elementary Diagrams
3-Wire Control:
Pilot Light Indicates when Motor is Running
FIG. 1
L1
1
3-Wire Control:
Pilot Light Indicates when Motor is Stopped
L2
STOP
START
M
3
2
FIG. 2
L1
OL
L2
1
STOP
START
3
2
M
OL
M
M
M
R
G
A pilot light can be wired in parallel with the starter coil to
indicate when the starter is energized, indicating the motor is
running.
3-Wire Control:
Push-to-Test Pilot Light Indicates when Motor is
Running
FIG. 3
L1
1
L2
STOP
START
M
3
2
A pilot light may be required to indicate when the motor is
stopped. This can be implemented by wiring a normally-closed
auxiliary contact on the starter in series with the pilot light, as
shown above. When the starter is deenergized, the pilot light
illuminates. When the starter picks up, the auxiliary contact
opens, turning off the light.
3-Wire Control:
Illuminated Push Button Indicates when Motor is
Running
FIG. 4
L1
OL
L2
1
STOP
2
START*
3
M
OL
M
M
R
TEST
R
*
* Pushing on pilot light operates Start contacts.
When the Motor Running pilot light is not lit, there may be doubt
as to whether the circuit is open or whether the pilot light bulb
is burned out. To test the bulb, push the color cap of the Pushto-Test pilot light.
3-Wire Control:
Fused Control Circuit Transformer and Control Relay
3-Wire Control:
Fused Control Circuit Transformer
FIG. 5
The illuminated push button combines a Start button and pilot
light in one unit. Pressing the pilot light lens operates the Start
contacts. Space is saved by using a two-unit push button
station instead of three.
L1
L2
FIG. 6
L1
L2
CR
FU2
FU1
START
STOP
M
M
OL
START
M
STOP
GROUND
(If used)
CR
OL
M
GROUND
(If used)
As an operator safety precaution, a step-down transformer can
be used to provide a control circuit voltage lower than line
voltage. The diagram above shows one way to provide
overcurrent protection for control circuits.
A starter coil with a high VA rating may require a control transformer of considerable size. A control relay and a transformer with a low
VA rating can be connected so the normally-open relay contact
controls the starter coil on the primary or line side. Square D Size 5
Combination Starter Form F4T starters use this scheme.
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7
Examples of Control Circuits
3-Wire Control
Elementary Diagrams
Jogging: Selector Switch and Start Push Button
FIG. 1
Jogging: Selector Push Button
FIG. 2
FPO 7-2
FPO 7-1
Jogging, or inching, is defined by NEMA as the momentary
operation of a motor from rest for the purpose of accomplishing
small movements of the driven machine. One method of jogging
is shown above. The selector switch disconnects the holding
circuit contact and jogging may be accomplished by pressing the
Start push button.
A selector push button may be used to obtain jogging, as shown
above. In the Run position, the selector-push button provides
normal 3-wire control. In the Jog position, the holding circuit is
broken and jogging is accomplished by depressing the
push button.
Jogging: Control Relay
Jogging: Control Relay for Reversing Starter
FIG. 3
FIG. 4
FPO 7-4
FPO 7-3
When the Start push button is pressed, the control relay is
energized, which in turn energizes the starter coil. The normallyopen starter auxiliary contact and relay contact then form a
holding circuit around the Start push button. When the Jog push
button is pressed, the starter coil is energized (independent of the
relay) and no holding circuit forms, thus jogging can be obtained.
This control scheme permits jogging the motor either in the
forward or reverse direction, whether the motor is at standstill or
rotating. Pressing the Start-Forward or Start-Reverse push button
energizes the corresponding starter coil, which closes the circuit
to the control relay.The relay picks up and completes the holding
circuit around the Start button. As long as the relay is energized,
either the forward or reverse contactor remains energized.
Pressing either Jog push button will deenergize the relay,
releasing the closed contactor. Further pressing of the Jog button
permits jogging in the desired direction.
3-Wire Control:
More than 1 Starter, 1 Push Button Station Controls all
3-Wire Control:
Reversing Starter
FIG. 5
FIG. 6
FPO 7-5
FPO 7-6
When one Start-Stop station is required to control more than one
starter, the scheme above can be used. A maintained overload on
any one of the motors will drop out all three starters.
8
3-wire control of a reversing starter can be implemented with a
Forward-Reverse-Stop push button station as shown above. Limit
switches may be added to stop the motor at a certain point in either
direction. Jumpers 6 to 3 and 7 to 5 must then be removed.
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Examples of Control Circuits
3-Wire Control
Elementary Diagrams
3-Wire Control:
Reversing Starter Multiple Push Button Station
3-Wire Control: Reversing Starter w/ Pilot Lights to
Indicate Motor Direction
FIG. 2
FIG. 1
More than one Forward-Reverse-Stop push button station may be
required and can be connected in the manner shown above.
3-Wire Control:
2-Speed Starter
Pilot lights may be connected in parallel with the forward and
reverse contactor coils, indicating which contactor is energized
and thus which direction the motor is running.
3-Wire Control: 2-Speed Starter w/ 1 Pilot Light to
Indicate Motor Operation at Each Speed
FIG. 4
FIG. 3
3-wire control of a 2-speed starter with a High-Low-Stop push button
station is shown above. This scheme allows the operator to start the
motor from rest at either speed or to change from low to high speed.
The Stop button must be operated before it is possible to change from
high to low speed. This arrangement is intended to prevent excessive
line current and shock to motor and driven machinery, which results
when motors running at high speed are reconnected for a lower speed.
One pilot light may be used to indicate operation at both low and
high speeds. One extra normally-open auxiliary contact on each
contactor is required. Two pilot lights, one for each speed, may
be used by connecting pilot lights in parallel with high and low
coils (see reversing starter diagram above).
Plugging:
Plugging a Motor to a Stop from 1 Direction Only
Anti-Plugging:
Motor to be Reversed but Must Not be Plugged
FIG. 5
FIG. 6
Plugging is defined by NEMA as a braking system in which the motor
connections are reversed so the motor develops a counter torque, thus
exerting a retarding force. In the above scheme, forward rotation of the
motor closes the normally-open plugging switch contact and
energizing control relay CR. When the Stop push button is operated,
the forward contactor drops out, the reverse contactor is energized
through the plugging switch, control relay contact and normally-closed
forward auxiliary contact. This reverses the motor connections and the
motor is braked to a stop. The plugging switch then opens and
disconnects the reverse contactor. The control relay also drops out.
The control relay makes it impossible for the motor to be plugged in
reverse by rotating the motor rotor closing the plugging switch. This
type of control is not used for running in reverse.
Anti-plugging protection is defined by NEMA as the effect of a
device that operates to prevent application of counter-torque by
the motor until the motor speed has been reduced to an
acceptable value. In the scheme above, with the motor operating
in one direction, a contact on the anti-plugging switch opens the
control circuit of the contactor used for the opposite direction.
This contact will not close until the motor has slowed down, after
which the other contactor can be energized.
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Examples of Control Circuits
Shunting Thermal Units During Starting Period
Elementary Diagrams
Shunting Thermal Units During Starting Period
FIG. 1
Article 430-35 of the NEC describes circumstances under
which it is acceptable to shunt thermal units during
abnormally long accelerating periods.
430-35. Shunting During Starting Period.
(a) Nonautomatically Started. For a nonautomatically
started motor, the overload protection shall be
permitted to be shunted or cut out of the circuit during
the starting period of the motor if the device by which
the overload protection is shunted or cut out cannot be
left in the starting position and if fuses or inverse time
circuit breakers rated or set at not over 400 percent of
the full-load current of the motor are so located in the
circuit as to be operative during the starting period of
the motor.
FPO 9-1
(b) Automatically Started. The motor overload protection
shall not be shunted or cut out during the starting
period if the motor is automatically started.
Exception. The motor overload protection shall be
permitted to be shunted or cut out during the starting period
on an automatically started motor where:
(1) The motor starting period exceeds the time delay
of available motor overload protective devices, and
(2) Listed means are provided to:
a. Sense motor rotation and to automatically
prevent the shunting or cut out in the event
that the motor fails to start, and
b. Limit the time of overload protection shunting
or cut out to less than the locked rotor time
rating of the protected motor, and
c. Provide for shutdown and manual restart if
motor running condition is not reached.
Figures 1 and 2 show possible circuits for use in
conjunction with 3-wire control schemes. Figure 1 complies
with NEC requirements. Figure 2 exceeds NEC
requirements, but the additional safety provided by the zero
speed switch might be desirable.
Figure 3 shows a circuit for use with a 2-wire, automatically
started control scheme that complies with NEC
requirements. UL or other listed devices must be used in
this arrangement.
FIG. 2
FPO 9-2
FIG. 3
FPO 9-3
10
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Examples of Control Circuits
Overcurrent Protection for 3-Wire Control Circuits
Elementary Diagrams
3-Wire Control:
Fusing in 1 Line Only
FIG. 1
3-Wire Control:
Fusing in Both Lines
L1
L2
FIG. 2
L1
FU1
FU2
FU1
START
STOP
M
OL
M
START
STOP
3-Wire Control:
Fusing in Both Primary and Secondary Lines
L1
L2
FIG. 4
L1
FU2
L2
FU4
FU3
PRI
PRI
FU1
X1
STOP
SEC
START
X2
FU2
X1
M
OL
STOP
X2
M
OL
M
Control circuit transformer with fusing in both primary lines, no
secondary fusing and all lines ungrounded.
Control circuit transformer with fusing in both primary lines and
both secondary lines, with all lines ungrounded.
3-Wire Control:
Fusing in Both Primary Lines and 1 Secondary Line
L1
L2
FU1
SEC
START
M
FIG. 5
OL
Common control with fusing in both lines and with both lines
ungrounded.
3-Wire Control:
Fusing in Both Primary Lines
FU1
M
M
GND
Common control with fusing in one line only and with both lines
ungrounded or, if user’s conditions permit, with one line grounded.
FIG. 3
L2
3-Wire Control:
Fusing in Both Primary and Secondary Lines
For Large Starters using Small Transformer
FIG. 6
L1
L2
FU2
FU3
PRI
FU4
M
CR
FU3
STOP
SEC
START
PRI
M
OL
FU1
FU2
X1
M
GND
STOP
SEC
START
X2
CR
OL
M
Control circuit transformer with fusing in one secondary line and
both primary lines, with one line grounded.
Control circuit transformer with fusing in both primary lines and
both secondary lines, with all lines ungrounded. Used for large VA
coils only.
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11
AC Manual Starters and Manual Motor Starting Switches
Class 2510
Manual Motor Starting Switches:
Class 2510 Type K
FIG. 1
T1
FIG. 2
L1
T1
L1
L1
T2
T3
L2
L3
T3
L2
T1
L3
PILOT
LIGHT
(IF USED)
R
PILOT
LIGHT
(IF USED)
R
T3
T1 T2 T3
MOTOR
MOTOR
2-Pole, 1-Phase
3-Pole, 3-Phase
Fractional Horsepower Manual Starters:
Class 2510 Type F
FIG. 3
FIG. 4
T2
FIG. 5
T2
L2
L2
L1
L1
T2
A
O
H
R
T1
T1
PILOT
LIGHT
(IF USED)
PILOT
LIGHT
(IF USED)
R
T1
T2
T1
MOTOR
2 1
L1
4 3
PILOT
LIGHT
(IF USED)
R
T1
T2
2
MOTOR
1-Pole
L2
A O H
4
2-WIRE
CONTROL
DEVICE
2-Pole
T2
4
MOTOR
2-Pole w/ Selector Switch
Integral Horsepower Manual Starters:
Class 2510 Size M0 and M1
FIG. 6
L1
L2
FIG. 7
L1
L2
T2
FIG. 8
L1
L2
FIG. 9
L1
L2
L3
T1
T2
T3
FIG. 10
L1
L2
L3
T1
T2
T3
L2
L3
L1
T1
T2
T1
T1
T2
T1
T2
T1
MOTOR
T2
T1
T3
T1 T2 T3
T1 T2 T3
MOTOR
MOTOR
T3
MOTOR
MOTOR
2-Pole, 1-Phase
3-Pole, DC
3-Pole, 1-Phase
3-Pole, 3-Phase
3-Pole, 3-Phase w/ additional
Interlock (Form X)
®
12
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AC Manual Starters and Manual Motor Starting Switches
Class 2511 and 2512
AC Reversing Manual Starters and Manual Motor Starting Switches:
Class 2511
FIG. 1
FIG. 2
REV
FWD
T1
L1
T2
L2
T3
L3
L1
L2
L3
T1
T2
T3
T1 T2 T3
T1 T2 T3
MOTOR
MOTOR
Reversing Manual Motor Starting Switch
Type K, 3-Pole, 3-Phase
Reversing Manual Starter
Sizes M0 and M1, 3-Pole, 3-Phase
AC 2-Speed Manual Motor Starting Switches:
Class 2512 Type K
FIG. 4
FIG. 3
FPO
12-6b
FPO
12-6a
2-Pole, 1-Phase w/ Pilot Lights
3-Pole, 3-Phase
AC 2-Speed Manual Motor Starters:
Class 2512 Type F
FIG. 5
FIG. 6
FPO 13-1b
FPO
13-1a
2-Unit, 2-Pole w/ Mechanical Interlock and Pilot Lights
3-Unit, 2-Pole w/ Selector Switch and Pilot Lights
®
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13
2-Speed AC Manual Starters and IEC Motor Protectors
Class 2512 and 2520 and Telemecanique GV1/GV3
2-Speed AC Manual Motor Starters:
Class 2512 Size M0 and M1
FIG. 1
L1
L2
L3
T2 T11 T13
T1 T3 T12
MOTOR
T1
T2
T3
T11
T12
T13
2-Speed Manual Starter for Wye-Connected, Separate Winding Motor
Motor Protective Switches:
Class 2520
FIG. 2
1/L1
3/L2
FIG. 3
5/L3
1/L1
3/L2
5/L3
FIG. 4
1/L1
3/L2
5/L3
2/T1 4/T2 6/T3
2/T1 4/T2 6/T3
2/T1 4/T2 6/T3
T1 T2 T3
T1
T3
T3
MOTOR
MOTOR
MOTOR
3-Pole, 3-Phase
2-Pole Application
1-Pole Application
IEC Manual Starters:
GV1/GV3
FIG. 5
1/L1 3/L2
5/L3
FIG. 6
FIG. 7
GV3 B•
D1
I> I> I>
2/T1 4/T2 6/T3
GV3 A08
95
D2
96
23
14
22
14
24
14 24 34
GV1 A06
98
GV3 A0• Fault Signalling Contacts
13
14 24 32
GV3 A09
97
I>
21
GV1 A05
13 23 33
C2
I>
GV1 A02
13
GV1 A03
13 23 31
GV3 D•
C1
GV3 M• Motor Protector
FIG. 8
<
GV1 A01
GV3 Voltage Trips
GV1 A07
13 23 33
13 23 31
14 24 34
14 24 33
GV1 A0• Contact Block
®
14
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Drum Switches
Class 2601
Drum Switches:
Class 2601
REVERSE
OFF
MOTOR
FORWARD
1
2 1
2
1
2
3
4 3
4
3
4
5
6 5
6
5
6
1
2
3
4
5
6
DRUM SW.
MOTOR
1
2
3
4
5
6
MOTOR
DRUM SW.
FIG. 3
MOTOR
DRUM SW.
1
2
3
4
5
6
LINE
1-Phase, Capacitor or Split-Phase Motor
FIG. 5
LINE
MOTOR
1-Phase, 4-Lead Repulsion Induction Motor
FIG. 6
LINE
3-Phase, 3-Wire Motor
Internal Switching
FIG. 4
DRUM SW.
START
FIG. 2
HANDLE END
RUN
FIG. 1
DRUM SW.
1
2
3
4
5
6
LINE
1-Phase, 3-Lead Repulsion Induction Motor
FIG. 7
LINE
DRUM SW. LINE
MOTOR
1
2
1
2
3
4
3
4
5
6
5
6
COMMON
2-Phase, 4-Wire Motor
MOTOR
LINE
1
2
3
4
5
6
DC, Shunt Motor
DRUM SW.
1
LINE
2
ARMATURE
3
4
5
6
DC, Series Motor
FIG. 10
MOTOR
DRUM SW.
LINE
1
2
ARMATURE
SERIES
FIELD
DRUM SW.
