E-OEC DC60S-3 Solid-state relay Datasheet

Solid-State Relays
Features
Opto 22 Power
Series SSR
improvements and the same 100% testing policy established
over 30 years ago, Opto 22 is still recognized today for the very
high quality and reliability of all our solid-state relays.
Description
Overview
In 1974, Opto 22 introduced the first liquid epoxy-filled line of
power solid-state relays (SSR). This innovation in SSR design
greatly improved the reliability and reduced the cost of
manufacturing. At that time, we also incorporated into our
manufacturing process 100% testing under full load
conditions of every relay we produced.
By 1978, Opto 22 had gained such a reputation for reliability
that we were recognized as the world’s leading manufacturer
of solid-state relays. Through continuous manufacturing
Opto 22 offers a complete line of SSRs, from the rugged 120/
240/380-volt AC Series to the small footprint MP Series,
designed for mounting on printed circuit boards. All Opto 22
SSRs feature 4,000 volts of optical isolation, and most are UL
and CSA recognized. The innovative use of room-temperature
liquid epoxy encapsulation, coupled with Opto 22’s unique
heat-spreader technology, are key to mass producing the
world’s most reliable solid state relays.
Solid-State Relays
Rugged, epoxy encapsulation construction
4,000 volts of optical isolation
Subjected to full load test and six times the rated
current surge before and after encapsulation
Unique heat-spreader technology
Guaranteed for life
Every Opto 22 solid state relay is subjected to full load test and
six times the rated current surge both before and after
Part Numbers
Part
Description
Part
Description
AC Switching
AC Switching
120 VAC, 10 Amp, AC Control
575D15-12
575 VAC, 15 Amp, DC Control, Transient Proof
120A25
120 VAC, 25 Amp, AC Control
575D45-12
575 VAC, 45 Amp, DC Control, Transient Proof
240A10
240 VAC, 10 Amp, AC Control
575D30-HS
240A25
240 VAC, 25 Amp, AC Control
575 VAC, 30 Amp, DC Control, Transient Proof,
with integrated heatsink
240A45
240 VAC, 45 Amp, AC Control
575Di45-12
575 VAC, 45 Amp, DC Control, Transient Proof,
with LED Indicators
120D3
120 VAC, 3 Amp, DC Control
120D10
120 VAC, 10 Amp, DC Control
MP120D2
or P120D2
120 VAC, 2 Amp, DC Control.
P model is low profile.
120D25
120 VAC, 25 Amp, DC Control
120D45
120 VAC, 45 Amp, DC Control
MP120D4
or P120D4
120 VAC, 4 Amp, DC Control.
P model is low profile.
240D3
240 VAC, 3 Amp, DC Control
240D10
240 VAC, 10 Amp, DC Control
MP240D2
or P240D2
240 VAC, 2 Amp, DC.
P model is low profile.
240Di10
240 VAC, 10 Amp, DC Control, with LED Indicators
MP240D4
or P240D4
240 VAC, 4 Amp, DC.
P model is low profile.
240D25
240 VAC, 25 Amp, DC Control
MP380D4
380 VAC, 4 Amp, DC
Z Model, 120 VAC, 10 Amp, DC Control
240Di25
240 VAC, 25 Amp, DC Control, with LED Indicators
Z120D10
Z240D10
Z Model, 240 VAC, 10 Amp, DC Control
240D30-HS
240 VAC, 30 Amp, DC Control, with integrated
heatsink
240D45
240 VAC, 45 Amp, DC Control
240Di45
240 VAC, 45 Amp, DC Control, with LED Indicators
380D25
120A10
DC Switching
380 VAC, 25 Amp, DC Control
DC200P or
DC200MP
200 VDC, 1 Amp, DC Control.
P model is low profile.
380D45
380 VAC, 45 Amp, DC Control
DC60S-3
60 VDC, 3 Amp, DC Control
480D10-12
480 VAC, 10 Amp, DC Control, Transient Proof
DC60S-5
60 VDC, 5 Amp, DC Control
480D15-12
480 VAC, 15 Amp, DC Control, Transient Proof
480D25-12
480 VAC, 25 Amp, DC Control, Transient Proof
Accessories
480D25-HS
480 VAC, 25 Amp, DC Control, Transient Proof,
with integrated heatsink
SAFETY COVER
Power Series SSR safety cover
SSR-HS
Power Series SSR heatsink
SSR-THERMOPAD
Thermal conductive pad (pack of 10)
480D45-12
480 VAC, 45 Amp, DC Control, Transient Proof
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
DATA SHEET
60 VDC, 3 Amp, DC Control.
P model is low profile.
