SECTION 7
Magnecraft Solution Guide 105A
Magnecraft Solution Guide 105A
755785
711
303
Series
385
Latching, Sequence and Impulse Relays – Application Data
Energy Conservation Relays
In many applications it is important for the customer to conserve electrical energy. One approach to energy conservation in
an electrical system is to use relays that do not require constant power to maintain contact closure.
“Latching relay” is a generic term that is used to describe a relay that maintains its contact position after the control power
has been removed. Latching relays allow a customer to control a circuit by simply providing a single pulse to the relay control
circuit. Latching relays are also desirable when the customer needs to have a relay that maintains its position during an
interruption of power.
There are three main types of Latching relays. Magnetic latching, Mechanical Latching and Impulse Sequencing.
Magnetic Latching Relays
Magnetic Latching relays require one pulse of coil power to move their contacts in one direction, and another, redirected pulse
to move them back. Repeated pulses from the same input have no effect. Magnetic Latching relays are useful in applications
where interrupted power should not be able to transition the contacts.
Magnetic Latching relays can have either single or dual coils. On a single coil device, the relay will operate in one direction
when power is applied with one polarity, and will reset when the polarity is reversed. On a dual coil device, when polarized
voltage is applied to the reset coil the contacts will transition. AC controlled magnetic latch relays have single coils that
employ steering diodes to differentiate between operate and reset commands.
Mechanical Latching Relays
Mechanical latching relays use a locking mechanism to hold their contacts in their last set position until commanded to change
state, usually by means of energizing a second coil. Since the relay does not rely on a magnet, the locking strength will
not degrade over time or weaken during thermal cycling. The contacts will remain locked in the directed position until the
opposing coil has been energized. Packaging machinery that places several units into a single container would be a good
example.
Impulse Relays
Impulse relays are a form of latching relay that transfers the contacts with each pulse. Many impulse relays are made up of a
magnetic latch relay and a solid state steering circuit that, upon application of power, determines which position the relay is
in and energizes the opposite coil. The contacts transfer and hold that position when power is removed. When reenergized,
the contacts transfer again and hold that position, and so on. In order to transfer the contacts, one simply provides a single
unidirectional pulse. There is no need to redirect the control pulse or reverse the polarity.
Impulse relays can be used as wear equalizers. They are well suited for applications such as turning a single device on or off
from one or more locations with a single momentary switch or push button at each station. For example, a conveyor could be
started and/or stopped from multiple locations by means of a single button at each position.
7/2
Magnecraft Solution Guide 105A
SECTION 7
Magnecraft Solution Guide 105A
INDUSTRIAL
AUTOMATION
PACKING
MACHINES
PUMPING
MACHINES COMPRESSORS INDUSTRIAL
FANS
INDUSTRIAL
APPLIANCES
www.magnecraft.com 847-441-2540
Alternating Relay – Application Data
Applications:
712 Alternating Relay
In many industrial pumping applications, two identical pumps are used for the same job. A standby unit is available in case
the first pump fails. However, a completely idle pump might deteriorate and provide no safety margin. Alternating relays
prevent this by assuring that both pumps get equal run time.
The Model 712 Series Alternating Relay is designed for duplex pumping systems where it is desirable to equalize pump run
time. The solid state alternating circuit drives an internal electromechanical relay. A continuous power source and control
switch is required.
The control switch (float, pressure or other isolated contact) is connected as shown in the respective wiring diagrams. Each
time the control switch is opened the output contacts will change status. Indicator lights on the case show the internal relay
status.
Setting the top toggle switch to the “center position” alternates the load; while setting the switch to “Load 1” or “Load 2” will
lock the relay in the respected position, preventing alternation.
The alternating relay approach isn’t limited to pumping applications. The control switches could be thermostats or pressure
switches, and the loads could be fans or compressors.
7/3
SECTION 7
Magnecraft Solution Guide 105A
Magnecraft Solution Guide 105A
Single Coil (DC) Single Coil (AC)Dual Coil (DC)
A
A1
7
11
14
4
12
1
B
A2
9
21
24
6
22
3
RESET
OPERATE
A
A1
7
11
14
4
12
1
B
A2
9
21
24
6
22
3
8
B2 OPERATE
RESET
COMMON
A
A1
7
11
14
4
12
1
B
A2
9
21
24
6
22
3
8
B2
B1
5
RESET
OPERATE
COIL
2
COIL 1
IEC
NEMA
1.53
(38.8)
1.4
(35.5)
1.9
(48.4)
0.032
(0.812)
0.1875 QUICK
CONNECTS
785 Magnetic Latching Square Base Relay/DPDT, 16 Amp Rating
Single and Dual (DC only)
coil available.