SERIES
FIELD
ARMATURE
SHUNT FIELD
MOTOR
FIG. 9
SHUNT FIELD
2-Phase, 3-Wire Motor
FIG. 8
3
4
5
6
DC, Compound Motor
®
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15
DC Starters, Constant and Adjustable Speed
Class 7135 and 7136
Constant Speed DC Starter: Class 7135
FIG. 1
FPO 15-1
Typical Elementary Diagram for
NEMA Size 2, 3 and 4
Adjustable Speed DC Starter: Class 7136
FIG. 2
FPO 15-2
Typical Elementary Diagram for
NEMA Size 2, 3 and 4
Acceleration Contactors: Class 7135, 7136, 7145 and 7146
NEMA Size
1
2
3
4
5
No. of Acceleration Contactors
1
2
2
2
3
®
16
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Reversing DC Starters, Constant and Adjustable Speed
Class 7145 and 7146
Reversing Constant Speed DC Starter: Class 7145
FIG. 1
FPO 16-1
Typical Elementary Diagram
for NEMA Size 2, 3 and 4
Reversing Adjustable Speed DC Starter: Class 7146
FIG. 2
FPO 16-2
Typical Elementary Diagram
for NEMA Size 2, 3 and 4
®
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17
Mechanically Latched Contactors and Medium Voltage Motor Controllers
Class 8196 and 8198
Mechanically Latched Contactor:
Class 8196 Type FL13, FL23, FL12 and FL22
FIG. 1
FPO 17-2
150%
Full-Voltage, Non-Reversing Squirrel Cage Motor Controller:
Class 8198 Type FC11, FC21, FC13, FC23, FC12 and FC22
FIG. 2
FPO 17-1
145%
®
18
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Medium Voltage Motor Controllers
Class 8198
Full-Voltage Squirrel Cage Motor Controller:
Class 8198 Type FCR1 and FCR2
FIG. 1
FPO 17-3
160%
®
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19
Medium Voltage Motor Controllers
Class 8198
Reduced-Voltage, Primary Reactor, Non-Reversing Squirrel Cage Motor Controller:
Class 8198 Type RCR1 and RCR2
FIG. 1
FPO 18-1
130%
®
20
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Medium Voltage Motor Controllers
Class 8198
Reduced-Voltage, Primary Reactor, Autotransformer, Non-Reversing Squirrel Cage Motor Controller:
Class 8198 Type RCA1 and RCA2
FIG. 1
FPO 18-2
150%
®
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21
Medium Voltage Motor Controllers
Class 8198
Full Voltage, Non-Reversing Synchronous Motor Controller:
Class 8198 Type FS1 and FS2
FIG. 1
FPO 19-1
170%
®
22
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Medium Voltage Motor Controllers
Class 8198
Reduced-Voltage, Primary Reactor, Non-Reversing Synchronous Motor Controller:
Class 8198 Type RS1 and RS2
FIG. 1
FPO 19-2
140%
®
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23
Medium Voltage Motor Controllers
Class 8198
Reduced-Voltage, Autotransformer, Non-Reversing Synchronous Motor Controller:
Class 8198 Type RSA1 and RSA2
FIG. 1
FPO 20-1
160%
®
24
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Medium Voltage Motor Controllers
Class 8198
Full-Voltage, Non-Reversing, Brushless Synchronous Motor Controller:
Class 8198 Type FSB1 and FSB2
FIG. 1
FPO 20-2
155%
®
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25
Solid State Protective Relays
Class 8430
Solid State Protective Relays:
Class 8430 Type DAS, DASW, DASV and DASVW
FIG. 1
L1
L2
L3
M
OL
T1
M
OL
T2
M
OL
T3
MOTOR
START
STOP
OL
M
Dashed lines
represent
optional contacts
12
L1
14
22
L2
L3
24
11
With the line voltage connections directly at
the motor terminals, the relay will detect all
phase loss conditions ahead of the connection
points. However, the motor may sustain a
momentary “bump” in the reverse condition if
the proper phase sequence is not present.
M
21
FIG. 2
L1
L2
L3
STOP
START
M
12
L1
14
22
L2
L3
24
11
Dashed lines represent
optional contacts
M
OL
T1
M
OL
T2
M
OL
T3
MOTOR
With the line voltage connections
ahead of the starter, the motor can
be started in the reverse direction.
The relay cannot detect a phase loss
on the load side of the starter.
OL
M
21
Solid State Protective Relays:
Class 8430
FIG. 3
FIG. 4
FIG. 5
4
5
3
Input
Signal
2
L1
L2
L3
A1 11 21 B1 B2
1
2
3
4
5
6
1
8
6
L1
7
L2
L3
Type MPS 240V
FIG. 6
1
2
3
4
5
6
7
8
9
12 14 22 24 A2
VS
7
8
9 10 11 12
Dashed lines represent optional contacts
(DIAW and DUAW devices only)
Type DIA, DIAW, DUA and DUAW
A
B
L3
L2
L1
Type MPD
Type MPS 480V
®
26
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Solid State Protective Relays
Class 8430
Load Detector Relay:
Class 8430 Type V
FIG. 1
FPO 22-1
Wiring Diagram
FPO 22-3
Elementary Diagram (Common Control)
Load Converter Relay:
Class 8430 Type G
FIG. 2
FPO 22-2
®
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27
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General Purpose Relays
Class 8501
Control Relays:
Class 8501 Type CO and CDO
FIG. 2
FIG. 1
Type CO6 and
CDO6
FIG. 3
Type CO7 and
CDO7
FIG. 4
Type CO8 and
CDO8
FIG. 5
Type CO21 and
CDO21
FIG. 6
Type CO15 and
CDO15
Type CO16, CDO16, CO22 and
CDO22
Control Relays:
Class 8501 Type UBS
FIG. 7
START
L1
M
STOP
L2
M
9
10
8
5
TERMINAL NUMBERS
Control Relays:
Class 8501 Type K
FIG. 8
FIG. 9
FIG. 10
1
3
4
6
1
3
7
9
4
6
7
9
8
RESET
A
B
COMMON
LATCH
4
3
B
A
FIG. 12
FIG. 11
1
6
2
7
1
Type KU, KF, KX, KUD, KFD and KXD
2-Pole
Type KL
6
7
9
FIG. 13
6
A
B
–
+
+
–
LATCH
RESET
Type KLD
8
Type KP and KPD
2-Pole
3
4
5
1
2
3
4
5
6
7
8
9
A
B
5
7
4
8
3
9
2
10
1
Type KU, KF, KX, KUD, KFD and KXD
3-Pole
11
Type KP and KPD
3-Pole
®
28
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NEMA Control Relays
Class 8501 and 9999
10 A Control Relay w/ Convertible Contacts:
Class 8501 Type X
FIG. 1
FPO 27-1
* Note: Class 8501 Type XO••••XL, XDO••••XL, XDO••••XDL and
XO••••XDL latch relays use the same diagram except for the
addition of an unlatch coil (8 poles maximum).
Timer Attachment:
Class 9999 Type XTD and XTE
FIG. 2
TIMED CONTACTS
14
2 N.O.
1 N.C. 1 N.O.
14
14
13
13
13
14
POLE #13
14
2 N.C.
14
POLE #14
Note: All contacts are
convertible.
13
13
ON
DELAY
(TDE)
13
OFF
DELAY
(TDD)
No. of
Timed
Contacts
Class
9999
Type
2
XTD
XTE
Pole No.*
13
14
O
1
* O = N.O. Contact
1 = N.C. Contact
®
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29
General Purpose Relays and Sensing Relays
Class 8501 and Telemecanique RM2 LA1/LG1
Miniature Control Relays:
Class 8501 Type RS and RSD
FIG. 1
FIG. 2
1
1
4
5
5
8
9
9
12
14 (+)
13 (–)
Type RS42 and RSD42
Type RS41 and RSD41
FIG. 3
FIG. 4
1
2
3
4
8
5
6
7
8
12
9
10
11
12
1
2
4
5
6
9
10
14 (+)
13 (–)
14 (+)
13 (–)
14 (+)
13 (–)
Type RS4, RSD4, RS14, RSD14, RS24, RSD24,
RS34, RSD34, RS44 and RSD44
Type RS43 and RSD43
Control Relays w/ Intrinsically Safe Terminals:
Class 8501 Type TO41 and TO43
FIG. 6
FIG. 5
1
ON
2
3
4
5
6
OFF
SUPPLY
VOLTAGE
OFF
ON
7
8
9
10
11
12
Non-Hazardous Location Terminals
Intrinsically Safe Terminals
Sensing Relays:
RM2 LA1/LG1
FIG. 7
M
H
16
18
B1
B2
A1 15 B3 B1 B2
B1
B2
15
16 18
B3
A2
H
L
H
M
Supply voltage
Supply voltage
L
A1
15
B2
B1 B3
M
B2
B1 B3
16 18
X A2
1 Level
RM2 LG1
H = High level
electrode
L = Low level
electrode
16 18 X
2 Levels
15
M = Reference
electrode
(common)
RM2 LA1
®
30
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IEC Relays
IEC D-Line Control Relays
(for input modules see page 42)
Control Relays: CA2 and CA3
FIG. 1
A1
13 23 33 43
NO NO NO NO
A2
14
24
34
FIG. 2
44
13 21 33 43
NO NC NO NO
A2
14
22
34
FIG. 3
44
3 N.O. & 1 N.C. Instantaneous
CA2 DN31 and CA3 DN31
4 N.O. Instantaneous
CA2 DN40 and CA3 DN40
FIG. 4
A1
A1
13 21 35
NO NC NC
47
NO
A2
14
48
22
36
13 21 31 43
NO NC NC NO
A2
14
22
32
44
2 N.O. & 2 N.C. Instantaneous
CA2 DN22 and CA3 DN22
FIG. 5
2 N.O. & 2 N.C. Instantaneous, w/ 2 Make-Before-Break
CA2 DC22 and CA3 DC22
A1
E1
A1
E2
A2
13 21 31
NO NC NC
14
22
43
NO
32
44
2 N.O. & 2 N.C. Instantaneous w/ Mechanical Latch
CA2 DK22 and CA3 DK22
Front-Mounted Standard Instantaneous Auxiliary Contact Blocks: LA1
FIG. 6
FIG. 7
53 61
NO NC
54
53 63
NO NO
62
54
52
54
62
76
54
54
64
74
FIG. 13
72
52
62
72
53 61 71 81
NO NC NC NC
84
51 61 71 81
NC NC NC NC
84
4 N.O.
LA1 DN40
2 N.O. & 2 N.C. w/ 2 Make-Before-Break
LA1 DC22
62
FIG. 10
54
2 N.O. & 2 N.C.
LA1 DN22
53 63 73 83
NO NO NO NO
88
53 61 71 83
NO NC NC NO
62
2 N.C.
LA1 DN02
FIG. 12
53 61 75 87
NO NC NC NO
FIG. 9
51 61
NC NC
64
2 N.O.
LA1 DN20
1 N.O. & 1 N.C.
LA1 DN11
FIG. 11
FIG. 8
62
72
82
1 N.O. & 3 N.C.
LA1 DN13
FIG. 14
53 61 73 83
NO NC NO NO
82
54
4 N.C.
LA1 DN04
62
74
84
3 N.O. & 1 N.C.
LA1 DN31
Front-Mounted Damp- and Dust-Protected Instantaneous Auxiliary Contact Blocks: LA1
FIG. 15
53
NO
63
NO
54
64
FIG. 16
53
NO
63
NO
54
64
FIG. 17
54
2 N.O. w/ Grounding Screw
LA1 DY20
2 N.O.
LA1 DX20
FIG. 18
53 63 73 83
NO NO NO NO
64
74
53 61 73 83
NO NC NO NO
84
54
2 Dusttight N.O. & 2 N.O.
LA1 DZ40
62
74
84
2 Dusttight N.O. & 1 N.O. & 1 N.C.
LA1 DZ31
Front-Mounted Time Delay Auxiliary Contacts: LA2 and LA3
45
E1
46
E2
FIG. 24
A2
LA6 DK2
58
66
Off Delay, 1 N.O. & 1 N.C.
LA3 DR
53/
NO
83
NO
E2
65
NC
Side-Mounted Auxiliary Contact Blocks: LA8
A1
A2
LA6 DK1
FIG. 23
57
NO
54/
61/
NC
71
NC
E1
68
FIG. 21
62/
1 N.O. & 1 N.C. Instantaneous
LA8 DN11
FIG. 25
53/
NO
83
NO
Front-Mounted Mechanical Latch Adder Blocks: LA6
A1
56
On Delay, 1 N.C. w/ 1 Offset N.O.
LA2 DS
On Delay, 1 N.O. & 1 N.C.
LA2 DT
FIG. 22
67
NO
54/
63/
NO
73
NO
68
55
NC
84
56
FIG. 20
72
67
NO
84
55
NC
74
FIG. 19
64/
2 N.O. Instantaneous
LA8 DN20
®
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31
IEC Relays
Class 8501
Miniature IEC Relays:
Class 8501 Type PR 1
FIG. 1
A1
13 21
NO NC
A2
14
PR 1.11 E
FIG. 2
33 41
NO NC
PRD 1.11 E
A1
PV 11
22
34
42
14
44
PV 02
PRD 1.20 E
A2
PV 20
34
31 41
NC NC
13 23
NO NO
PR 1.20 E
33 43
NO NO
32
24
Type PR 1 and PRD 1 Relays
42
Type PV Adder Decks for PR 1.20 E
Alternating Relays:
Class 8501 Type PHA
FIG. 3
relay coil
A1
13
23
13
14
energized
deenergized
closed
open
14
A2
24
23
24
closed
open
®
32
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Type P Contactors and Type T Overload Relays
Class 8502 and 9065
Power Terminals
FIG. 1
Coil Terminals
1
3
5
2
4
6
FIG. 2
A1
A2
Power terminals on contactors, overloads and switches are single
digits – odd for line side terminals and even for load side terminals.
Coil terminals are designated by a letter and a number. Terminals
for a single winding coil are designated “A1” and “A2”.
Overload Relay Contact Terminals
Auxiliary Contact Terminals
FIG. 3
FIG. 4
Location
13
21
31 43
53
95
97
96 98
With Isolated
N.O. Alarm Contact
14
22
32 44
95
Status
(N.O. or N.C.)
54
Auxiliary contacts on contactors, relays and push button contacts
use 2-digit terminal designations, as shown in the diagram above.
The first digit indicates the location of the contact on the device. The
second digit indicates the status of the contacts, N.O. or N.C. “1”
and “2” indicate N.C. contacts. “3” and “4” indicate N.O. contacts.
96 98
With Non-Isolated
N.O. Alarm Contact
Overload contact terminals are marked with two digits. The first
digit is “9”. The second digits are “5” and “6” for a N.C. and “7” and
“8” for a N.O. isolated contact. If the device has a non-isolated
alarm contact (single pole), the second digits of the N.O. terminals
are “5” and “8”.