Form 0859-140606
DC60P or
DC60MP
PAGE
1
Solid-State Relays
encapsulation. This double testing of every part before it
leaves the factory means you can rely on Opto 22 solid state
relays. All Opto 22 SSRs are guaranteed for life.
Accessories for the Power-Series SSRs include a safety cover,
heatsink, and a matching thermal conductive pad. See page 3.
The MP Series packaging is designed with a minimum
footprint to allow maximum relay density on the printed
circuit board.
P Series
The P Series power relays provide low-profile [0.5 in.
(12.7 mm)] center mounting on printed circuit boards.
Power Series SSRs
Solid-State Relays
MP Series
Opto 22 provides a full range of
Power Series relays with a wide
variety of voltage (120–575 volts)
and current options (3–45 amps).
All Power Series relays feature 4,000
volts of optical isolation and have a
high PRV rating. Some Power Series
relays include built-in LEDs to
indicate operation.
See page 4.
HS Series SSRs
The HS Series features an integrated
heatsink, which makes them so cool.
These relays have less thermal
resistance inside, so heat dissipates
more easily than in a standard SSR
mounted to the same heatsink. With
the heatsink built-in, you don't have
to select one from a catalog, and
installation is much easier. See
page 13.
DC Series
The DC Series delivers isolated DC control to large OEM
customers worldwide. All DC control SSRs are LS TTL
compatible.
AC Series
The AC Series offers the ultimate in solid state reliability. All AC
Power Series relays feature a built-in snubber as well as zerovoltage turn-on and zero-current turn-off. Transient-proof
models offer self protection for noisy electrical environments.
Z Series SSRs
The Z Series employs a unique heat
transfer system that makes it
possible for Opto 22 to deliver a
low-cost, 10-amp, solid state relay
in an all-plastic case. The push-on,
tool-free quick-connect terminals
make the Z Series ideal for highvolume OEM applications.
Operating temperature: –40 °C to
100 °C. See page 7.
Form 0859-140606
DATA SHEET
Printed Circuit Series SSRs
PAGE
2
Opto 22’s Printed Circuit Series
allows OEMs to easily deploy solid
state relays on printed circuit
boards. Two unique packages are
available, both of which will switch
loads up to four amps. Operating
temperature: –40 °C to 100 °C. See
page 9.
Specifications
(all Power Series models)
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
4,000 V optical isolation, input to output
Zero voltage turn-on
Zero-current turn-off
Turn-on time: 0.5 cycle maximum
Turn-off time: 0.5 cycle maximum
Operating temperature: –40 °C to 100 °C
Operating frequency: 25 to 65 Hz
(operates at 400 Hz with six times off-state leakage)
Coupling capacitance, input to output: 8 pF maximum
Hermetically sealed
DV/DT Off-state: 200 volts per microsecond
DV/DT commutating: snubbed for rated current at
0.5 power factor
UL recognized
CSA certified
CE component
Torque specs for screws (this spec is both the
recommended torque and the maximum torque you
should use):
Control terminals, 10 in-lb (1.13 N-m)
Field terminals, 18 in-lb (2.03 N-m)
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Power Series SSR Accessories
25 Amp Relay on SSR-HS Heatsink Derating
30
Safety Cover
20
V
15
H
10
5
20
30
40
50
60
70
80
90 100
Ambient Temperature (°C)
V: Heatsink mounted to a vertical surface
H: Heatsink mounted to a horizontal surface.
Heatsink Assembly
An optional plastic safety cover can be installed on a Power Series SSR.
SSR-HS Heatsink
Custom designed for the Power Series SSRs, the SSR-HS
heatsink provides excellent heat dissipation when mounted to
the SSR with a matching thermal conductive pad, which is
used in place of silicon grease. One thermal pad is included
with the heatsink. Additional pads may be purchased in packs
of 10 (part number SSR-THERMOPAD).
Thermal Ratings
Before attaching the SSR, remove the protective film from
both sides of the thermal pad, then place the pad on the
heatsink making sure to align the holes. Secure the SSR to the
heatsink with the two 8-32 x 3/8˝ panhead Phillips screws
included in the kit. Use 20 in-lb (2.26 N-m) of torque.
Solid-State Relays
RMS Amperes
25
A plastic safety cover (Opto 22 part number SAFETY COVER) is
available for use with Opto 22 Power Series SSRs. The safety
cover reduces the chance of accidental contact with relay
terminals, while providing access holes for test
instrumentation.