16 Amp switching
capabilities
High strength magnetic
latch helps contacts hold
during vibration.
Standard .1875 blade
style socket mounting.
WIRING DIAGRAMS
Units
A
V
Resistive
Resistive
Resistive
HP
HP
Pilot Duty
mA
V
V
VA
W
(Resistive)
ms
V(rms)
V(rms)
V(rms)
°C
°C
g-n
g-n
grams
Standard
DPDT
Silver Alloy
16
300
16A @ 277V 50/60Hz
16A @ 120V 50/60Hz
16A @ 28V
1/3 @ 120 VAC
1/2 @ 240 VAC
B300
100 @ 5 VDC (.5W)
6....240, 50/60 Hz
6....125
85% to 110%
80% to 110%
3
1.4
15%
10%
100,000
5,000,000
20
1500
1500
1500
UL, CSA, CE
-40...+85
-40...+55
3, 10 - 55 Hz
10
IP 40
87
% of Nominal
Operations @ Rated Current
Unpowered
Between coil and contact
Between poles
Between contacts
Standard version
Storage
Operation
Operational
Contact Characteristics
Number and type of Contacts
Contact materials
Thermal (Carrying) Current
Maximum Switching Voltage
Switching Current @ Voltage
Minimum Switching Requirement
Coil Characteristics
Voltage Range
Operating Range
Average consumption
Drop-out voltage threshold
Performance Characteristics
Electrical Life (UL508)
Mechanical Life
Operating time (response time)
Dielectric strength
Environment
Product certifications
Ambient air temperature
around the device
Vibration resistance
Shock resistance
Degree of protection
Weight
General Specifications (UL 508)
~
~
~
~
~
~
~
~
~
785XBX
WHITE
UL Recognized
File No. E43641
UL
US
C
UL Listed When Used With
Magnecraft Sockets.
7/14
Magnecraft Solution Guide 105A
SECTION 7
Magnecraft Solution Guide 105A
Other mating sockets see Section 2: 70-788EL11-1, 70-124-1, 70-124-2,
70-178-1, 70-178-2
Part Number Builder
(63)
(92)
(96)
2.48
3.62
3.7
2.93
(74)
BOLD-FACED PART NUMBERS ARE NORMALLY STOCKED
www.magnecraft.com 847-441-2540
785
Series
785
XBX
Contact Configuration
DPDT = XBX
C
Coil Options
Single Coil = C
Double Coil = CD
–
240A
Coil Voltage
VAC = 6 - 240A
VDC = 6 - 125D
Coil Resistance
32 Ohms
120 Ohms
470 Ohms
10,000 Ohms
40,000 Ohms
22/22 Ohms
88/88 Ohms
350/350 Ohms
1,400/1,400 Ohms
9,000/9,000 Ohms
120 Ohms
470 Ohms
10,000 Ohms
Part Number
785XBXC-6A
785XBXC-12A
785XBXC-24A
785XBXC-120A
785XBXC-240A
785XBXCD-6D
785XBXCD-12D
785XBXCD-24D
785XBXCD-48D
785XBXCD-110D
785XBXC-12D
785XBXC-24D
785XBXC-125D
Nominal Voltage
AC Operated (Single Coil)
6 VAC 50/60 HZ
12 VAC 50/60 HZ
24 VAC 50/60 HZ
120 VAC 50/60 HZ
240 VAC 50/60 HZ
DC Operated (Dual Coil)
6 VDC
12 VDC
24 VDC
48 VDC
110/125 VDC
DC Operated (Single Coil)
12 VDC
24 VDC
110/125 VDC
Standard Part Numbers
70-788EL11-1
SOCKET
The 785 Magnetic Latching relay, with
an Industry Standard square base,
operates by using a pulsed input. A
permanent magnet maintains the last
position until a redirected second
pulse moves the contacts back to the
original state.
7/15