Class 8502 Type PD or PE Contactor
w/ Class 9065 Type TR Overload Relay
FIG. 5
FPO 30-2 120%
Wiring Diagram
FPO 30-2 120%
Elementary Diagram
®
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33
Type P Contactors and Type T Overload Relays
Class 8502 and 9065
Class 8502 Type PG or PD Contactor
w/ Class 9065 Type TD Overload Relay
FIG. 1
FPO 30-3 120%
FPO 30-3 120%
Wiring Diagram
Elementary Diagram
Class 8502 Type PE Contactor
w/ Class 9065 Type TE Overload Relay
FIG. 2
FPO 30-4 120%
FPO 30-4 120%
Elementary Diagram
Wiring Diagram
Class 8502 Type PF, PG or PJ Contactor
w/ Class 9065 Type TF, TG or TJ Overload Relay
FIG. 3
FPO 31-1 120%
FPO 31-1 120%
Wiring Diagram
Elementary Diagram
®
34
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Type P Reversing Contactors and Type T Overload Relays
Class 8502, 8702 and 9065
Class 8502 Type PJ or PK Contactor
w/ Class 9065 Type TJE Overload Relay
FIG. 4
FPO 31-2 120%
FPO 31-2 120%
Wiring Diagram
Elementary Diagram
Class 8702 Type PDV or PEV Reversing Contactor
w/ Class 9065 Type TR Overload Relay
FIG. 1
FPO 31-3
Elementary Diagram
FPO 31-3 120%
Elementary Diagram
®
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35
Type S AC Magnetic Contactors
Class 8502
AC Magnetic Contactors:
Class 8502 Type S
FIG. 1
3
L1
FIG. 2
L2
3
T1
L2
T1
MOTOR
T1
T2
T2
T1
2
1-Pole, Size 0 and 1
FIG. 3
2-Pole, Size 00, 0 and 1
FIG. 4
3
L1
3
L2
1
T2
T1 T2 T3
MOTOR
L1
L2
L3
T1
T2
T3
1
MOTOR
2
T1
T2
2
3-Pole, Size 00 to 5
2-Pole, Size 2 to 5
FIG. 5
L2
MOTOR
2
T1
L1
1
1
FIG. 6
3
L1
T1 T3 T4 T2
L3
L4
3
L2
L1
1
L2
L3
T2
T3
T1 T2 T3
X2
MOTOR
MOTOR
2
T1
T3
T4
T2
2
4-Pole, Size 0, 1 and 2
T1
5-Pole, Size 0, 1 and 2
FIG. 7
FIG. 8
TO
SEPARATE
CONTROL
2- and 3-Wire Control for Figure 1 to 5
3
X2
Separate Control for Figure 6
®
36
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Type S AC Magnetic Contactors
Class 8502
Size 6, 3-Pole Contactor – Common Control
Class 8502 Type SH Series B
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Short-Circuit Protection
Rating of branch circuit protective device must
comply with applicable electrical codes and the
following limitations:
Max. Rating
Type of Device
Class K5 or RK5 time-delay fuse 600 A
Class J, T or L fuse
1200 A
Inverse-time circuit breaker
800 A
Elementary Diagram
®
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37
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Type S AC Magnetic Contactors
Class 8502
Size 6, 3-Pole Contactor – Separate Control
Class 8502 Type SH Form S Series B
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Short-Circuit Protection
Rating of branch circuit protective device must
comply with applicable electrical codes and the
following limitations:
Max. Rating
Type of Device
Class K5 or RK5 time-delay fuse 600 A
Class J, T or L fuse
1200 A
Inverse-time circuit breaker
800 A
Elementary Diagram
®
38
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Type S AC Magnetic Contactors
Class 8502
Size 7, 3-Pole Contactor – Common Control
Class 8502 Type SJ Series A
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Short-Circuit Protection
Rating of branch circuit protective device must
comply with applicable electrical codes and the
following limitations:
Max. Rating
Type of Device
Class K5 or RK5 time-delay fuse 600 A
Class J, T or L fuse
1600 A
Inverse-time circuit breaker
2000 A
Elementary Diagram
®
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39
Type S AC Magnetic Contactors
Class 8502
Size 7, 3-Pole Contactor – Separate Control
Class 8502 Type SJ Form S Series A
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Short-Circuit Protection
Rating of branch circuit protective device must
comply with applicable electrical codes and the
following limitations:
Max. Rating
Type of Device
Class K5 or RK5 time-delay fuse 600 A
Class J, T or L fuse
1600 A
Inverse-time circuit breaker
2000 A
Elementary Diagram
®
40
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IEC Contactors
IEC Contactors and Auxiliary Contact Blocks
(for Input Modules see page 42)
3- and 4-Pole Contactors: LC1 and LP1
(Terminal markings conform to standards EN 50011 and 50012)
FIG. 1
A1
A2
1
L1
3
L2
5 13
L3 NO
T1
2
T2
4
T3
6
FIG. 2
A1
A2
14
A1
A2
5 21
L3 NC
T1
2
T3
6 22
T2
4
FIG. 3
1
L1
3
L2
5
L3
7
L4
T1
2
T2
4
T3
6
T4
8
FIG. 5
A1
1
A2
R1
2
A2
FIG. 6
3
R4
4
D12 008 and D25 008
D12 004 to D80 004
T1
2
5
L3
T2
4
13 21
NO NC
T3
6
14
22
D40 11 to D95 11
R3
R2
1
3
L1 L2
A1
D09 01 to D32 01
D09 10 to D32 10
FIG. 4
1
3
L1 L2
A1
R1
1
3 R3
A2
R2
2
4 R4
D40 008 to D80 008
Front-Mounted Standard Instantaneous Auxiliary Contact Blocks: LA1
FIG. 8
94
FIG. 7
43
54
FIG. 10
53 63
NO NO
62
54
FIG. 11
51 61
NO NO
64
52
53
NO
62
54
61 71
NC NC
83
NO
62
84
72
FIG. 12
53
NO
61 71
NC NC
54
62
81
NC
72
82
93
44
1 N.O. & 1 N.C
LA1 DN 11
1 N.O.
LA1 DN 10
FIG. 14
92
FIG. 13
FIG. 9
53 61
NO NC
NO
41
NO
2 N.O.
LA1 DN 20
53
NO
61 75
NC NC
54
62
FIG. 15
87
NO
76
2 N.C.
LA1 DN 02
53
NC
54
88
63 73
NC NC
64
74
2 N.O. & 2 N.C.
LA1 DN 22
FIG. 16
83
NC
51
NC
84
61 71
NC NC
52
62
72
1 N.O. & 3 N.C.
LA1 DN 13
FIG. 17
81
NC
82
53
NO
61 73
NC NO
83
NO
54
62
84
74
91
42
2 N.O. & 2 N.C. w/
2 Make-Before-Break
LA1 DC 22
1 N.C.
LA1 DN 01
4 N.O.
LA1 DN 40
4 N.C.
LA1 DN 04
3 N.O. & 1 N.C.
LA1 DN 31
Front-Mounted Damp- and Dust-Protected (IP 54) Instantaneous Auxiliary Contact Blocks: LA1
FIG. 18
53
N0
63
NO
54
64
FIG. 19
53
N0
63
NO
54
64
FIG. 20
53
N0
63
N0
73
N0
83
N0
54
64
74
84
FIG. 21
53 61
N0 NC
73
N0
83
N0
54 62
74
84
2 N.O. (5-24 V) w/ Grounding Screw 2 Dusttight N.O. (24-50 V) & 2 N.O. 2 Dusttight N.O. (24-50 V) & 1 N.O. & 1 N.C.
LA1 DY 20
LA1 DZ 40
LA1 DZ 31
2 N.O.
LA1 DX 20
Front-Mounted Time Delay Auxiliary Contacts: LA2 and LA3
56
On Delay, 1 N.O. w/ 1 Offset N.O.
LA2 DS•
E1
45
E1
46
E2
Side-Mounted Auxiliary Contact Blocks: LA8
FIG. 27
A1
A2
A2
LA6 DK 2, LA6 DK 3
53/
NO
83
NO
E2
LA6 DK 1
FIG. 26
Off Delay, 1 N.O. & 1 N.C.
LA3 DR•
54/
61/
NC
71
NC
A1
66
62/
1 N.O. & 1 N.C. Instantaneous
LA8 DN 11
FIG. 28
53/
NO
83
NO
Front-Mounted Mechanical Latch Adder Blocks: LA6
FIG. 25
58
84
On Delay, 1 N.O. & 1 N.C.
LA2 DT•
68
54/
63/
NO
73
NO
68
57 65
NO NC
72
56
FIG. 24
55 67
NC NO
84
FIG. 23
55 67
NC NO
74
FIG. 22
64/
2 N.O. Instantaneous
LA8 DN 20
®
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41
IEC Contactors
Input Modules and Reversing Contactors
Input Modules:
LA4
FIG. 2
FIG. 1
FIG. 3
AC/DC
PLC
AC
A1
A2
B2
A1
A2
AC/DC
B1
A1
A2
A/M
0
0
t
A1
A2
A1
+
E1
A1
A2
K
K
Off Delay Timer Module
LA4 DR
On Delay Timer Module
LA4 DT
AC
A1
1/0
A2
K
FIG. 4
t
E2
AC
A2
A1
FIG. 5
AC
A1
+
E1
E2
A1
A2
Auto-Manual-Off Control Module
LA4 DM
AC
A2
FIG. 6
AC
A1
A2
+
E1
A1
K
Relay Interface Amplifier Module w/
Manual Override, LA4 DL
Relay Interface Amplifier Module
LA4 DF
AC
A2
A2
K
K
E2
Solid State Interface Amplifier Module
LA4 DW
Contactors:
LC2, LP2 and LA9
FIG. 8
FIG. 7
A1
1
3
5
1
3
5 A1
A2
2
4
6
2
4
6 A2
FIG. 9
01
01
U
V W
A1
1
3
5
7
1
3
5
7
A1
A2
2
4
6
8
2
4
6
8
A2
A1
A1
A2
A2
02
21
21
02
KM2
KM2
22
KM1
A2
22
KM1
A2
Reversing Contactor
3-Pole, for Motor Control
LC2, LP2 D0901 to D3201
Transfer Contactor,
4-Pole, Mechanically Interlocked
LC2, LP2 D12004 to D8004
Mechanical Interlock w/ Electrical Interlock
LA9 D0902, D4002 and D8002
®
42
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Type S AC Magnetic Starters
Class 8536
1-Phase, Size 00 to 3
1-Pole, 1-Phase Magnetic Starters, Size 00 to 3:
Class 8536 Type S
FIG. 1
* Marked “OL” if alarm
contact is supplied
Wiring Diagram
Elementary Diagram
Single Phase Starter w/ Single Voltage Motor
FIG. 2
* Marked “OL” if alarm
contact is supplied
Note: Starters are factory-wired with coil connected for
the higher voltage. If starter is used on lower
voltage, connect per coil diagram.
Wiring Diagram
Elementary Diagram
Single Phase Starter w/ Dual Voltage Motor
3-Pole, 3-Phase Magnetic Starters, Size 00 to 3, Connected for Single Phase:
Class 8536 Type S
FIG. 3
* Marked “OL” if alarm contact is supplied
Wiring Diagram
Elementary Diagram
3-Phase Starter Connected for Single Phase, Single Voltage Motor
®
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43
Type S AC Magnetic Starters
Class 8536
2-Phase and 3-Phase, Size 00 to 5
4-Pole, 2-Phase Magnetic Starters:
Class 8536 Type S
FIG. 1
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 0, 1 and 2
FIG. 2
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 3 and 4
3-Pole, 3-Phase Magnetic Starters:
Class 8536 Type S
FIG. 3
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 00 to 4
FIG. 4
▲ If alarm contact is supplied, a single (3 thermal unit)
overload block is furnished, fed from 3 current transformers.
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 5
®
44
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Type S AC Magnetic Starters
Class 8536, 8538 and 8539
3-Phase, Size 6
3-Pole, 3-Phase Magnetic Starters, Size 6 – Common Control
Class 8536/8538/8539 Type SH Series B
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Elementary Diagram
®
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45
Type S AC Magnetic Starters
Class 8536
3-Phase, Size 7
3-Pole, 3-Phase Magnetic Starters, Size 7 – Common Control
Class 8536 Type SJ Series A
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Elementary Diagram
®
46
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Type S AC Magnetic Starters
Class 8536
3-Phase Additions and Special Features
3-Pole, 3-Phase Magnetic Starters, Size 00 to 4:
Class 8536 Type S
FIG. 1
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Form A – Start-Stop Push Button Mounted in Cover
FIG. 2
* Marked “OL” if alarm
contact is supplied
Wiring Diagram
Elementary Diagram
Form C – Hand-Off-Auto Selector Switch Mounted in Cover
FIG. 3
* Marked “OL” if alarm contact is supplied
∆ Single or dual voltage primary connection
per transformer nameplate.
Wiring Diagram
∆ Single or dual voltage primary connection
per transformer nameplate.
Elementary Diagram
Form F4T – Control Circuit Transformer and Primary Fuses
®
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47
Type S AC Magnetic Starters
Class 8536
3-Phase Additions and Special Features
3-Pole, 3-Phase Magnetic Starters, Size 00 to 4:
Class 8536 Type S
FIG. 1
* Marked “OL” if alarm
contact is supplied
Elementary Diagram
Wiring Diagram
Form S – Separate Control
FIG. 2
* Marked “OL” if alarm contact is supplied
On NEMA Size 3 and 4 starters, holding circuit contact is in position
#1. Max. of 3 external auxiliary contacts on NEMA Size 00.
Wiring Diagram
Elementary Diagram
Form X – Additional Auxiliary Contacts
3-Pole, 3-Phase Magnetic Starters, Size 5:
Class 8536 Type S
FIG. 3
∆
* Marked “OL” if alarm contact is supplied
∆ If alarm contact is supplied, a single (3 thermal unit) overload
block is furnished, fed from 3 current transformers
Wiring Diagram
Elementary Diagram
Form F4T – Control Circuit Transformer and Primary Fuses
®
48
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Type S AC Magnetic Starters
Class 8536, 8538 and 8539
3-Phase Additions and Special Features
3-Pole, 3-Phase Magnetic Starters, Size 6 – Separate Control
Class 8536/8538/8539 Type SH Form S Series B
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Elementary Diagram
®
www.epdatech.com
49
Type S AC Magnetic Starters
Class 8536
3-Phase Additions and Special Features
3-Pole, 3-Phase Magnetic Starters, Size 7 – Separate Control
Class 8536 Type SJ Form S Series A
FIG. 1
Wiring Diagram
This symbol denotes the coil function,
provided by a solid-state control module,
30 VA transformer, two fuses in the
secondary of the transformer, N.C.
electrical interlock and DC magnet coil.
Elementary Diagram
®
50
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Integral Self-Protected Starters
Integral 18
State of Auxiliary Contacts
State of Auxiliary Contacts for LD1
FIG. 1
LD1
Auxiliary contact actuators
1
3
5
L1 L2 L3
AUTO
+
0
AUTO
+
0
A1 A2
Auxiliary contacts
2
LA1-LB019
LA1-LB017
LA1-LB015
LA1LB001
LA1LB031
LA1-LB034
T1 T2 T3
4
6
Contact open
Contact closed
Off
AUTO
On, contactor
open
AUTO
On, contactor
closed
13 23 31
95 97
13 31
97
13 31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
13 23 31
95 97
13
31
97
13
31
95
41
16 18
16 18
6
8
14 24 32
96 98
14 32
98
14 32
96
42
15 17
15 17
5
7
TRIP. +
Tripped on
overload
Tripped on
short circuit
Off after short
circuit
Manual reset
TRIP. +
TRIP. +
TRIP. +
RESET
®
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Integral Self-Protected Starters
Integral 18
State of Auxiliary Contacts
State of Auxiliary Contacts for LD5
FIG. 1
LD5
Auxiliary contact actuators
1 3 5
L1 L2 L3
A1A2
AUTO
+ 0
A1A2
Auxiliary contacts
LA1-LB015
2
Contact open
Contact closed
T1 T2 T3
4
6
Off
AUTO
On, contactor
open
AUTO
On, contactor II
closed
AUTO
On, contactor I
closed
Tripped on
overload
Tripped on
short circuit
Off after short
circuit
Manual reset
LA1-LB019
LA1-LB017
LA1LB001
LA1-LB021
LA1LB001
On
Integral
13 23 31
95 97
13 31
97
13 31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
13 23 31
95 97
13
31
97
13
31
95
41
13 23 31
16 18
41
6
8
14 24 32
96 98
14 32
98
14 32
96
42
14 24 32
15 17
42
5
7
TRIP. +
TRIP. +
TRIP. +
TRIP. +
RESET
®
52
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Integral Self-Protected Starters
Integral 32 and 63
State of Auxiliary Contacts
State of Auxiliary Contacts for LD4
FIG. 1
LD4
Auxiliary contact actuators
1 3 5
L1 L2 L3
AUTO
+ 0
U
U
A1 A2
Auxiliary contacts
T1 T2 T3
2 4 6
Contact open
Contact closed
LD4
LA1-LC010
LA1-LC012
LA1-LC020
LA1-LC030
98
13 23 31
(63)
53
05
95
14 24 32
54
(64)
08
98
13 23 31
53
14 24 32
05
95
14 24 32
54
13 23 31
08
98
13 23 31
53
14 24 32
05
95
14 24 32
54
13 23 31
08
98
13 23 31
53
14 24 32
05
95
14 24 32
54
96 98
13 23 31
08
98
13 23 31
53
95
14 24 32
05
95
14 24 32
54
06 08
96 98
13 23 31
08
98
13 23 31
53
05
95
14 24 32
05
95
14 24 32
54
16 18
06 08
96 98
13 23 31
08
98
13 23 31
53
14 24 32
15
05
95
14 24 32
05
95
14 24 32
54
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
53
14 24 32
15
05
95
14 24 32
05
95
14 24 32
54
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
53
14 24 32
15
05
95
14 24 32
05
95
14 24 32
54
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
53
14 24 32
15
05
95
14 24 32
05
95
14 24 32
54
13 23 31
16 18
06 08
96 98
13 23 31
14 24 32
15
05
95
14 24 32
13 23 31
16 18
06 08
96 98
13 23 31
14 24 32
15
05
95
13 23 31
16 18
06 08
96 98
14 24 32
15
05
95
13 23 31
16 18
06 08
96 98
14 24 32
15
05
95
13 23 31
16 18
06 08
14 24 32
15
05
13 23 31
16 18
14 24 32
15
13 23 31
08
Off + isolation
Off
On, contactor open
AUTO
On, contactor closed
AUTO
Tripped, on overload
TRIP. +
Off, after overload
TRIP. +
Tripped, on short circuit
TRIP. +
Off, after short circuit
TRIP. +
Manual reset
TRIP. +
RESET
®
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53
Integral Self-Protected Starters
Integral 32 and 63
State of Auxiliary Contacts
State of Auxiliary Contacts for LD5
FIG. 1
LD5
Auxiliary contact actuators
1 3 5
L1 L2 L3
AUTO
A2 A1
+ 0
U
A2 A1
U
Auxiliary contacts
LA1-LC010
T1 T2 T3
2 4 6
LA1-LC012
LA1-LC020
LA1-LC021
98
13 23 31
13 23 31
53 63
LA1-LC031
13 23 31
16 18
06 08
96 98
13 23 31
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
08
Contact open
Contact closed
Off + isolation
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
14 24 32
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
13 23 31
16 18
06 08
96 98
13 23 31
08
98
13 23 31
13 23 31
53 63
15
05
95
14 24 32
05
95
14 24 32
14 24 32
54 64
Off
On, both contactors open
AUTO
On, contactor
open
AUTO
On, contactor
closed
AUTO
Tripped on overload
TRIP. +
Off, after overload
TRIP. +
Tripped on short circuit
TRIP. +
Off after short circuit
TRIP. +
Manual reset
TRIP. +
14 24 32
RESET
®
54
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Integral Self-Protected Starters
Wiring Diagrams
Integral 18
FIG. 1
FIG. 2
1
3
5
L1
L2
L3
1
3
5
L1 L2 L3
A1 A2
A1 A2
A1 A2
I
T1
2
II
T2 T3
4
6
T1
T2
4
2
T3
6
Self-Protected Reversing Starter w/ Protection Module LB•
Integral 18 LD5 LB130 + LB1 LB03P
Self-Protected Starter w/ Protection Module LB•
Integral 18 LD1 L80
Integral 32
FIG. 3
FIG. 5
1
3
5
L1 L2 L3
A1 A2
g
(
1
L1
T1 T2 T3
2
4
6
A1
3
L2
)
5
L3
A2
A1
A2
Starter w/ Isolator
Integral 32 LD4
FIG. 4
External
control
circuit
1
3
5
L1 L2 L3
A1 A2
Handle
operator
Control
circuit
contact
Instantaneous
trip
mechanism
(Trip coil)
Protection
module
trip
mechanism
T1 T2 T3
2
4
6
Protection module
Thermal trip
Magnetic trip
T1 T2 T3
2
4
6
Reversing Starter w/ Isolator
Integral 32 LD5
Starter w/o Isolator
Integral 32 LD1
Protection Modules: LB•
FIG. 6
FIG. 7
T1 T2 T3
2
4
6
Thermal and Magnetic Trip
LB1
T1 T2 T3
2
4
6
Magnetic Trip Only
LB6
®
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55
Integral Self-Protected Starters
Wiring Diagrams
Auxiliary Contact Blocks
FIG. 1
LA1 LC010
LA1 LC012
LA1 LC020
13 23 31
13 23 31
13 23 31
14 24 32
14 24 32
14 24 32
9698
98
95
95
0608
08
05
05
Trip signal
1
Short-circuit signal
Knob position signal
Auto + O
16
1
Contactor signalling placed
on the right
18
15
For LD1 or LD4 and reverser LD5 (mounted on right)
LA1 LC010, LA1 LC012 and LA1 LC020
FIG. 2
FIG. 3
LA1 LC030
(63)
53
(63)
53
54
(64)
54
(64)
1 or 2 LA1 LC030
Remote Reset Units1
for LD1, LD4 and LD5
AUTO
TRIP
+
O
RESET
AC
B4
AC
M
B1
13 23 31
LA1 LC031
14 24 32
2
Contactor signalling placed
on the left
Isolating contacts
(mounted on left)
LA1 LC031
Trip Units
for LD1, LD4 and LD5
Use of the
LA1 LC020
contact
block
prevents the
mounting
of trip or
remote units
FIG. 6
AC A1
+ E1
- E1
AC A2
C1
A1
A2
D1
LA1 LC180, LA1 LD180
U<
C2
D2
FIG. 8
AC A1
+ E1
- E1
AC A2
For starter and reverser already fitted
with a block, LA1 LC010 or LA1 LC012.