Screws
Power Series SSR
(not included)
Thermal conductive pad
The thermal ratings shown in the following graphs were
obtained with an SSR attached to a heatsink using a thermal
conductive pad.
45 Amp Relay on SSR-HS Heatsink Derating
Heatsink
30
25
V
H
15
10
20
30
40
50
60
70
80
90 100
Ambient Temperature (°C)
V: Heatsink mounted to a vertical surface
H: Heatsink mounted to a horizontal surface.
NOTE: To take advantage of the
cooling effect of natural air flow,
mount the SSR/heatsink assembly to
a vertical surface with the Opto 22
logo right side up as shown here.
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
5
DATA SHEET
RMS Amperes
20
PAGE
3
Solid-State Relays
AC Power Series Specifications
Opto 22 provides a full range of Power Series relays with a wide variety of voltage (120–575) and current options (3–45 amps). All
Power Series relays feature 4,000 volts of optical isolation and have a high PRV rating. Operating temperature is –40 °C to 100 °C.
Solid-State Relays
Connection
Diagram
120/240/380
Volt
NOTE: Model numbers ending in -17 are replacement parts only. Their specifications are identical
to the same model number without the -17. For example, 240D10-17 is identical to 240D10.
Model Nominal Nominal 1 cycle
Nominal
Number AC Line Current Surge Signal Input
Voltage
Rating (Amps) Resistance
(Amps)
Peak
(Ohms)
120D3
120
3
85
1000
Signal
Dropout
Voltage
3VDC
(32V allowed)
1 VDC
600
1.6 volts
2.5mA
12–140
30
4,000VRMS
11
1.7
1 VDC
600
1.6 volts
7 mA
12–140
50
4,000VRMS
1.3
1.6
rent Control varies with control voltage. See “Control
120
10
110
1000
3VDC
ent120D10
Calculation”
on page
17 for
information.
(32V allowed)
Peak
Maximum Off-State Operating
I2t
Repetitive
Output
Leakage
Voltage Rating
Voltage
Voltage
(mA)
Range
t=8.3
Maximum
Drop
Maximum** (Volts AC) (ms)
θjc* Dissipation
(Watts/
(°C/Watt)
Amp)
Signal
Pick-up
Voltage
Isolation
Voltage
120D25
120
25
250
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
7 mA
12–140
250
4,000VRMS
1.2
1.3
120D45
120
45
650
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
7 mA
12–140
1750
4,000VRMS
0.67
0.9
240D3
240
3
85
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
5 mA
24–280
30
4,000VRMS
11
1.7
240D10
240
10
110
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
24–280
50
4,000VRMS
1.3
1.6
240Di10
240
10
110
730
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
24–280
50
4,000VRMS
1.3
1.6
240D25
240
25
250
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
24–280
250
4,000VRMS
1.2
1.3
240Di25
240
25
250
730
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
12–280
250
4,000VRMS
1.2
1.3
240D45
240
45
650
1000
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
24–280
1750
4,000VRMS
0.67
0.9
240Di45
240
45
650
730
3VDC
(32V allowed)
1 VDC
600
1.6 volts
14 mA
24–280
1750
4,000VRMS
0.67
0.9
380D25
380
25
250
1000
3VDC
(32V allowed)
1 VDC
800
1.6 volts
12 mA
24–420
250
4,000VRMS
1.2
1.3
380D45
380
45
650
1000
3VDC
(32V allowed)
1 VDC
800
1.6 volts
12 mA
24–420
1750
4,000VRMS
0.67
0.9
120A10
120
10
110
33K
85VAC
(280V allowed)
10 VAC
600
1.6 volts
7 mA
12–140
50
4,000VRMS
1.3
1.6
120A25
120
25
250
33K
85VAC
(280V allowed)
10 VAC
600
1.6 volts
7 mA
12–140
250
4,000VRMS
1.2
1.3
240A10
240
10
110
33K
85VAC
(280V allowed)
10 VAC
600
1.6 volts
14 mA
24–280
50
4,000VRMS
1.3
1.6
240A25
240
25
250
33K
85VAC
(280V allowed)
10 VAC
600
1.6 volts
14 mA
24–280
250
4,000VRMS
1.2
1.3
240A45
240
45
650
33K
85VAC
(280V allowed)
10 VAC
600
1.6 volts
14 mA
24–280
1750
4,000VRMS
0.67
0.9
Note: θjc* = Thermal resistance from internal junction to base. Maximum internal junction temperature is 110 °C.
** Operating Frequency: 25 to 65 Hz (operates at 400 Hz with 6 times the offstate leakage)
Form 0859-140606
DATA SHEET
Connection Diagram, DC Power Series
PAGE
4
*Control Current varies with control voltage. See “Control
Current Calculation” on page 17 for information.
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
120/240/380 Volt (cont.)
Thermal Ratings
Surge Current Data
3-Amp 10-Amp 25-Amp 45-Amp
Time
Time*
Peak
Peak
Peak
Peak
(Seconds) (Cycles) Amps Amps Amps Amps
1
85
110
250
650
0.050
3
66
85
175
420
0.100
6
53
70
140
320
0.200
12
45
60
112
245
0.500
30
37
50
80
175
1
60
31
40
67
134
2
120
28
33
53
119
3
180
27
32
49
98
4
240
26
31
47
95
5
300
25
30
45
91
10
600
24
28
42
84
Solid-State Relays
0.017
Note: *60 HZ.
Connection Diagram, AC Power Series
Mounted on a heat sink with
2 °C/watt rating
Mounted on a heat sink with
1 °C/watt rating
Dimensional Drawings
NOTE: All dimensions are nominal.
Side view: Part numbers
DC60S3, 120D3, and
240D3 only
Side view: All other
part numbers
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
+
DATA SHEET
3-32VDC Control
PAGE
5
Solid-State Relays
480/575 Volt
Solid-State Relays
Model
Number
Nominal Nominal 1 cycle Nominal
AC Line Current Surge Signal Input
Voltage Rating (Amps) Resistance
(Amps) Peak
(Ohms)
Signal
Pick-up
Voltage
Signal
Peak
Maximum Off-State Operating
Isolation
θjc* Dissipation
I2t
Drop- Repetitive Output
Leakage
Voltage Rating Voltage (°C/Watt) (Watts/Amp)
out
Voltage
Voltage
(mA)
Range
t=8.3
Voltage Maximum
Drop
Maximum** (Volts AC) (ms)
480D10-12
480
10
110
1000
3VDC
(32V allowed)
1 VDC
1200
3.2 volts
11 mA
100–530
50
4,000VRMS
1.2
2.5
480D15-12
480
15
150
1000
3VDC
(32V allowed)
1 VDC
1200
3.2 volts
11 mA
100–530
50
4,000VRMS
1.2
2.5
480D25-12
480
25
250
1000
3VDC
(32V allowed)
1 VDC
1000
1.6 volts
11 mA
100–530
250
4,000VRMS
1.3
1.3
480D45-12
480
45
650
1000
3VDC
(32V allowed)
1 VDC
1000
1.6 volts
11 mA
100–530
1750
4,000VRMS
0.67
0.9
575D15-12
575
15
150
1000
3VDC
(32V allowed)
1 VDC
1200
3.2 volts
15 mA
100–600
90
4,000VRMS
1.2
2.5
575D45-12
575
45
650
1000
3VDC
(32V allowed)
1 VDC
1000
1.6 volts
15 mA
100–600
1750
4,000VRMS
0.67
0.9
575Di45-12
575
45
650
730
3VDC
(32V allowed)
1 VDC
1000
1.6 volts
15 mA
100–600
1750
4,000VRMS
0.67
0.9
Note: θjc* = Thermal resistance from internal junction to base. Maximum internal junction temperature is 110 °C.
** Operating Frequency: 25 to 65 Hz (operates at 400 Hz with 6 times the offstate leakage)
Surge Current Data
Thermal Ratings
15-Amp 25-Amp 45-Amp
Time
Time*** 10-Amp
Peak
Peak
Peak
Peak
Second (Cycles) Amps
Amps
Amps
Amps
0.017
1
110
150
250
650
0.050
3
85
140
175
420
0.100
6
70
110
140
320
0.200
12
60
90
112
245
0.500
30
50
70
80
175
1
60
40
55
67
134
2
120
33
49
53
119
3
180
32
47
49
98
4
240
31
43
47
95
5
300
30
40
45
91
10
600
28
35
42
84
Mounted on a heat sink with
2 °C/watt rating
Mounted on a heat sink with
1 °C/watt rating
Form 0859-140606
DATA SHEET
Note: ***60 HZ
PAGE
6
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
480/575 Volt (cont)
Dimensional Drawings
NOTE: All dimensions are nominal.