LA1 LC052
Interface Modules
FIG. 7
B2
B3
FIG. 4
2
For reversing LD5
(mounted on left)
LA1 LC021
For LD4 w/ isolating contacts
(mounted on left)
LA1 LC030
FIG. 5
LA1 LC021
LA1 LC07••
A1
A2
LA1 LC580, LA1 LD580
®
56
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Integral Self-Protected Starters
Wiring Diagrams
Add-on Blocks: LA1 LB0••
FIG. 1
Contactor breakers
Trip signal
LA1 LB015
13 23 31
LA1 LB017
13
31
LA1 LB019
13
31
14
24 32
14
14
95
97
97
95
96
98
98
96
32
LA1 LB001
41
32
42
and
For LD1 (mounted on right)
FIG. 2
FIG. 3
LA1 - LB034
5
7
6
LA1 - LB031
Knob position
8
15
17
42
15 17
Signal
16
18
Contacts integrated
into device
14 24 32
5
7
6
8
Short
circuit
signal
0
Auto
15 17
Short
circuit
signal
Contactor breakers
LA1 - LB021
13 23 31
LA1 - LB001
41
Auto
0
Signal
16 18
16 18
For LD1 (mounted on left)
For LD5 (mounted on left)
Time Delay Modules
FIG. 4
Control Module
FIG. 5
AC
A1
Knob position
AC
A1
A2
FIG. 6
A2
B2
TSX
AC
B1
A1
0
t
0
A1
A2
A/M
1/0
t
A2
A1
A1
K
K
On Module
LA4 DT
A2
A2
K
Off Module
LA4 DR
Auto-Man-Stop Module
LA4 DM
Interface Modules
FIG. 7
AC
A1
+
-
E1
AC
A2
E2
A1
FIG. 8
+
AC
A1
-
E1
A1
A2
AC
A2
E2
FIG. 9
AC
A1
Solid State Module
LA4 DW
-
AC
A2
E2
A1
A2
A2
K
K
K
+
E1
Relay Module
LA4 DF
Relay Module w/ Manual Override
LA4 DL
Voltage Converters: LA1 LC080 and LA1 LD080
FIG. 11
Control by supply switching 24 or 48V
E1
+
A1
DC
- (OV) E3
AC
A2
FIG. 12
110V
+
A1
DC
- (OV) E2
Low voltage control 24 or 48V
E1
E1
Supply
FIG. 10
AC
A2
E3 +
{-
A1
DC
AC
A2
E2
E2
Low voltage input
For 24 or 48 V Supply
For 110 V Supply
For 24 or 48 V Supply w/ Low Voltage Input
®
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57
Type S AC Combination Magnetic Starters
Class 8538 and 8539
3-Phase, Size 0-5 (see pages 45 and 49 for Size 6)
3-Pole, 3-Phase Combination Starters:
Class 8538 and 8539 Type S
FIG. 1
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 0-4
FIG. 2
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 5
®
58
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Type S AC Combination Magnetic Starters
Class 8538 and 8539
3-Phase Additions and Special Features
3-Pole, 3-Phase Combination Starters w/ Control Circuit Transformer and Primary Fuses:
Class 8538 and 8539 Type S Form F4T
FIG. 1
L1
L2
L3
2-WIRE CONTROL
(If used)
2
START
DISCONNECTING MEANS,
PROVIDED BY USER OR
WITH CONTROLLER
3
START
1 STOP
2
OL
3
M
M
STOP
L1
1
L2
L3
FU2
X2
X1
3-WIRE CONTROL
FU1
SEC
3
1
PRI
FU2
FU1
GROUND
(If used)
PRI
X2
M
SEC
3
A
2-WIRE CONTROL
GROUND
(If used)
ALARM (IF
SUPPLIED)
T1 T2 T3
A
*
T1
L1
L2
OL
COM
MOTOR
1
DISCONNECTING
MEANS
2
T2
L3
T3
M
OL
M
OL
M
OL
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 0-4
FIG. 2
L1
L2
L3
2-WIRE CONTROL
(If used)
2
START
DISCONNECTING MEANS,
PROVIDED BY USER OR
WITH CONTROLLER
3
START
1 STOP
2
OL
3
CR
STOP
M
CR
1
3-WIRE CONTROL
X2
X1
1
L1
L2
L3
SEC
FU2
FU1
FU1
3
PRI
M
X2
M
T1 T2 T3
A
A
GROUND
(If used)
ALARM (IF
SUPPLIED)
*
COM
1
L1
L2
OL
L3
T1
T2
DISCONNECTING
MEANS
SEC
2
MOTOR
GROUND
(If used)
CR
3
2-WIRE CONTROL
FU2
PRI
M
OL
M
OL
M
OL
T3
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 5
®
www.epdatech.com
59
Reduced Voltage Controllers
Class 8606
Autotransformer Type, Size 2-6
Reduced Voltage Autotransformer Controllers w/ Closed Transition Starting: Class 8606 Size 2-5
FIG. 1
L3
50
0
100
84
65
OL
T1
OL
T2
1S
AT
R
2S
MOTOR
AT
2S
1S
R
TR
0
L2
2S
100
84
65
50
L1
CIRCUIT BREAKER
OR DISCONNECT SWITCH
R
OL
T3
1S
TR
R
R
1S
1S
2S
2S
2 WIRE CONTROL DEVICE (IF USED)
START
STOP
OL
3
2
1
TR
TR
Reduced Voltage Autotransformer Controller w/ Closed Transition Starting: Class 8606 Size 6
FIG. 2
L3
50
0
100
84
65
2S
T1
1OL
1S
AT
R
2CT
T2
2S
MOTOR
2OL
AT
2S
R
1S
0
L2
1CT
100
84
65
50
L1
CIRCUIT BREAKER
OR DISCONNECT SWITCH
R
3CT
T3
3OL
1TR
R
1TR
1S
1S
2TR
2TR
2S
R
1S 2S
(H1) PRI
(X1) SEC
(X2)
R
(H1)
PRI
(X1)
SEC
(X2)
2 WIRE CONTROL DEVICE (if used)
START
STOP
1
GROUND
(if used)
3
2
OL
1TR
1TR
®
60
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Reduced Voltage Controllers
Class 8606
Autotransformer Type, Size 7
Reduced Voltage Autotransformer Controllers w/ Closed Transition Starting:
Class 8606 Size 7
FIG. 1
L3
50
0
100
84
65
1CT
T1
2CT
T2
1S
AT
R
2S
MOTOR
AT
2S
1S
R
0
L2
2S
100
84
65
50
L1
CIRCUIT BREAKER
OR DISCONNECT SWITCH
R
3CT
T3
SOLID STATE
OVERLOAD RELAY
1TR
R
(H1) PRI
1TR
(X1) SEC
(X2)
1S
1S
2TR
2TR
(H1) PRI
(X1) SEC
(X2)
2S
R
1S 2S
(H1) PRI
(X1) SEC
(X2)
R
(H1)
PRI
(X1)
SEC
(X2)
2 WIRE CONTROL DEVICE (If used)
START
STOP
1
GROUND
(If used)
3
2
OL
1TR
1TR
®
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61
Reduced Voltage Controllers
Class 8630
Wye-Delta Type, Size 1Y∆-5Y∆
Wye-Delta Type Reduced Voltage Controllers, Size 1Y∆-5Y∆:
Class 8630
FIG. 1
FPO
46-1
110%
Size 1Y∆-5Y∆ Controllers with Open-Transition Starting
FIG. 2
FPO
46-2
110%
Size 1Y∆-5Y∆ Controllers with Closed-Transition Starting
®
62
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Reduced Voltage Controllers
Class 8630
Wye-Delta Type, Size 6Y∆
Wye-Delta Type Reduced Voltage Controllers, Size 6Y∆:
Class 8630
FIG. 1
FPO
46-3
110%
Size 6Y∆ Controller with Open-Transition Starting
FIG. 2
FPO
46-4
110%
Size 6Y∆ Controller with Closed-Transition Starting
®
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63
Reduced Voltage Controllers
Class 8640
2-Step, Part-Winding Type
Table 5
Motor Lead Connections
Part Winding Schemes
1/2 Wye or Delta 6 Leads
1/2 Wye 9 Leads
[1]
1/2 Delta 9 Leads
[1]
[2]
A
T1
Lettered Terminals in Panel
B
C
D
E
F
T2
T3
T7
T8
T9
T1
T2
T3
T7
T8
T9
T1
T8
T3
T6
T2
T9
Connect terminals T4, T5 and T6 together at terminal box.
[2]
Part Winding Schemes
Lettered Terminals in Panel
B
C
D
E
F
T2
T9
T7
T8
T3
2/3 Wye or Delta 6 Leads
A
T1
2/3 Wye 9 Leads [1]
T1
T2
T9
T7
T8
T3
T1
T4
T9
T6
T2
T3
2/3 Delta 9 Leads
[2]
Connect terminals T4 and T8, T5 and T9, T6 and T7 together in 3 separate pairs at terminal box.
Part-Winding Reduced Voltage Controllers: Class 8640, Size 1PW-7PW
FIG. 2
FIG. 1
Size 1PW-4PW, 2-Step Part-Winding Controllers
Size 5PW, 2-Step Part-Winding Controller
FIG. 4
FIG. 3
Size 6PW, 2-Step Part-Winding Controller
➀ Disconnect means (optional): 2 required, 1 for each motor winding.
Size 7PW, 2-Step Part-Winding Controller
➁ See Table 5 for motor lead connections.