3-32VDC Control
Side view: All other
part numbers
+
Solid-State Relays
Side view: Part numbers
DC60S3, 120D3, and
240D3 only
Z Series Specifications
AC Power: 120/240 Volt
The Z Series employs a unique heat transfer system that makes it possible for Opto 22 to deliver a low-cost, 10-amp, solid-state
relay in an all-plastic case. The push-on tool-free quick-connect terminals make the Z Series ideal for high-volume OEM
applications. Operating temperature is –40 °C to 100 °C.
NOTE: Part number Z240D10-17 is a replacement part only. Its specifications are identical to Z240D10.
Z120D10
Z240D10
240
10
10
1 cycle Surge (Amps) Peak
110
110
Nominal Signal Input Resistance (Ohms)
1000
1000
Signal Pick-up Voltage
3VDC (32V
allowed)
3VDC (32V
allowed)
Signal Drop-out Voltage
1 VDC
1 VDC
Peak Repetitive Voltage Maximum
600
600
Maximum Output Voltage Drop
1.6 volts
1.6 volts
Off-State Leakage (mA) Maximum**
6 mA
12 mA
Operating Voltage Range (Volts AC)
12–140
24–280
I t Rating t=8.3 (ms)
50
50
Isolation Voltage
4,000 VRMS
4,000 VRMS
θjc* (°C/Watt) Dissipation (Watts/Amp)
4
4
2
Notes: θjc* = Thermal resistance from internal junction to base. Maximum internal junction temperature is 110°C.
** Operating Frequency: 25–65 Hz (operates at 400 Hz with 6 times the offstate leakage)
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
120
Current Rating (Amps)
DATA SHEET
Nominal AC Line Voltage Nominal
PAGE
7
Solid-State Relays
AC Power: 120/240 Volt (cont.)
Surge Current Data
Solid-State Relays
Current vs. Ambient Ratings
Mounted on a heat sink with
2 °C/watt rating
Connection Diagram
*Control Current varies with control voltage. See “Control
Current Calculation” on page 17 for information.
Dimensional Drawings
Form 0859-140606
DATA SHEET
NOTE: All dimensions are nominal.
PAGE
8
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Printed Circuit Series Specifications
AC Power: MP and P Series
The MP Series packaging is designed with a minimum footprint to allow maximum relay density on the printed circuit board. The
P Series power relays provide low-profile for 0.5-inch (12.7 mm) center mounting on printed circuit boards. Operating
temperature: –40 °C to 100 °C.
MP120D2
or P120D2
MP240D2
or P240D2
MP240D4
or P240D4
MP380D4
Nominal AC Line Voltage 120
120
240
240
380
Nominal Current Rating
Amps
2
4
2
4
4
1 cycle Surge (Amps)
Peak
20
85
20
85
85
Nominal Signal Input
Resistance (Ohms)
1000
1000
1000
1000
1000
Signal Pick-up Voltage
3VDC***
(24V allowed)
3VDC***
(24V allowed)
3VDC***
(24V allowed)
3VDC***
(24V allowed)
3VDC***
(24V allowed)
Signal Drop-out Voltage
1 VDC
1 VDC
1 VDC
1 VDC
1 VDC
Peak Repetitive Voltage
Maximum
600
600
600
600
800
Maximum Output Voltage Drop
1.6 volts
1.6 volts
1.6 volts
1.6 volts
1.6 volts
Off-State Leakage mA
Maximum**
5 mA
5 mA
5 mA
5 mA
5 mA
Operating Voltage
Range (Volts AC)
12–140
12–140
24–280
24–280
24–420
I2t Rating t=8.3 (ms)
2
30
2
30
30
Isolation Voltage
4,000 VRMS
4,000 VRMS
4,000 VRMS
4,000 VRMS
4,000 VRMS
θjc* °C/Watt
20
6.5
20
6.5
6.5
Dissipation Watts/Amp
1.2
1.2
1.2
1.2
1.2
Rating (Motor Load)
1 FLA at 120 VAC 2.5 FLA at 240 VAC 1 FLA at 120 VAC 2.5 FLA at 240 VAC 2.5 FLA at 380 VAC
6 LRA at 120 VAC 6 LRA at 240 VAC 15 LRA at 120 VAC 15 LRA at 240 VAC 15 LRA at 380 VAC
Solid-State Relays
MP120D4
or P120D4
Notes: θjc* = Thermal resistance from internal junction to base. Maximum internal junction temperature is 110 °C.