®
64
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Reduced Voltage Controllers
Class 8647
Primary-Resistor Type
3-Phase Primary-Resistor Reduced Voltage Controllers:
Class 8647, Size 1-7
FIG. 1
RES
M
L3
FIG. 2
T1
M
DISCONNECT MEANS
(OPTIONAL)
L2
OL
L1
DISCONNECT MEANS
(OPTIONAL)
L1
A
RES
M
OL
T2
L2
MOTOR
A
RES
M
OL
T3
L3
RES
OL
T1
RES
OL
T2
A
M
MOTOR
A
RES
M
OL
T3
A
A
TR
A
TR
M
M
TR
TR
A
A
2 WIRE CONTROL DEVICE (if used)
2 WIRE CONTROL DEVICE (if used)
START
STOP
1
3
2
START
STOP
OL
1
TR
TR
Size 5
L3
1CT
RES
A
M
2CT
M
L1
T2
MOTOR
A
L2
2OL
3CT
RES
A
F
U
2
T1
1OL
RES
M
FIG. 4
T3
L3
3OL
DISCONNECT MEANS
(OPTIONAL)
L2
DISCONNECT MEANS
(OPTIONAL)
M
L1
F
U
3
1TR
M
1CT
T1
RES
2CT
T2
MOTOR
A
M
RES
3CT
T3
A
SOLID STATE
OVERLOAD RELAY
F
U
3
1TR
2TR
RES
A
F
U
2
1TR
TR
TR
Size 1-4
FIG. 3
OL
3
2
1TR
2TR
2TR
2TR
M
(H1) PRI
M
A
(X1) SEC
(H1) PRI
(X1) SEC
M
M
(X2)
A
(H1) PRI
A
(H1)
PRI
FU1 (X1)
SEC
(X1) SEC
(X2)
(X2)
A
2 WIRE CONTROL DEVICE (if used)
(H1)
PRI
FU1 (X1)
SEC
GROUND
(if used)
START
STOP
1
(X2)
3
2
OL
1TR
1TR
(X2)
2 WIRE CONTROL DEVICE (if used)
START
STOP
1
GROUND
(if used)
3
2
OL
1TR
1TR
Size 7
Size 6
®
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65
Reduced Voltage Controllers
Class 8650 and 8651
Wound-Rotor Type
Wound-Rotor Reduced Voltage Controllers:
Class 8650 and 8651
FIG. 1
FPO 49-3
135%
Non-Reversing Wound-Rotor Motor Controller w/ 3 Points of Acceleration
Class 8650
FIG. 2
FPO 49-4
135%
Reversing Wound-Rotor Motor Controller w/ 3 Points of Acceleration
Class 8651
®
66
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Solid State Reduced Voltage Starters
Class 8660
®, Type MD-MG
ALPHA PAK
ALPHA PAK® Solid State Reduced Voltage Starters:
Class 8660 Type MD-MG
FIG. 1
1CT
CIRCUIT BREAKER
OR DISCONNECT SWITCH
M
L1
L2
L3
T1
T2
M
MOTOR
3CT
M
T3
SOLID STATE
OVERLOAD RELAY
TO 120 V
SEPARATE
CONTROL
STOP
START
OT*
* OT is a switch that opens
when an overtemperature
condition exists (Type MFO
and MGO only)
M
M
Type MD (16 A), ME (32 A), MF (64 A) and MG (128 A)
L1
L2
L3
CIRCUIT BREAKER
OR DISCONNECT SWITCH
FIG. 2
ISO
M
ISO
M
1CT
T1
T2
MOTOR
ISO
3CT
M
T3
SOLID STATE
OVERLOAD RELAY
TO 120 V
SEPARATE
CONTROL
STOP
START
OT*
M
M
CR
* OT is a switch that opens
when an overtemperature
condition exists (Type MFO
and MGO only)
TR
TR
ISO
ALARM
CR
Type MD (16 A), ME (32 A), MF (64 A) and MG (128 A) w/ Isolation Contactor
®
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67
Solid State Reduced Voltage Controllers
Class 8660
Type MH, MJ, MK and MM
Solid State Reduced Voltage Controllers: Class 8660 Type MH, MJ, MK and MM
FIG. 1
Type MH (200 A), MJ (320 A), MK (500 A) and MM (750 A)
FIG. 2
Type MH (200 A) w/ Shorting Contactor
FIG. 3
Type MJ (320 A), MK (500 A) and MM (750 A) w/ Shorting Contactor
®
68
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Solid State Reduced Voltage Controllers
Class 8660
Type MH, MJ, MK and MM
Solid State Reduced Voltage Controllers: Class 8660 Type MH, MJ, MK and MM
FIG. 1
FPO
51-1
130%
Type MH (200 A) w/ Isolation Contactor
FIG. 2
FPO
51-2
130%
Type MJ (320 A), MK (500 A) and MM (750 A) w/ Isolation Contactor
®
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69
Solid State Reduced Voltage Controllers
Class 8660
Type MH, MJ, MK and MM
Solid State Reduced Voltage Controllers: Class 8660 Type MH, MJ, MK and MM
FIG. 1
FPO
51-3
130%
Type MH (200 A) w/ Isolation Contactor and Shorting Contactor
FIG. 2
FPO
51-4
130%
Type MJ (320 A), MK (500 A) and MM (750 A) w/ Isolation Contactor and Shorting Contactor
®
70
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Type S AC Reversing Magnetic Starters
Class 8736
2- and 3-Pole
Reversing Starters, 2- and 3-Pole, Size 00-1:
Class 8736 Type S
FPO 52-1
FIG. 1
FPO 52-1
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
2-Pole, w/ Single Phase, 3-Lead Motor
FIG. 2
FPO 52-2
* Marked “OL” if alarm contact is supplied
FPO
52-2
Elementary Diagram
Wiring Diagram
3-Pole, w/ Single Phase, 4-Lead Repulsion-Induction Motor
FPO 53-1
FIG. 3
FPO 53-1
* Marked “OL” if alarm contact is supplied
Wiring Diagram
Elementary Diagram
3-Pole, w/ Single Phase, 4-Lead Capacitor or Split-Phase Motor
®
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71
Type S AC Reversing Magnetic Starters
Class 8736
3- and 4-Pole
Reversing Starters, 3- and 4-Pole:
Class 8736 Type S
FIG. 1
FPO 53-2
FPO
53-2
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 00-2, 4-Pole, 2-Phase
FIG. 2
FPO 53-3
* Marked “OL” if alarm contact is supplied
FPO
53-3
Elementary Diagram
Wiring Diagram
Size 00-4, 3-Pole, 3-Phase
FIG. 3
FPO
54-1
FPO 54-1
Elementary Diagram
Wiring Diagram
Size 5, 3-Pole, 3-Phase
®
72
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Type S AC 2-Speed Magnetic Starters
Class 8810
Starters for 2-Speed, 2-Winding (Separate Winding), 3-Phase Motors:
Class 8810 Type S
FPO 54-2
FIG. 1
FPO
54-2
Elementary Diagram
Wiring Diagram
Size 0-4
FIG. 2
FPO 54-3
Size 5 Wiring Diagram
Starters for 2-Speed, 1-Winding (Consequent Pole), Constant or Variable Torque, 3-Phase Motors:
Class 8810 Type S
FPO 55-1
FIG. 3
FPO
55-1
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 0-2
®
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73
Type S AC Reversing Magnetic Starters
Class 8810
Starters for 2-Speed, 1-Winding (Consequent Pole), Constant or Variable Torque, 3-Phase Motors:
Class 8810 Type S
FIG. 2
FIG. 1
FPO
55-3
FPO
55-2
* Marked “OL” if alarm contact is supplied
Size 5 Wiring Diagram
Size 3 and 4 Wiring Diagram
Starters for 2-Speed, 1-Winding (Consequent Pole), Constant Horsepower, 3-Phase Motors:
Class 8810 Type S
FPO 55-4
FIG. 3
FPO
55-4
* Marked “OL” if alarm contact is supplied
Elementary Diagram
Wiring Diagram
Size 0-2
FIG. 4
FIG. 5
FPO 56-2
75%
FPO 56-1
75%
* Marked “OL” if alarm contact is supplied
* Marked “OL” if alarm contact is supplied
Size 3 and 4 Wiring Diagram
Size 0, w/ High-Off-Low Selector Switch (Form C7) Wiring Diagram
®
74
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2-Speed Magnetic Starters
Class 8810
Special Control Circuits
Form R1
Form R2
FIG. 1
FIG. 2
FPO 57-2
FPO
57-1
Compelling Relay, Requiring Motor Starting in Low Speed
Accelerating Relay, Providing Timed Acceleration to Selected Speed
Form R3
Form R2R3
FIG. 4
FIG. 3
FPO
57-3
FPO
57-4
Accelerating Relay and Decelerating Relay
Decelerating Relay, w/ Time Delay During Transfer from
Higher to Lower Speed
Form R1R3
FIG. 5
Form A10C
FPO 57-5
FIG. 6
FPO
57-6
Compelling Relay and Decelerating Relay
Hand-Off-Auto Selector Switch and High-Low Push Button
Form CC17
Form A10CR1
FIG. 7
FIG. 8
FPO
57-7
Hand-Off-Auto Selector Switch and High-Low Selector Switch
FPO
57-8
Hand-Off-Auto Selector Switch and High-Low Push Button w/
Compelling Relay/Timer
®
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75
2-Speed Magnetic Starters and Multispeed Motor Connections
Class 8810
Special Control Circuits and 1- and 3-Phase Motor Connections
Form C25
Form CC17 R2R3
FIG. 1
FIG. 2
FPO
57-10
120%
FPO
57-9
Hand-Off-Auto Selector Switch and High-Low Selector Switch w/
Accelerating and Decelerating Relay/Timer
High-Low-Off-Auto Selector Switch
Multispeed Motor Connections:
1-Phase, 2-Speed Motors
FIG. 3
T1
T2
T3
FIG. 4
T4
T1
T2
T3
FIG. 5
T4
COM
A
B
Speed
L1
L2
Open
Together
Speed
L1
L2
Open
Together
Speed
L1
L2
Open
Together
Low
High
T1
T3
T2
T4
T3,T4
T1,T2
—
—
Low
High
T3
T1
T4
T2
T1,T2
T3,T4
—
—
Low
High
COM
COM
A
B
B
A
—
—
2 Windings
FIG. 6
T1
2 Windings
COM
FIG. 7
T4
T1
1 Winding
COM
FIG. 8
T4
T1
COM
T4
Speed
L1
L2
Open
Together
Speed
L1
L2
Open
Together
Speed
L1
L2
Open
Together
Low
High
COM
COM
T1
T4
T4
T1
—
—
Low
High
T1
T1
T4
COM
COM
—
—
T1,T4
Low
High
T1
T1
COM
T4
—
COM
T1,T4
—
1 Winding
1 Winding
1 Winding
Multispeed Motor Connections:
3-Phase, 2-Speed Motors
FIG. 9
FIG. 10
T4
T3
FIG. 11
T4
T1
T3
T4
T1
T1
T3
T5
Speed
L1
L2
L3
Low
High
T1
T6
T2
T4
T3
T5
Open
Together
—
T4,T5,T6
All others
—
1 Winding, Constant Horsepower
FIG. 12
T1
T3
Speed
Low
High
L1
L2
T13
L3
T1 T2 T3
T11 T12 T13
Separate Windings
Speed
L1
L2
L3
Low
High
T1
T6
T2
T4
T3
T5
T12
Open
All others
All others
T6
Open
Together
All others
—
—
T1,T2,T3
T3
Speed
Low
High
T2
L1
L2
T13 T17
L3
T1 T2
T3
T11 T12 T13,T17
T6
Speed
L1
L2
L3
Low
High
T1
T6
T2
T4
T3
T5
Open
Together
All others
—
—
T1,T2,T3
1 Winding, Variable Torque
FIG. 14
T11
T1
T2
T5
1 Winding, Constant Torque
FIG. 13
T11
T2
T2
T5
T6
T2
T12
T1
T3
T2 T13
T7
Open
Speed
All others
All others
Low
High
Separate Windings
T11
L1
L2
T1 T2
T11 T12
T12
L3
Open
T3,T7
T13
All others
All others
Separate Windings
®
76
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Multispeed Motor Connections
3-Phase
Multispeed Motor Connections:
3-Phase, 2-Speed Motors
FIG. 1
T1
FIG. 2
T11
T1
FIG. 3
T5
T1
T11
T2
T4
T4
T2
T14
L3
L2
T12
T6
T3
T7
T2 T13 T17
Speed
L1
Low
High
L2
T12
L3
Open
T1 T2
T3,T7
T11 T12 T13,T17
T3
T3
Speed
All others
All others
L1
Low
High
Separate Windings
L3
T1
T1,T5
L2
L4
Open
T5
T2
T6
T3 T2,T6 T4
T13
Speed L1
Low
High
T3,T4
—
2-Phase, 1 Winding, Variable Torque
L4
Open
T1 T3 T2
T4 All others
T11 T13 T12 T14 All others
2-Phase, Separate Windings
Multispeed Motor Connections:
3-Phase, 3-Speed Motors
FIG. 4
T4
FIG. 5
T11
T4
T3
T1
T7
L1
Low
2nd
High
L2
L3
T12
Open
Together
Speed L1
Low
2nd
High
T1
L1
Low
2nd
High
T13
T12
L3
Open
Together
Speed
T3
T5
T13
All others
All others
All others
—
T1,T2,T3
—
Low
2nd
High
T6
L2
T1 T2
T6 T4
T11 T12
Together
L1
T12
T15
L3
L2
T1 T2
T11 T12
T6 T4
Together
2 Windings, Constant Torque
FIG. 9
T14
T1
T11
T13
T3
T13
T12
L3
Open
Together
Speed
T3
T13
T5
All others
All others
All others
—
—
T1,T2,T3
Low
2nd
High
T6
T16
Open
Low T1 T2
T3
All others
—
2nd T11 T12 T13,T17 All others
—
High T16 T14 T15
All others T11,T12,T13,T17
T11
T2
T5
2 Windings, Variable Torque
T2
Speed L1 L2
T1
T3
T2
Open
T4
T11
T3
L3
T3
T12
T1 T2 T3,T7 All others
—
T11 T12 T13 All others
—
T6 T4
T5
All others T1,T2,T3,T7
FIG. 8
T4
T5
L2
T11
T17
2 Windings, Constant Torque
2 Windings, Constant Torque
Speed
T13
T6 T13
T2
T5
T1 T2 T3,T7 All others
—
T6 T4
T5
—
T1,T2,T3,T7
T11 T12 T13 All others
—
FIG. 7
T14
T1
T1
T7
T6 T13
T2
T5
Speed
FIG. 6
T11
T3
2 Windings, Variable Torque
L1
T2
T15
L2
L3
T1 T2
T11 T12
T16 T14
T3
T13
T15
T12
T16
Open
Together
All others
—
All others
—
All others T11,T12,T13
2 Windings, Variable Torque
Multispeed Motor Connections:
3-Phase, 4-Speed Motors
FIG. 10
T4
T3
FIG. 11
T14
T1
T13
T4
T11
FIG. 12
T14
T3
T1
T13
T4
T14
T13
T3
T11
T1
T7
T7 T2
T5
Speed
Low
2nd
3rd
High
L1
L2
T6
L3
T1 T2
T3
T6 T4 T5,T7
T11 T12
T13
T16 T14 T15,T17
T15 T17 T12
Open
T16
Speed
All others T4,T5,T6,T7
All others
—
All others T14,T15,T16,T17
All others
—
T4
T1
T7
T2
T5
Low
2nd
3rd
High
T15 T17 T12
T6
L3
Open
T1 T2
T3
T11 T12
T13
T6 T4 T5,T7
T16 T14 T15,T17
T16
Speed
All others T4,T5,T6,T7
All others T14,T15,T16,T17
All others
—
All others
—
T4
T2
T5
Together
L1
Low
2nd
3rd
High
2 Windings, Constant Horsepower
FIG. 14
T14
L2
T6
L2
L3
T12
T15
Open
T16
Together
T1 T2 T3,T7 All others
—
T6 T4
T5
All others T1,T2,T3,T7
T11 T12 T13,T17 All others
—
T16 T14
T15
All others T11,T12,T13,T17
2 Windings, Constant Torque
FIG. 15
T14
T4
T14
T13
T3
Speed
L1
Low
2nd
3rd
High
2 Windings, Constant Horsepower
FIG. 13
T7 T2
T5
Together
T11
T17
L1
L2
T11
T17
T6
L3
T15
Open
T1
T3
T12
T16
Together
T1 T2 T3,T7 All others
—
T11 T12 T13,T17 All others
—
T6 T4
T5
All others T1,T2,T3,T7
T16 T14
T15
All others T11,T12,T13,T17
2 Windings, Constant Torque
T5
Speed
Low
2nd
3rd
High
T2
L1
T6
L2
T11
T13
L3
T1 T2 T3
T6 T4 T5
T11 T12 T13
T16 T14 T15
T15
T12
T16
T5
Open
Together
Speed
All others
All others
All others
All others
—
T1,T2,T3
—
T11,T12,T13
Low
2nd
3rd
High
2 Windings, Variable Torque
T1
T3
T2
L1
T6
L2
T11
T13
L3
T1 T2 T3
T11 T12 T13
T6 T4 T5
T16 T14 T15
T15
T12
T16
Open
Together
All others
All others
All others
All others
—
—
T1,T2,T3
T11,T12,T13
2 Windings, Variable Torque
®
www.epdatech.com
77
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Programmable Lighting Controllers
Class 8865
Programmable Lighting Controller:
Class 8865 Type TC12
FIG. 1
CIRCUIT 12
CIRCUIT 9
CIRCUIT 8
RELAY OUTPUT CONNECTIONS
CIRCUITS 7-12
CIRCUIT 11
CIRCUIT 10
35
CIRCUIT 7
18
19
17
20
16
CIRCUIT 6
21
15
22
14
23
13
CIRCUIT 5
24
12
25
11
26
10
CIRCUIT 4
27
9
28
8
29
7
30
6
CIRCUIT 3
RELAY OUTPUT CONNECTIONS
CIRCUITS 1-6
31
5
32
4
CIRCUIT 2
33
3
34
2
CIRCUIT 1
1
INPUTS
Demand
Input
36
+1– +2– +3– +4– +5– +6– +7– +8–
24 VAC
INPUT
®
78
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AC Lighting Contactors
Class 8903
Load Connections
Load Connections for AC Lighting Contactors:
Class 8903
FIG. 1
FIG. 2
L1
L1
L2
L2
IF
USED
LOAD
LOAD
IF
USED
LOAD
LOAD
Vload = Vline-tol-line
Vload
L2 = Vline-to-lineLN
L1
1-Phase, 2-Wire, Single Load
FIG. 3
L1
L2
1-Phase, 2-Wire, Multiple Loads
FIG. 4
LN
L1
L2
IF
USED
LN
IF
USED
LOAD
LOAD
Vload = Vline-to-neu-
LOAD
Vload = Vline-to-line
1-Phase, 3-Wire, Loads Connected Line-to-Neutral
FIG. 5
L1
L2
1-Phase, 3-Wire, Load Connected Line-to-Line
FIG. 6
L3
L1
LOAD
L2
LOAD
L3
LOAD
LOAD
LOAD
Vload = Vline-to-line
L1
1.732
L2
L3
Vload = Vline-to-line
LN
3-Phase, 3-Wire, Wye-Connected Load
FIG. 7
L1
L2
L3
LOAD
Iload = Icontacts
1.732
3-Phase, 3-Wire, Delta-Connected Load
LN
LOAD
IF
USED
LOAD
LOAD
Vload = Vline-to-neu-
Application Limits:
1. Voltage between line side conductors must not
exceed line-to-line voltage rating of contactor.
2. Vload must not exceed volts-per-load rating of
contactor.
3. Line current carried by any contact must not
exceed ampere rating of contactor.
For contact ratings, refer to the Square D Digest.
3-Phase, 4-Wire, Loads Connected Line-to-Neutral
®
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79
AC Lighting Contactors
Class 8903
Control Circuit Connections
Control Circuit Connections for Electrically-Held Contactors:
Class 8903 Type L and S
FIG. 1
ON
OFF
To AC common
or separate
control supply
COIL
FIG. 4
M
On-Off Push Button (Form A12)
FIG. 2
2-WIRE
PILOT DEVICE
A1
A2
COIL
I
I
HAND OFF AUTO
To AC common
or separate
control supply
A1
A2
A1
To AC common
or separate
control supply
Direct Control from Pilot Device
FIG. 3
COIL
2-WIRE
PILOT
DEVICE
A2
I
I
ON OFF
COIL
A1
To AC common
or separate
control supply
A2
On-Off Selector Switch (Form C6)
Hand-Off-Auto Selector Switch (Form C)
Control Circuit Connections for Mechanically-Held Contactors:
Class 8903 Type LX and S
FIG. 5
COIL CLEARING
CONTACTS
(Supplied)
ON
FIG. 6
A1
A2
LATCH
I
ON OFF
LATCH
14
17
14
A
OFF
UNLATCH
15
18
A2
To AC common
or separate
control supply
On-Off Push Button (Form A3)
B
On-Off Selector Switch (Form C6)
COIL CLEARING
CONTACTS
(Supplied)
FIG. 8
1-POLE
PILOT
DEVICE
CR
CR
LATCH
COIL
CLEARING
CONTACTS
(Supplied)
LATCH
14
17
A
To AC common
or separate
control supply
A
UNLATCH
15
B
2-POLE
PILOT
DEVICE
17
A1
18
To AC common
or separate
control supply
FIG. 7
COIL CLEARING
CONTACTS
(Supplied)
I
14
UNLATCH
15
Control from 2-Pole Pilot Device
17
A
18
B
CR
To AC common
or separate
control supply
UNLATCH
15
18
B
1-Pole Pilot Device w/ CR relay (Form R6)
®
80
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AC Lighting Contactors and Electronic Motor Brakes
Class 8903 and 8922
Panelboard Type Wiring:
Class 8903 Type PB, 30-225 A
FIG. 1
FIG. 3
FIG. 4
L1
L2/N
O
ON
ON
Control Circuit – Standard
O
CR1
CR2
CR2
L2/N
CR1
CR
+
L
C
L = Line (common)
O = Open (unlatch)
C = Close (latch)
Control Circuit – 2-Wire Control
(Form R6)
–
SC
C
L1
BR
SO
O
CR
T3
O
L1
L
CR
T2
L
C
OFF
FIG. 2
2-Wire
Pilot Device
T1
L2/N
C
L1
L3
C
L
OFF
L2
Control Circuit – Long-Distance Control
(Form R62)
Omit middle pole
for 2-pole unit
Power Circuit
QWIK-STOP® Electronic Motor Brake:
Class 8922
FIG. 5
CUSTOMER CONTROL CIRCUIT
F1
F1
ETB 10/18
15 18
Xo
START
OL
M
Xo
M
OL
T1
F2
M
OL
T2
F2
M
OL
T3
L2
[1]
STOP
F2
L1
MOTOR
L3
+
M
24 VDC
–
M
F3
[3]
ETB 10/18
[2]
F3
[3]
L1
L+
L2
L–
[4]
[1] Contacts 15 and 18 close when
L1 and L2 are energized.
PLC
[2] When controlling electronic motor brake
ETB 10/18 with a PLC (programmable logic
control), terminals Xo-Xo must be jumpered.
B–
B1
[3] Semiconductor fuses.
B+
[4] Connection for ETBS only.
POWER CIRCUIT
Type ETB10, ETB18 and ETBS18 w/ Internal Braking Contactor
FIG. 6
CUSTOMER CONTROL CIRCUIT
F1
F1
ETB 20/800
B
STOP
START
OL
T1
F2
M
OL
T2
F2
M
OL
T3
MOTOR
+
24 VDC
M
B
Xo
OL
L3
M
M
25 28
M
L2
[1]
15 18
F2
L1
–
F3
[3]
ETB 20/800
Xo
F3
M
[3]
PLC
[2]
L1
L+
B
L2
L–
B
[4]
[1] Contacts 15 and 18 close when L1 and L2 are energized.
[2] When controlling electronic motor brake ETB 20/800 with a PLC
B–
B1
(programmable logic control), terminals Xo-Xo must be jumpered.
B+
[3] Semiconductor fuses.
[4]
POWER CIRCUIT
QWIK-STOP is a registered trademark of Square D.
Connection for ETBS only.
Type ETB20-ETB800 and ETBS20-ETBS800
®
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81
Electronic Motor Brakes, Duplex Motor Controllers and Fiber Optic Transceivers
Class 8922, 8941 and 9005
QWIK-STOP® Electronic Motor Brake: Class 8922 Type ETBC
FIG. 1
CUSTOMER CONTROL
CIRCUIT
F1
F2
M
OL
T1
F2
M
OL
T2
F2
M
OL
T3
L1
F1
L2
1
2
L3
[1]
3
MOTOR
M
START
4
5
ETBC
M
M
F3
[2]
L1
B
T1/2
L2
B
T2/4
[1] To control electronic motor
PLC
9
+
B– 10
–
B+
[2]
M
6
7
F3
OL
STOP
24 VDC INPUT
brake ETBC with input B+/B–,
terminals 3 and 4 must be
jumpered.
[2] Semiconductor fuses.
QWIK-STOP is a registered trademark of Square D.
Type ETBC
AC Duplex Motor Controller: Class 8941
FIG. 2
Fiber Optic Transceiver: Class 9005
FIG. 3
14
OUTPUT
12
11
POWER
86
GAIN
ADJ.
SCREW
GAIN
OUTPUT
STATUS
LED
SETUP
LED
SETUP
OUTPUT
FIBER RELEASE
FIBER
RELEASE
LEVER
FIBER
A1
Elementary Diagram for Duplex Motor Controller w/
Electric Alternator
INPUT
A2
Transceiver, Front View
FIG. 4
HAZARDOUS LOCATIONS
CLASS I GROUPS A, B, C & D
CLASS II GROUPS E, F & G
CLASS III
NONHAZARDOUS LOCATIONS
FIBER OPTIC
TRANSCEIVER
FIBER OPTIC
PUSH BUTTON,
SELECTOR SWITCH,
LIMIT SWITCH, ETC.
FIBER OPTIC CABLE
CLASS 9005 TYPE FT
FIBER OPTIC CABLE
ELECTRICAL
CONNECTIONS
BOUNDARY SEAL TO BE IN
ACCORDANCE WITH ARTICLE
501-5 OF THE NATIONAL
ELECTRICAL CODE
Location
®
82
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Photoelectric and Inductive Proximity Switches
Class 9006
Photoelectric Switches:
Class 9006 Type PE1 (Obsolete)
FIG. 1
FIG. 2
AC thru-beam emitter has no
output switching capability,
therefore leakage current is not
applicable. Thru-beam emitter is
connected directly across the AC
line and typically draws 15 mA.
Connect load in series. To prevent
damage, all switches except
emitters must have load
connected to switch.
2-Wire AC, Single Device Operation
AC Emitter
FIG. 3
FIG. 4
DC thru-beam emitter has no
output switching capability,
therefore it requires only a 2-wire
cable connected directly across
the DC. Thru-beam emitter draws
a maximum of 45 mA.
DC switches cannot be wired in
series. To prevent damage, all
switches except emitters must
have load connected to switch.
4-Wire DC, Single Device Operation, 10-30 VDC, 250 mA Max. Load
DC Emitter
Photoelectric Switches:
Class 9006 Type PE6 and PE7 (Obsolete)
Photoelectric Switches:
Class 9006 Type PEA120 (Obsolete)
FIG. 5
FIG. 8
12-24 VDC, Sinking (NPN)
FIG. 6
These switches are light
operated only.
12-24 VDC, Sourcing (PNP)
Beam broken = load deenergized
Beam unbroken = load energized
FIG. 7
Diagram shows contact arrangement with beam broken.
120 VAC, Emitter Only
120 VAC Amplifier
Inductive Proximity Switches:
Class 9006 Type PS (Obsolete)
FIG. 9
FIG. 10
2-Wire AC, N.O.
FIG. 12
FIG. 11
2-Wire AC, N.C.
FIG. 13
2-Wire DC, N.O.
2-Wire AC, N.O. or N.C.
FIG. 14
4-Wire DC, Sinking (NPN)
4-Wire DC, Sourcing (PNP)
®
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83
Inductive Proximity Sensors
XS, XSC, XSF and XSD
XS Tubular Inductive Proximity Sensors
FIG. 1
+/–
BN/3
FIG. 2
for connector version only
BN/2
NO BU/4
–/+
BU/3
2-Wire DC, Non-Polarized
FIG. 3
BN/1
FIG. 5
BN/1
+
PNP
BK/4 NO
BK/2 NC
NO
NC
NO
–
BU/3
BN/1
BN/1
–
3-Wire DC, N.O. or N.C.
WH/2
–
BU/3 (NO), BN/1 (NC)
+
NC
BU/3
+
BK/4
PNP
–
NO
NO
BK/4
NPN
BK/2 NC
BK/4 NO
BN/1 (NO), BU/3 (NC)
+
BU/3
+
NPN
L2 –/+
2-Wire AC/DC
FIG. 4
PNP
L1 +/–
AC/DC
BU/3
+
NPN
BK/4
BK/4
WH/2
–
–
BN/1 (NO), BU/3 (NC)
3-Wire DC, N.O. and N.C., Complementary
3-Wire DC, Selectable PNP/NPN, N.O./N.C.
XSC Rectangular Inductive Proximity Sensors
FIG. 6
+/–
3
FIG. 7
5
FIG. 8
L1
FIG. 9
5
1
PNP
AC/DC
NO
NC
4
–/+
3
+/–
4
–/+
NO 6
NO
7
8
L2
8 BK
5
L1
6
L2
5
AC/DC
NC
NC
7
7 BK
2-Wire AC, Programmable
2-Wire DC, Non-Polarized
NO
NC
6
2
3
–
1
NPN
+
NO
6
NC
8
3
2-Wire AC/DC, Programmable
+
4
4
2
–
3-Wire DC, N.O. or N.C.
XSF Rectangular Inductive Proximity Sensors
FIG. 11
FIG. 10
1
NO
NC
L1
1
PNP
4
NO
NC
+
2
2
L2
3
–
1
L1
1
NPN
+
4
L2
NO
NC
3
2-Wire AC, Programmable N.O. or N.C.
4
2
–
3-Wire DC, N.O. or N.C.
XSD Rectangular Inductive Proximity Sensors
FIG. 13
FIG. 12
3
NO
FIG. 14
+/–
4
–/+
3
+/–
NO
7
NC
4
8
–/+
NC
7
NO
2
–
1
NPN
+
NO
L2
2-Wire AC, Programmable N.O. or N.C.
+
3
NC
3
2-Wire DC, Non-Polarized
4
NC
L1
LOAD
8
1
PNP
4
2
–
3-Wire DC, N.O. or N.C.
®
84
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Inductive and Capacitive Proximity Sensors
XS and XTA
AA
A
XS Tubular Inductive Proximity NAMUR Sensors
ed to a solid state in ut (e.g. : ST1 CC/CS, TSX DET 466)
Ri = 1K
BN-1 +
Object
+
present
7...12V DC
_
FIG. 1
Object
absent
BU-2
-
BN-1
+
BU-2
-
I < 1mA
Ri = 1K
FIG. 2
Wiring diagram
-
+
+
BN
+
proximity
sensor
_
1
BU
-
(110...240 V)
(110...240V)
ACHzP=
AC
P = 5 VA, 50
XZD
7...12V DC
I > 3mA
A
2
}
4 2.F 2.0 1.+
Non-Intrinsically Safe Applications (Normal Safe Zone),
Connected to a Solid State Input
With XZD Power Supply/Relay Amplifier Unit
XS Inductive Proximity Sensors w/ Analog Output
FIG. 3
FIG. 4
Output current
@ 24 V:
0-10 mA
0-16 mA
@ 48 V:
0-10 mA
Value of Load R (max.)
1800 Ω
1125 Ω
4200 Ω
Output current
@ 24 V:
4-14 mA
4-20 mA
@ 48 V:
4-14 mA
2-Wire DC
FIG. 5
Value of Load R (max.)
640 Ω
450 Ω
These sensors may be wired in
the 2- or 3-wire mode, depending
on the current output
characteristics required.
2350 Ω
3-Wire DC
XTA Tubular Capacitive Proximity Sensors
,
BN
BU
FIG. 6
BN
L1
L2
PNP
BN
+
NPN
BK
+
BK
Gn*
BU
* Ground for XTA A115 only
-
BU
-
3-Wire DC
2-Wire AC
®
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85
Magnet Actuated Proximity Sensors and Photoelectric Sensors
SG, ST and XUB
SG Magnet Actuated Proximity Sensors, Surface Mount Style
FIG. 1
FIG. 2
L2
L1
FIG. 3
L2
L1
Black
Red
LOAD
LOAD
White
SGA 8016, SGA 8031, SGA 8182, SGA 8053,
SGA 8176, SGA 8177, SG0 8168 and SG08239
SGB 8175
LOAD
LOAD
SG2 8195
SG Magnet Actuated Proximity Sensors, Limit Switch Style
FIG. 4
FIG. 5
L2
L1
FIG. 6
L2
L1
NO
Com
LOAD
LOAD
NC
SG0 8003, SG1 8004, SGA 8005 and SGA 8040
FIG. 7
+
+
SG0 L8003 and SG1 L8004
FIG. 8
Com
–
+
+
SG1 8056 is normally closed. Connect
red terminal (+) to power source.
Connect minus (-) terminal to load.
Housing must be connected to minus.
LOAD
SG0 B8114, SG1 B8147, SG0 BL8114,
SG0 BL8147 and SGC 8142-T-P
LOAD
SGC 8027 and SGC 8025
-
L
LOAD
LOAD
SG0 8079 and SG1 8056
SG Magnet Actuated Proximity Sensors, Tubular Style
FIG. 9
FIG. 10
L2
L1
NO
LOAD
Com
LOAD
LOAD
NC
SGC 8058 and SGC 8181
SGA 8057, SGA 8189, SGA 8072, SGA 8179,
SGA 8180 and SGA 8038
SG Magnet Actuated Proximity Sensors, Maintained Contact
FIG. 11
FIG. 12
L2
L1
L1
LOAD
2
1
6.8k
SGA 8018, SGO 8026
L2
LOAD
3
SGO 8110
ST Grounded Probe Switch
FIG. 13
FIG. 14
Blk Gnd Wht Red
L1
L2
LOAD
hot
1
L1
hot
housing
neutral
Target connected to ground
2
3
4
Not
used
L2
LOAD
neutral
Target connected to ground. Housing
must be grounded for proper operation.
Cable Wiring
ST switches may be wired in series or parallel.
For series operation, connect red lead
(terminal 4) to black lead (terminal 1) of other
switch. The voltage drop across each switch
(in the closed state) does not exceed 2 VAC.
Terminal strip Wiring
XUB Short Range Tubular Photoelectric Sensors
FIG. 16
FIG. 15
2-Wire AC
FIG. 17
AC Emitter
DC Emitter
®
86
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Photoelectric Sensors
XUM, XUH, XUG, XUL and XUJ
XUM Miniature High Performance Photoelectric Sensors
FIG. 1
+ Light
Prog.
FIG. 2
FIG. 3
Test
W
OG
- Dark
BN
BK
J
BN
BK
H
LOAD
LOAD
+ Light
Prog
.
OG
Test
LOAD
BU
BU
W
XUH and XUG Medium Range
Photoelectric Sensors
LOAD
- Dark
NPN Output
PNP Output
5-Wire AC
XUL Subcompact Photoelectric Sensors
FIG. 4
Emitter DC
FIG. 5
Connector, PNP output
BN
1
4
BU
3
Prog.
2
Emitter
+ light
- dark
DC 3 wire
Connector, NPN output
PNP output
Prog.
2
+ light
+ light
BK
DC connector
NPN output
BN
1
+ light
- dark
AC/DC
OG
RD
+
BK
BU
OG
AC/DC
Relay output
AC/DC versions
- dark
- dark
Prog.
BU
4
3
BU
OG
AC/DC
1
BN
BK
Prog.
BN
2
prog.