** Operating Frequency: 25 to 65 Hz (operates at 400 Hz with 6 times the offstate leakage)
*** = P Series 32 volts maximum.
Connnection Diagram
NOTE: Part numbers ending in -17
are replacement parts only. Their
specifications are identical to the
same part number without the -17.
For example, P240D4-17 is identical
to P240D4.
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
DATA SHEET
*Control Current varies with control voltage. See “Control
Current Calculation” on page 17 for information.
PAGE
9
Solid-State Relays
AC Power: MP and P Series (cont.)
Dimensional Drawings
NOTE: All dimensions are nominal.
Solid-State Relays
Surge Current Data
Time
(Seconds)
Time*
(Cycles)
2-Amp
Peak Amps
4-Amp
Peak Amps
0.017
1
20
85
0.050
3
18
66
0.100
6
15
53
0.200
12
11
45
0.500
30
9
37
1
60
8.5
31
2
120
8
28
3
180
7.5
27
4
240
7
26
5
300
6.5
25
10
600
6
24
Note: *60 Hz
Form 0859-140606
DATA SHEET
Thermal Ratings
PAGE
10
Mounted on a heat sink with
2 °C/watt rating
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
DC Switching Series Specifications
Thermal Ratings
DC200P or
DC200MP
DC60S-3
DC60S-5
Operating Voltage
Range
5–60 VDC
5–200 VDC
5–60 VDC
5–60 VDC
Forward Voltage Drop
1.5 volts
at 3 amps
1.5 volts
at 1 amp
1.5 volts
at 3 amps
1.5 volts
at 5 amps
Nominal Currrent Rating 3 amps
1 amp
3 amps
5 amps
Off-State Blocking
60 VDC
250 VDC
60 VDC
60 VDC
Signal Pickup Voltage
3 VDC
32 Volts*
allowed
3 VDC
32 Volts*
allowed
3 VDC
32 Volts
allowed
3 VDC
32 Volts
allowed
1 VDC
1 VDC
Signal Dropout Voltage
1 VDC
1 VDC
Signal Input Impedance
1,000 ohms
1,000 ohms 1,000 ohms 1,000 ohms
1 Second Surge
5 amps
2 amps
5 amps
10 amps
Operating Temp. Range
–40 °C to
100 °C
–40 °C to
100 °C
–40 °C to
100 °C
–40 °C to
100 °C
Isolation Voltage
4,000 VRMS
4,000 VRMS 4,000 VRMS 4,000 VRMS
Off-State Leakage
1 mA
maximum
1 mA
maximum
1 mA
maximum
1 mA
maximum
Package Type
P/MP series
P/MP series
Power
series
Power
series
Turn-on Time
100 usec
100 usec
100 usec
100 usec
Turn-off Time
750 usec
750 usec
750 usec
750 usec
Solid-State Relays
DC60P
or DC60MP
Note: *MP series maximum allowed control signal is 24 VDC.
NOTE: When controlling an inductive load, like a solenoid or coil, a commutating diode
must be used. Install the commutating diode across the terminals of the load (not the
SSR terminals). This will protect the SSR from damage caused by voltage spikes when
turning off the load.
Mounted on a heat sink with
2 °C/watt rating
Model DC60MP Basic Schematic (also applies to the other SSRs on this page)
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
DATA SHEET
*Control Current varies with control voltage. See “Control
Current Calculation” on page 17 for information.
PAGE
11
Solid-State Relays
Dimensional Drawings
Solid-State Relays
NOTE: All dimensions are nominal.
Side view: Part numbers DC60S3,
120D3, and 240D3 only
(+)
(+)
(+)
Side view: All other part numbers
(+)
(+)
Form 0859-140606
DATA SHEET
(+)
PAGE
12
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
HS Series Specifications
The HS Series features an integrated heatsink, which makes them so cool. Because there is less thermal resistance internal to the
unit than in a standard SSR mounted to the same heat sink, heat dissipates more easily. The built-in heatsink means you don't
have to select a heatsink, and installation is much easier. Each HS-series SSR has built-in hardware for screw mounting and a builtin DIN-rail adapter clip for mounting to a 35mm DIN rail.