BU
BN
AC/DC
4
Output
–
DC
AC/DC
XUJ Compact High Performance Photoelectric Sensors
FIG. 7
FIG. 6
FIG. 8
FIG. 9
1
Dark 2
Light 3
–
NPN
–
or
+
+
4
+
PNP
1 kΩ
5-Wire Relay, AC/DC
AC/DC Microchange
DC Connector
5
6
DC Output
LOAD
Test
DC Output Microchange
DC Connector
®
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87
Photoelectric Sensors and Security Light Barriers
XUE, XUR, XUD, XUG and XUE S
XUE Long Range Plug-In Photoelectric Sensors
FIG. 1
FIG. 2
FIG. 3
XUE A
DC Emitter
XUE H, NPN
FIG. 5
FIG. 4
FIG. 6
XUE F
XUE H, PNP
XUE T
XUR Color Registration Photoelectric Sensors
FIG. 8
FIG. 7
PNP
NPN
XUD Amplifiers
FIG. 9
XUG Amplifiers
FIG. 10
BN
PNP
H
+
OG
BK
BU
FIG. 11
Light Mode:
Connect to +
BN
Dark Mode:
Connect to –
NPN
J
+
BK
–
OG
–
BU
Light Mode:
Connect to +
Dark Mode:
Connect to –
XUD J
XUD H
for XUF N Plastic Fiber Optics – DC models
XUE S Security Light Barriers
FIG. 12
FIG. 13
5
6
T1
T2
Open
to
test
A1
L1
A2
L2
Emitter
3
4
1
L1
2
L2
Receiver
®
88
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Photoelectric Sensors
XUV
XUV Photoelectric Sensors w/ Separate Optical Heads
FIG. 1
+
H
Grey
Test
W
J
+
LOAD
BU
W
Gating Sensor
BN
BK
H
FIG. 2
PNP
Synchro
LOAD
BK
BU
LOAD
+
–
Grey
Synchro
–
NPN
–
LOAD
Test
J
PNP Output
FIG. 3
BN
Gating Sensor
NPN Output
1 CHANNEL AMPLIFIER
Terminals
13 15 17 19
A
Potentiometers
2
4
6-8
13
15
17
19
TERMINALS
L1 Supply
L2 Supply
Relay output (1 contact)
Receiver (white wire)
Receiver shielded cable
Emitter shield
Emitter (red wire)
1
2
A
1
2
3
SWITCHES
Light/Dark
Monostable timer (pulse stretcher)
POTENTIOMETERS
Sensitivity adjustment
LED INDICATORS
Green: power supply
Red: unstable
Yellow: output
Switches
1
LED indicators
2
4
2
1 2
3
6
8
Terminals
2 CHANNEL AMPLIFIER – FORM C RELAY
10 12 14 16 18 20
Terminals
9 11 13 15 17 19
A
Potentiometers
B
Switches
2
1 23 4
3
4
2
4
6
8
1
3
5
7
1
LED indicators
5
Terminals
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
TERMINALS
L1 Supply
L2 Supply
NC output, Channel 2
NC output, Channel 1
Common, Channel 2
Common, Channel 1
NO output, Channel 2
NO output, Channel 1
12 VDC output
for synchro sensors
12 VDC output
for synchro sensors
Synchronization, Channel 2, NPN
Synchronization, Channel 1, NPN
Emitter shield, Channel 1
Receiver, Channel 1 (white wire)
Emitter, Channel 1 (red wire)
Receiver shield, Channel 1
Emitter shield, Channel 2
Receiver, Channel 2 (white wire)
Emitter, Channel 2 (red wire)
Receiver shield, Channel 2
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
TERMINALS
L1 Supply
L2 Supply
Output test (1 contact relay)
Output test (1 contact relay)
Channel 1 output (1 contact relay)
Channel 1 output (1 contact relay)
Channel 2 output (1 contact relay)
Channel 2 output (1 contact relay)
12 VDC output
for synchro sensors
12 VDC output
for synchro sensors
Synchronization, Channel 2, NPN
Synchronization, Channel 1, NPN
Emitter shield, Channel 1
Receiver, Channel 1 (white wire)
Emitter, Channel 1 (red wire)
Receiver shield, Channel 1
Emitter shield, Channel 2
Receiver, Channel 2 (white wire)
Emitter, Channel 2 (red wire)
Receiver shield, Channel 2
1
2
3
4
A
B
1
2
3
4
5
SWITCHES
Monostable timer (pulse stretcher), Channel 1
Light/Dark, Channel 1
Monostable timer (pulse stretcher), Channel 2
Light/Dark, Channel 2
POTENTIOMETERS
Sensitivity adjustment, Channel 1
Sensitivity adjustment, Channel 2
LED INDICATORS
Green: power supply
Red: unstable, Channel 1
Yellow: output, Channel 1
Red: unstable, Channel 2
Yellow: output, Channel 2
2 CHANNEL LOGIC MODULE
10 12 14 16 18 20
Terminals
9 11 13 15 17 19
LED indicators
5 6
Potentiometers
A
7
8
9 10
B
C
Switches
1 23 4 5 67 8
1 2
3
4
LED indicators
2
4
6
8
1
3
5
7
Terminals
SWITCHES
Time delay, Channel 1 (0.05 to 3 s or 1 to 60 s)
Time delay, Channel 1 (On/Off)
Time delay mode (mono. or adjustable time delay)
Leading/Trailing edge selection
Logic function (And/Or)
Logic function (On/Off)
Light/Dark, Channel 1
Light/Dark, Channel 2
POTENTIOMETERS
A Time delay, Channel 1
B Sensitivity adjustment, Channel 1
C Sensitivity adjustment, Channel 2
LED INDICATORS
1 Green: power supply
2 Red: output test
3 Yellow: output, Channel 1
4 Yellow: output, Channel 2
5 Green: synchronization, Channel 1
6 Yellow: detection, Channel 1
7 Red: unstable, Channel 1
8 Green: synchronization, Channel 2
9 Yellow: detection, Channel 2
10 Red: unstable, Channel 2
1
2
3
4
5
6
7
8
AC Wiring Diagrams
®
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89
Limit Switches
Class 9007
Contact Forms for
Class 9007 Limit Switches
FIG. 1
Limit Switches:
Class 9007 Type C
FIG. 2
FIG. 3
Types C52, C54
1-Pole
FIG. 4
Type C62
2-Pole, Same Polarity Each Pole
Type C66
2-Pole, 2-Stage, Same Polarity Each Pole
FIG. 5
FIG. 6
[1]
On CR switches, terminals 1-4 on left
side are for CW rotation and terminals
5-8 on right side are for CCW rotation.
Types C68T5, C68T10, CR67T5 [1] and CR67T10 [1]
2-Pole Neutral Position, Same Polarity Each Pole
Type C Reeds
Limit Switches:
Class 9007 Type XA
FIG. 8
FIG. 7
Type XA73 Reeds
Type XA75 Reeds
®
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Limit Switches
Class 9007
Limit Switches:
Class 9007 Type AW
FIG. 2
FIG. 1
Type AW12 and AW14
Type AW18
FIG. 3
FIG. 4
[1]
FIG. 5
[1]
If lever arm is placed at same end of box as
conduit, N.O. contacts become N.C. and
vice versa.
Type AW16
w/ Lever Arm Opposite Conduit Hole [1]
FIG. 6
If lever arm is placed at same end of box as
conduit, N.O. contacts become N.C. and vice
versa.
Type AW19
w/ Lever Arm Opposite Conduit Hole [1]
FIG. 7
Type AW32, AW34, AW42
and AW44
FIG. 8
Type AW36 and AW46
Type AW38 and AW48
Type AW39 and AW49
Limit Switches:
Class 9007 Type SG – GATE GARDTM Switch
FIG. 9
FIG. 10
Type SGS1DK
Type SGP1
®
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91
Limit Switches and Safety Interlocks
XCK and MS
XCK Limit Switches
FIG. 1
FIG. 2
SPDT, 1 N.O. and 1 N.C.
Positive Opening, Snap Action
FIG. 3
2 SPDT, 2 N.O. and 2 N.C.
SPDT, Isolated N.O. and N.C.
Positive Opening, Slow-Make Slow-Break
XCK Safety Interlocks
FIG. 4
FIG. 5
13
21
FIG. 6
LED 24 VDC
AC
24 VDC
21
13
22
14
L1
21
13
14
22
14
Orange
LOAD
No polarity
SPDT, Positive Opening,
Slow-Make Slow-Break
X3
X1
22
X3
Orange
LOAD
X2
Green
X1
0V
SPDT, w/ 24 VDC LED, Positive Opening,
Slow-Make Slow-Break
AC
Note: N.O. and N.C.
contacts are shown with
key inserted and fully
engaged.
L2
SPDT, w/ 2 Pilot Lights, Positive Opening,
Slow-Make Slow-Break
Contact Blocks for XY2CE Limit Switches
FIG. 7
21
13
FIG. 8
21
11
FIG. 9
11
FIG. 10
13
FIG. 11
X1
X1
X2
22
Zb 14
XEN P2151, Isolated N.C.
and N.O.
22
12
Zb 12
XEN P2141, Isolated N.C.
and N.O.
X2
Za 14
XEN P2051, N.C./N.O.,
12 and 14 same polarity
Indicator Light, Direct
Indicator Light
w/ Resistance
MS Miniature Limit Switches
FIG. 12
FIG. 13
White
Black
Green
Black
Orange
Red
Red
SPST
White
Green
SPDT
®
92
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Pressure Switches and Transducers
Class 9012, 9013, 9022 and 9025
Pressure and Temperature Switches:
Class 9012 and 9025 Type G
FIG. 1
FIG. 2
FIG. 3
Machine Tool, SPDT,
1 N.O. and 1 N.C.
Machine Tool, DPDT,
2 N.O. and 2 N.C.
FIG. 4
Industrial, SPST,
1 N.O. and 1 N.C.
FIG. 5
Machine Tool, SPDT, 1 N.O. and 1 N.C. w/ Form H10
Machine Tool, SPDT, 1 N.O. and 1 N.C. w/ Form H11
Commercial Pressure Switches:
Class 9013 Type CS
FIG. 6
Acceptable Wiring Schematics
Pressure Transducers:
Class 9022 Type PTA and PTB
FIG. 7
+
–
DC SUPPLY
FIG. 8
Black
DC SUPPLY
TRANSDUCER
White or
Red
Brown
TRANSDUCER
Red
+
LOAD
–
FIG. 9
+
DC SUPPLY
–
TRANSDUCER
4
LOAD
Black
2
1
3
LOAD
Type PTA, 2-Wire
FIG. 10
+
Type PTA, 3-Wire
–
DC SUPPLY
Green
+
Type PTA, 4-Wire
DC SUPPLY
–
TRANSDUCER
TRANSDUCER
Red
FIG. 11
LOAD
A
B
FIG. 12
+
DC SUPPLY
–
TRANSDUCER
LOAD
C
Red
Green
Black
White
LOAD
Type PTB, 2-Wire
Type PTB, 3-Wire
Type PTB, 4-Wire
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Level Sensors and Electric Alternators
Class 9034 and 9039
Level Sensors:
Class 9034 Types LSD and LSV
FIG. 1
Wiring Diagram
Elementary Diagram
Output selection of both sensors in maximum (N.C.
when absent). Both devices at max. setting.
Fill Cycle, Tank Full
FIG. 2
Wiring Diagram
Elementary Diagram
Output selection of both sensors in minimum (N.O.
when absent). Both devices at min. setting.
Drain Cycle, Tank Empty
Electric Alternators:
Class 9039 Type X
FIG. 3
Set pilot device A contacts to close before pilot device
B contacts.
Connections shown are for common control. If motor
line voltage is different from voltage rating stamped on
alternator coil terminals, alternator must be connected
to motor lines thru control transformers.
Control circuit conductors require overcurrent
protection in accordance with applicable electrical
codes.
* Overlapping contact.
FPO 69-1
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Pneumatic Timing Relays
Class 9050
Pneumatic Timing Relays:
Class 9050: Type AO
FIG. 1
FIG. 2
Type AO10E
FIG. 3
Type AO10D
FIG. 7
FIG. 8
Type AO11E
Type AO20E
FIG. 9
Type AO11D
FIG. 13
FIG. 14
Type AO12E
FIG. 20
Type AO210DE
Type AO20D
Type AO21E
FIG. 21
Type AO21D
FIG. 22
FIG. 25
Type AO111DE
Type AO121DE
FIG. 18
Type AO112DE
Type AO122DE
FIG. 24
Type AO221DE
Type AO222DE
Pneumatic Timing Relays:
Class 9050: Types B and C
FIG. 26
FIG. 27
FIG. 28
Off Delay
Type HO10E, On Delay
Type AO120DE
FIG. 12
FIG. 23
Type AO220DE
Pneumatic Timing Relays:
Class 9050: Type HO
Type AO110DE
FIG. 17
Type AO22D
Type AO212DE
FIG. 6
FIG. 11
FIG. 16
Type AO22E
Type AO211DE
FIG. 5
FIG. 10
FIG. 15
Type AO12D
FIG. 19
FIG. 4
Type HO10D, Off Delay
On Delay
Type B
Off Delay
On Delay
Type C
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95
Pneumatic Timing Relays and Solid State Industrial Timing Relays
Class 9050
Class 9050 Pneumatic Timing Relays: Typical Elementary Diagrams
FIG. 1
FIG. 2
Interval, Momentary Start
FIG. 3
On Delay
Interval, Maintained Start
FIG. 4
FIG. 5
Off Delay
Repeat Cycle
Solid State Industrial Timing Relays: Class 9050 Types FS and FSR
FIG. 6
FIG. 7
L1
L2
AC Supply Voltage
FPO 71-1
L1
L2
C1
Timed
Contacts
C2
C3
Instantaneous C5
Contacts
(optional)
P1
C6
C7
C4
C8
External Initiating Contact
Elementary Diagram
Wiring Diagram
Solid State Industrial Timing Relays: Class 9050 Type FT
FIG. 8
FIG. 9
L1
L2
AC Supply Voltage
FPO 71-2
C1
C3
C5
C7
L1
L2
Instantaneous
Contacts
(optional)
P
C2
C4
Timed
Contacts
C6
C8
External Initiating Contact
Elementary Diagram
Wiring Diagram
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Timers
Class 9050
Solid State Industrial Timing Relays:
Class 9050 Type JCK
FIG. 1
FIG. 2
FIG. 3
External Initiating Contact
4
External Initiating Contact
(used in one-shot and
off-delay mode only)
6
5
5
3
6
7
8
4
6
5
7
7
2
3
1
8
+
9
–
1
11
+
–
Control Power
Polarity markings are for DC units
only. JCK 60 is AC only.
8
3
9
10
2
Control Power
4
1
Terminals 5 and 10 are internally jumpered. Applying
power to terminal 7 or jumpering from terminal 5 to 7
through an external contact initiates the timer.
Type JCK 11-19, 31-39 and 51-60
10
2
Polarity markings are for DC units only.
11
Control Power
Type JCK 21-29 and 41-49
Type JCK 70
Solid State Timers:
Class 9050 Type D
FIG. 4
FIG. 5
A1/+ 15 25
FIG. 6
A1 15 25
A1/+ 15 25 Z1 Z2
16 18 26 28 A2/–
A1 15 25 Z1 Z2
16 18 26 28 A2
16 18 26 28 A2/–
Vs
Vs
Vs
Type DER, DZM, DTR, DWE,
DEW and DBR
FIG. 7
Type DERP, DERLP, DWEP
and DZMP
16 18 26 28 A2
Vs
Type DAR
Type DARP
Solid State Timers:
Class 9050 Type M
FIG. 8
FIG. 9
17 25 A1
15
18 26 A2
16 18 A2
Vs
Type MAN, MBR, MER, MEW,
MTG, MWE and MZM
A1
Vs
Type MAR
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Transformer Disconnects
Class 9070
Transformer Disconnects:
Class 9070
Note: Some factory modifications, depending on enclosure and transformer VA size selected, are not available. Consult factory modification chart.
FIG. 1
L1
L2
FIG. 2
GND
L3
L1
L2
GND
L3
OFF
OFF
ON
ON
F
U
1
F
U
2
F
U
1
460 V
H1
F
U
2
460 V
230 V
H3
H2
H4
H1
H3
H2
H4
H1
H3
230 V
H2
H1
H4
Optional Connection
F
U
5
X1A
F
U
4
R
R
Power
On
F
U
3
X2B
X2A
F
U
5
F
U
4
X2A
Optional
For Size 1 Enclosures except w/ Form E23
L1
F
U
6
X1A
Optional
FIG. 3
L2
For Size 1 Enclosures w/ Form E23
FIG. 4
GND
L3
L1
L2
GND
L3
OFF
OFF
ON
F
U
1
ON
F
U
2
F
U
1
H3
F
U
2
230 V
460 V
H1
H2
H4
H1
H3
230 V
460 V
H2
H4
H1
H3
H2
H4
Optional Connection
F
U
5
X1A
F
U
4
R
R
Power
On
F
U
3
X2B
X2A
H3
H2
H4
Electrostatically
Shielded Transformer
X1 115 V X2
Power
On
X1B
H1
Optional Connection
X1 115 V X2
F
U
3
H4
Electrostatically
Shielded Transformer
X1 115 V X2
Power
On
X1B
H2
Optional Connection
X1 115 V X2
F
U
3
H3
X1A
F
U
7
F
U
5
X1B
F
U
6
F
U
8
X2B
F
U
4
X2A
Optional
Optional
For Size 2 Enclosures except w/ Form E23
For Size 2 Enclosures w/ Form E23
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Enclosure Selection Guide
Table 6
Enclosures for Non-Hazardous Locations
Provides Protection Against
NEMA
NEMA
NEMA
NEMA
NEMA
NEMA
Type 5
Type 1 Type 3 [1] Type 3R [1] Type 4 [2] Type 4X [2]
Type 12 [3]
Type 12K
NEMA
Type 13
Accidental contact w/ enclosed equipment
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Falling dirt
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Falling liquids and light splashing
…
Yes
Yes
Yes
Yes
…
Yes
Yes
Yes
Dust, lint, fibers and flyings
…
…
…
Yes
Yes
Yes
Yes
Yes
Yes
Hosedown and splashing water
…
…
…
Yes
Yes
…
…
…
…
Oil and coolant seepage
…
…
…
…
…
…
Yes
Yes
Yes
Oil and coolant spraying and splashing
…
…
…
…
…
…
…
…
Yes
Corrosive agents
…
…
…
…
Yes
…
…
…
…
Rain, snow and sleet [4]
…
Yes
Yes
[5]
Yes
…
…
…
…
…
[5]
Yes
Yes
…
…
…
Windblown dust
[1]
…
Yes
Intended for outdoor use.
[2]
Intended for indoor and outdoor use.
[3]
Square D Industrial Control design NEMA Type 12 enclosures may be field modified for outdoor applications.
[4]
External operating mechanisms are not required to be operable when the enclosure is ice covered.
[5]
Square D Industrial Control design NEMA Type 4 enclosures provide protection against these environments.
Table 7
Enclosures for Hazardous Locations
Enclosure
Class [1]
Group [1]
7B
7C
7D
9E
9F
9G
Hydrogen, manufactured gas
I
B
Yes
…
…
…
…
…
Ethyl ether, ethylene, cyclopropane
I
C
Yes
Yes
…
…
…
…
Gasoline, hexane, naphtha, benzine, butane, propane,
alcohol, acetone, benzol, natural gas, lacquer solvent
I
D
Yes
Yes
Yes
…
…
…
Metal dust
Il
E
…
…
…
Yes
…
…
Carbon black, coal dust, coke dust
Il
F
…
…
…
…
Yes
…
Flour, starch, grain dust
Il
G
…
…
…
…
Yes
Yes
Provides Protection Against
[1]
NEMA Type 7
NEMA Type 9
As described in Article 500 of the National Electrical Code.
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99
Conductor Ampacity and Conduit Tables
Based on 1993 National Electrical Code
Ampacity Based on NEC® Table 310-16 — Allowable Ampacities of Insulated Conductors Rated 0-2000 Volts, Not More Than Three Conductors
in Raceway or Cable. Based on 30 °C Ambient Temperature. Trade Size of Conduit or Tubing Based on NEC Chapter 9, Table 1 and Tables 3A,
3B, 3C, 4 and 5B. Refer to Chapter 9 for Maximum Number of Conductors in Trade Sizes of Conduit or Tubing. Dimensions of Insulated Conductors for Conduit Fill Determined from NEC Chapter 9 Tables 5 and 5A.
For information on temperature ratings of terminations to equipment, see NEC Section 110-14c. Underlined conductor insulation
types indicates ampacity is for WET locations. See NEC Table 310-13.
Table 8
Conductor Ampacity based on NEC Table 310-16
ALUMINUM CONDUCTORS
THWN, XHHW
Conduit Conduit Conduit Conduit
3W
3W
4W [2]
4W [2]
THHN, XHHW
Conduit Conduit
3W
4W [2]
Wire
Size
AWG
kcmil
Table 310-16
Ampacity
Insulated Copper
THHW, THW,
RW, USE
90 °C (194 °F)
Conductor Insulation [1]
Table 310-16
Ampacity
Insulated Copper
Wire
Size
AWG
kcmil
Table 310-16
Ampacity
Insulated Copper
75 °C (167 °F)
Conductor Insulation [1]
75 °C (167 °F)
Conductor Insulation [1]
90 °C (194 °F)
Conductor Insulation [1]
THHW, THW,
USE
Table 310-16
Ampacity
Insulated Copper
COPPER CONDUCTORS
XHHW
Conduit Conduit Conduit Conduit
3W
3W
4W [2]
4W [2]
THHN, XHHW
Conduit Conduit
3W
4W [2]
†14
20
…
…
1/2
1/2
25
1/2
1/2
…
…
…
…
…
…
…
…
…
†12
25
…
…
1/2
1/2
30
1/2
1/2
†12
20
…
…
1/2
1/2
25
1/2
1/2
†10
35
…
…
1/2
1/2
40
1/2
1/2
†10
30
…
…
1/2
1/2
35
1/2
1/2
8
50
3/4
1
1/2 [3]
3/4
55
1/2 [3]
3/4
8
40
3/4
3/4
1/2
3/4
45
1/2
3/4
3/4
[4]
3/4
[4]
6
65
1
1
3/4
75
3/4
6
50
3/4
1
3/4
3/4
60
3/4
3/4
4
85
1
1-1/4
1
1
95
1
1
4
65
1
1
3/4
1
75
3/4
1
3
100
1-1/4
1-1/4
1
1-1/4
110
1
1-1/4
3
75
…
…
…
…
85
…
…
2
115
1-1/4
1-1/4
1
1-1/4
130
1
1-1/4
2
90
1
1-1/4
1
1-1/4
100
1
1-1/4
1
130
1-1/4
1-1/2
1-1/4
1-1/2
150
1-1/4
1-1/2
1
100
1-1/4
1-1/2
1-1/4
1-1/2
115
1-1/4
1-1/2
1/0
150
1-1/2
2
1-1/4
1-1/2
170
1-1/4
1-1/2
1/0
120
1-1/4
1-1/2
1-1/4
1-1/2
135
1-1/4
1-1/2
2/0
175
1-1/2
2
1-1/2
2
195
1-1/2
2
2/0
135
1-1/2
2
1-1/4
1-1/2
150
1-1/4
1-1/2
3/0
200
2
2
1-1/2
2
225
1-1/2
2
3/0
155
1-1/2
2
1-1/2
2
175
1-1/2
2
4/0
230
2
2-1/2
2
2
260
2
2
4/0
180
2
2
1-1 /2
2
205
1-1/2
2
250
255
2-1/2
2-1/2
2
2-1/2
290
2
2-1/2
250
205
2
2-1/2
2
2
230
2
2
300
285
2-1/2
3
2
2-1/2
320
2
2-1/2
300
230
2
2-1/2
2
2-1/2
255
2
2-1/2
350
310
2-1/2
3
2-1/2
3
350
2-1/2
3
350
250
2-1/2
3
2-1/2
3
280
2-1/2
3
305
2-1/2
2-1/2 [5]
3
350
2-1/2
3
400
335
3
3
2-1/2
3
380
2-1/2
3
400
270
2-1/2
3
2-1/2
500
380
3
3-1/2
3
3
430
3
3
500
310
3
3
2-1/2
600
420
3
3-1/2
3
3-1/2
475
3
3-1/2
600
340
3
3-1/2
3
3
385
3
3
700
460
3-1/2
4
3
3-1/2
520
3
3-1/2
700
375
3
3-1/2
3
3-1/2
420
3
3-1/2
750
475
3-1/2
4
3-1/2
4
535
3-1/2
4
750
385
3
3-1/2
3
3-1/2
435
3
3-1/2
800
490
3-1/2
4
3-1/2
4
555
3-1/2
4
800
395
…
…
…
…
450
…
…
900
520
4
5
3-1/2
4
585
3-1/2
4
900
425
…
…
…
…
480
…
…
1000
545
4
5
3-1/2
5
615
3-1/2
5
1000
445
3-1/2
4
3-1/2
4
500
3-1/2
4
[1]
[2]
Unless otherwise permitted in the Code, the overcurrent protection for conductor types marked
with an with an obelisk (†) shall not exceed 15 A for No. 14, 20 A for No. 12 and 30 A for No. 10
copper, or 15 A for No. 12 and 25 A for No. 10 aluminum after any correction factors for ambient
temperature and number of conductors have been applied..
[3]
2-1/2
[5]
#8 XHHW copper wire requires 3/4" conduit for 3W.
[4]
#6 XHHW copper wire requires 1" conduit for 3Ø4W.
[5]
400 kcmil aluminum wire requires 3" conduit for 3Ø4W.
On a 4-wire, 3-phase wye circuit where the major portion of the load consists of nonlinear loads
such as electric discharge lighting, electronic computer/data processing, or similar equipment
there are harmonic currents present in the neutral conductor and the neutral shall be considered
to be a current-carrying conductor.
NEC is a Registered Trademark of the National Fire Protection Association.
®
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Conductor Ampacity and Conduit Tables
Based on 1993 National Electrical Code
Ampacity Correction Factors:
For ambient temperatures other than 30 °C (86 °F), multiply the ampacities listed in Table 8 by the appropriate factor listed in Table 9.
Adjustment Factors:
Where the number of current-carrying conductors in a raceway or cable exceeds three, reduce the allowable ampacities as shown in Table 9.
Table 9
Ampacity Correction Factors
Ambient
Temperature (°C)
75 °C (167 °F)
Conductors
90 °C (194 °F)
Conductors
Table 10
Adjustment Factors
Ambient
Temperature (°F)
No. of Current-Carrying
Inductors
Values in Tables as Adjusted
for Ambient Temperature
4-6
80%
21-25
1.05
1.04
70-77
26-30
1.00
1.00
78-86
7-9
70%
31-35
.94
.96
87-95
10-20
50%
36-40
.88
.91
96-104
21-30
45%
41-45
.82
.87
105-113
31-40
40%
46-50
.75
.82
114-122
41 and above
35%
51-55
.67
.76
123-131
56-60
.58
.71
132-140
61-70
.33
.58
141-158
71-80
…
.41
159-176
For exceptions, see exceptions to Note 8 of NEC® Table 310-16.
Ratings for 120/240 V, 3-Wire, Single-Phase Dwelling Services:
The ratings in Table 11 are permitted ratings for dwelling unit service and feeder conductors which carry the total load of the dwelling. The
grounded conductor (neutral) shall be permitted to be not more than 2 AWG sizes smaller than the ungrounded conductors, provided the requirements of 215-2, 220-22 and 230-42 are met.
Table 11
Ratings for 120/240 V, 3-Wire, Single-Phase Dwelling Services – see NEC 310-16 Note 3
Rating (A)
100
110
125
150
175
200
225
250
300
350
400
Copper
4 AWG
3 AWG
2 AWG
1 AWG
1/0 AWG
2/0 AWG
3/0 AWG
4/0 AWG
250 kcmil
350 kcmil
400 kcmil
Aluminum
2 AWG
1 AWG
1/0 AWG
2/0 AWG
3/0 AWG
4/0 AWG
250 kcmil
300 kcmil
350 kcmil
500 kcmil
600 kcmil
NEC 240-3 Protection of Conductors:
Conductors, other than flexible cords and fixture wires, shall be protected against overcurrent in accordance with their ampacities as specified
in NEC Section 310-15, unless otherwise permitted in parts (a) through (m).
NEC 220-3 (a) Continuous and Noncontinuous Loads:
The branch circuit rating shall not be less than the noncontinuous load plus 125% of the continuous load (see exception for 100% rated devices).
NEC 220-10 (b) Continuous and Noncontinuous Loads:
Where a feeder supplies continuous loads or any combination of continuous and noncontinuous loads, the rating of the overcurrent device shall
not be less than the noncontinuous load plus 125% of the continuous load (see exception for 100% rated devices).
NEC 430-22 (a) Single Motor Circuit Conductors:
Branch circuit conductors supplying a single motor shall have an ampacity not less than 125% of the motor full-load current rating (see exceptions).
NEC is a Registered Trademark of the National Fire Protection Association.
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101
Wire Data
Table 12
AWG
Size
Conductor
dia. (mm)
29
Conductor
dia. (in)
Resistance @ 20 °C (68 °F)
Ohm per ft
.08180
.2684
.01240
.06743
.2212
.01264
.06491
.2130
.01398
.05309
.1742
.01420
.05143
.1687
.01575
.04182
.1372
.01594
.04082
.1339
.01772
.03304
.1084
.01790
.03237
.1062
.01969
.02676
.08781
.02010
.02567
.08781
.02205
.02134
.07000
.02257
.02036
.06679
.02480
.01686
.05531
.02535
.01614
.05531
.02795
.01280
.04201
.02846
.01280
.04201
.750
.02953
.01190
.03903
.800
.03150
.01045
.03430
.315
.355
27
.400
26
.450
25
.500
24
.560
23
.630
22
.710
21
20
AWG
Size
Ohm per m
.01126
28
13
Conductor
dia. (mm)
Conductor
dia. (in)
Resistance @ 20 °C (68 °F)
Ohm per ft
Ohm per m
1.900
.07480
.001853
.006081
2.000
.07874
.001673
.005488
.08081
.001588
.005210
2.120
.08346
.001489
.004884
2.240
.08819
.001333
.004375
12
11
.09074
.001260
.004132
2.360
.09291
.001201
.003941
2.500
.09843
.001071
.003512
.1019
.0009988
.003277
2.650
.1043
.0009528
.003126
2.800
.1102
.0008534
.002800
10
9
.1144
.0007924
.002500
3.000
.1181
.0007434
.002439
3.150
.1240
.0006743
.002212
.1285
.0006281
.002061
3.350
.1319
.0005662
.001956
3.550
.1398
.0005309
.001742
8
7
.1443
.0004981
.001634
3.750
.1476
.0004758
.001561
4.000
.1575
.0004182
.001372
.1620
.0003952
.001296
.03196
.01015
.03331
.850
.03346
.009261
.05038
.900
.03543
.008260
.02642
4.250
.1673
.0003704
.001215
.03589
.008051
.02642
4.500
.1772
.0003304
.001084
.950
.03740
.007414
.02432
1.000
.03937
.006991
.02195
19
18
.04030
.006386
.02095
1.060
.04173
.005955
.01954
1.120
.04409
.005334
.01750
.04526
.005063
.01661
1.180
.04646
.004805
.01577
1.250
.04921
.004282
.01405
17
16
.05082
.004016
.01317
1.320
.05197
.003840
.01260
1.400
.05512
.004016
.01317
.05707
.003414
.01045
1.500
.05906
.002974
.009756
1.600
.06299
.002526
.008286
15
14
13
AWG and Metric Wire Data
6
5
.1819
.0003134
.001028
4.750
.1870
.0002966
.0009729
5.000
.1968
.0002676
.0008781
.2043
.0002485
.0008152
.2205
.0002134
.0007000
.2294
.0001971
.0006466
.2480
.0001686
.0005531
.2576
.0001563
0005128
.2795
.0001327
.0004355
.2893
.0001239
.0004065
.3150
.0001045
.0003430
.3249
.00009825
.0003223
.3543
.00008260
.0002710
.3648
.00007793
.0002557
.3937
.00006691
.0002195
.4096
.00006182
.0002195
.4600
.00004901
.0001608
.4646
.00004805
.0001577
4
5.600
3
6.300
2
7.100
1
8.000
0
9.000
2/0
.06408
.002315
.007596
1.700
.06693
.002315
.007596
3/0
10.000
1.800
.07087
.002065
.006775
4/0
.07196
.002003
.006571
11.800
®
102
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Electrical Formulas
Table 13
Electrical formulas for Amperes, Horsepower, Kilowatts and KVA
Single phase
3-phase
Direct current
I x E x PF
1000
I x E x 1.73 x PF
1000
IxF
1000
IxE
1000
I x E x 1.73
1000
—
I x E x % Eff x PF
746
I x E x 1.73 x %Eff x PF
746
I x E x %Eff
746
HP x 746
E x %Eff x PF
HP x 746
1.73 x E x %Eff x PF
HP x 746
E x %Eff
Amperes when Kilowatts is
known
KW x 1000
E x PF
KW x 1000
1.73 x E x PF
KW x 1000
E
Amperes
KVA x 1000
E
KVA x 1000
1.73 x E
—
To find
Kilowatts
KVA
Horsepower (output)
Amperes when Horsepower is
known
E=Volts
l = Amperes
%Eff = Percent efficiency
PF = Power factor
HP = Horsepower
KVA = Kilovolt-Amps
Average Efficiency and Power Factor Values of Motors:
When actual efficiencies and power factors of the motors to be controlled are not known, the following approximations may be used:
Efficiencies:
DC motors, 35 hp and less:
DC motors, above 35 hp:
Synchronous motors (at 100% PF):
80% to 85%
85% to 90%
92% to 95%
“Apparent” efficiencies (Efficiency x PF):
3-phase induction motors, 25 hp and less:
3-phase induction motors above 25 hp:
Decrease these figures slightly for single phase induction motors.
Table 14
Ratings for 3-Phase, Single-Speed, Full-Voltage Magnetic Controllers
for Nonplugglng and Nonjogging Duty
Continous
Current Rating
(A)
Size of
Controller
[1]
70%
80%
Horsepower at [1]
60 Hz 200 V
60 Hz 230 V
50 Hz 380 V
60 Hz
460 or 575 V
Service-Limit
Current Rating
(A)
00
9
1-1/2
1-1/2
1-1/2
2
11
0
18
3
3
5
5
21
1
27
7-1/2
7-1/2
10
10
32
2
45
10
15
25
25
52
3
90
25
30
50
50
104
4
135
40
50
75
100
156
5
270
75
100
150
200
311
6
540
150
200
300
400
621
7
810
—
300
—
600
932
These horsepower ratings are based on typical locked-rotor current ratings. For motors having higher locked-rotor currents,
use a larger controller to ensure its locked-rotor current rating is not exceeded.
®
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103
Electrical Formulas
Table 15
Ratings for 3-Phase, Single-Speed, Full-Voltage Magnetic Controllers
for Plug-Stop, Plug-Reverse or Jogging Duty
[1]
Horsepower at [1]
Continous
Current Rating
(A)
Size of
Controller
60 Hz 200 V
60 Hz 230 V
50 Hz 380 V
1-1/2
1-1/2
1-1/2
0
18
1
27
3
3
2
45
7-1/2
10
3
90
15
20
4
135
25
30
5
270
60
6
540
125
60 Hz
460 or 575 V
Service-Limit
Current Rating
(A)
2
21
5
5
32
15
15
52
30
30
104
50
60
156
75
125
150
311
150
250
300
621
These horsepower ratings are based on typical locked-rotor current ratings. For motors having higher locked-rotor currents,
use a larger controller to ensure its locked-rotor current rating is not exceeded.
Table 16
Power Conversions
From
to kW
to PS
to hp
to ft-lb/s
1 kW (kilowatt) = 1010 erg/s
1
1.360
1.341
737.6
1 PS (metric horsepower)
0.7355
1
0.9863
542.5
1 hp (horsepower)
0.7457
1.014
1
1 ft-lb/s (foot-pound per sec)
1.356 x
10-3
1.843 x
10-3
1.818 x
550.0
10-3
1
®
104
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