Model Number
240D30-HS
Operating Voltage Range (Volts AC)
Peak Repetitive Voltage Maximum
575D30-HS
240
480
575
24–280
100–530
100–600
600
1000
1200
Off-State Leakage (mA) Maximum**
5 mA
10 mA
12 mA
Nominal Output Voltage Drop (RMS)
1.0 volts
1.0 volts
1.0 volts
Nominal Current Rating (Amps)
30
25
30
1 cycle Surge (Amps) Peak
610
610
610
1550
1550
1550
2,500VRMS
2,500VRMS
2,500VRMS
2
I t Rating t=8.3 (ms)
Isolation Voltage (transient 4KV)
Dissipation (Nominal Watts/Amp)
1.0
1.0
1.0
Signal Pick-up Voltage
4VDC
(32V allowed)
4VDC
(32V allowed)
4VDC
(32V allowed)
Signal Drop-out Voltage
1 VDC
1 VDC
1 VDC
Nominal Signal Input Resistance (Ohms)
730
1000
1000
θja* (°C/Watt)
2.2
2.2
2.2
Solid-State Relays
Nominal AC Line Voltage
480D25-HS
Note: θja* = Thermal resistance from internal junction to ambient. Maximum internal junction
temperature is 110 °C.
** Operating Frequency: 25 to 65 Hz (operates at 400 Hz with 6 times the offstate leakage)
Surge Current Data, Peak Amps
50HZ
0.0167
610
580
0.05
394
375
0.1
300
386
0.2
230
219
0.5
164
156
1
126
120
2
112
106
3
92
87
4
89
85
5
85
81
10
79
75
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
60HZ
DATA SHEET
Time
Second
PAGE
13
Solid-State Relays
HS-series (cont.)
Thermal Ratings
30
30
25
A
20
25 Amp Models
RMS Amperes
30 Amp Models
RMS Amperes
Solid-State Relays
25
B
15
10
5
20
30
40
50
60
70
80
90 100
A
20
B
15
10
5
20
Ambient Temperature (°C)
30
40
50
60
70
80
90 100
Ambient Temperature (°C)
A: Single relay or with 0.75” spacing between relays. Derate above 40 °C; subtract 0.5 amp/°C.
B: Three relays side by side with 0.25” spacing. All relays with the same load. Derate above 40 °C; subtract 0.4 amp/°C.
NOTE: This data is for SSRs mounted to a horizontal surface. To take advantage
of the cooling effect of natural air flow, we recommend mounting HS-series SSRs
to a vertical surface with the Opto 22 logo right side up as shown here.
Dimensional Drawing
3.90" (99.1 mm)
3.50" (88.9 mm)
0.20" (5.1 mm)
1.25"
(31.8 mm)
0.25"
(6.4 mm)
3.21" (81.6 mm)
1.75"
(44.5 mm)
Form 0859-140606
DATA SHEET
4.81"
(122.2 mm)
PAGE
14
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Applications: Tips
Heat Sink Calculation
Like all semiconductor devices, SSR current ratings must be based on maximum internal junction temperature. All Opto 22 SSRs
operate conservatively at maximum internal junction temperatures of 110 °C. Use the equation below to calculate the maximum
allowable heat sink thermal resistance for your application. It is good engineering practice to provide a margin for error instead of
running the application right at the limits. If your application is near the thermal limit, it can be helpful to add a fan to move air
across the heat sink.
Sample Calculation 1
Solid-State Relays
IMPORTANT: Thermally conductive grease must be used between the relay base and the heat sink.
120-volt, 20-amp load; 50 °C ambient air temperature
Model: 120D25 SSR.
See the last two columns of the table on page 4 for thermal resistance and dissipation values for the 120D25. Also, see the note at
the bottom of the table.
Dissipation: 1.3 watts/amp
Thermal resistance: 1.2 °C/watt
Maximum junction temperature: 110 °C
The calculation would be as follows:
This calculation indicates that you
should select a heat sink with a thermal
resistance of less than 1.1 °C/watt.
Form 0859-140606
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
DATA SHEET
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
PAGE
15
Solid-State Relays
Sample Calculation 2
240-volt,18-amp load, 25 °C ambient air temperature
Model: 240D45
Solid-State Relays
See the last two columns of the table on page 4 for thermal resistance and dissipation values for the 240D45. Also, see the note at
the bottom of the table.
Dissipation: 0.9 watts/amp
Thermal resistance: 0.67 °C/watt
Maximum junction temperature: 110 °C
The calculation would be as follows:
This calculation indicates that you should
select a heat sink with a thermal resistance
of less than 4.6 °C/watt.
Duty Cycle Calculation
When solid-state relays are operated in an on/off mode, it may be advantageous to calculate the RMS value of the current through
the SSR for heat sinking or determining the proper current rating of the SSR for the given application.
IRMS = RMS value of load or SSR
T1 = Time current is on
I RMS =
(ION)2 x T1
T2 = Time current is off
T 1 + T2
Form 0859-140606
DATA SHEET
ION = RMS value of load current during on period
PAGE
16
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Transformer Loads
Control Current Calculation
Careful consideration should be given to the selection of the
proper SSR for driving a given transformer. Transformers are
driven from positive saturation of the iron core to negative
saturation of the core each half cycle of the alternating
voltage. Large inrush currents can occur during the first half
cycle of line voltage if a zero-voltage SSR happens to turn on
during the positive half cycle of voltage when the core is
already in positive saturation. Inrush currents greater than 10
times rated transformer current can easily occur. The following
table provides a guide for selecting the proper SSR for a given
transformer rating.
All Opto 22 DC-controlled SSRs have a control circuit
consisting of 1000 ohms in series with an Optocoupler LED.
The LED will drop 1 volt, so the voltage across the internal
resistor will be 1 volt less than the control voltage.
The control current (IC ) can be calculated from the control
voltage (VC ) as follows:
Examples:
3 VDC control voltage:
IC = (3 - 1)/1000 = 0.002 A (2 mA)
32 VDC control voltage:
IC = (32 - 1)/1000 = 0.031 A (31 mA)
For control voltages above 32 VDC, an external resistor can be
added in series with the SSR to limit the control current. Also, if
the device driving the control current to the SSR is limited, you
can limit the control current by using an external resistor (Re).
Solid-State Relays
IC = (VC - 1)/1000
IC = (VC - 1)/ (Re + 1000)
Re = [(VC - 1)/(IC)] -1000
To limit the control current to 2 mA, this simplifies to:
Re = 500 (VC - 3)
Solenoid Valve and Contactor Loads
All Opto 22 SSRs are designed to drive inductive loads such as
solenoid valves and electromechanical contactors. The built-in
snubber in each SSR assures proper operation into inductive
loads. The following table is a guide in selecting an SSR to
drive a solenoid or contactor.
120-Volt Coils
CONTACTOR
2-Amp
1-Amp
NEMA Size 4
4-Amp
3-Amp
NEMA Size 7
240-Volt Coils
SSR CURRENT
RATING
SOLENOID
CONTACTOR
2-Amp
1-Amp
NEMA Size 7
4-Amp
3-Amp
NEMA Size 7
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
SOLENOID
DATA SHEET
SSR CURRENT
RATING
PAGE
17
Solid-State Relays
Opto 22 SSRs for controlling single-phase motors are shown in
the following tables:
120-Volt Single-Phase
Non-Reversing Motors
Solid-State Relays
SSR Model
MOTOR RATING
P or MP120D2
1 Amp
Z120D10
1/4 HP
120D3
1-1/2 Amp
P or MP120D4
1-1/2 Amp
120D10 or 120A10
1/4 HP
120D25 or 120A25
1/3 HP
120D45
3/4 HP
Solid-State Relays in Series
In applications requiring higher voltage, two Opto 22 SSRs
may be operated in series for double the voltage rating. The
built-in snubber in each SSR assures proper voltage sharing of
the two SSRs in series. In the following diagram, two 240-volt,
45-amp SSRs are connected in series for operation on a 480volt line. The control is shown with a parallel hook-up but it
should be noted that a serial connection can also be
implemented.
240-Volt Single Phase
Non-Reversing Motors
SSR Model
MOTOR RATING
P or MP240D2
1 Amp
Z240D10
1/4 HP
240D3
1-1/2 Amp
P or MP240D4
1-1/2 Amp
240D10 or 240A10
1/3 HP
240D25 or 120A25
1/2 HP
240D45
1-1/2 HP
Lamp Loads
Since all Opto 22 AC output SSRs use zero-voltage turn-on, they
are ideal for driving incandescent lamps, because the initial
inrush current into a cold filament is reduced. The life of the
lamp is increased when switched by a zero-voltage turn-on SSR.
The following table is a guide to selecting an Opto 22 SSR for
switching a given incandescent lamp.
120 Volt Lamps
120-Volt Single-Phase
Reversing Motors
Form 0859-140606
DATA SHEET
LAMP RATING
2-Amp
100 Watt
4-Amp
400 Watt
10-Amp
1 Kilowatt
SSR Model
MOTOR RATING
P or MP240D2
1 Amp
Z240D10
1/4 HP
240D3
1-1/2 Amp
25-Amp
2 Kilowatt
45-Amp
3 Kilowatt
P or MP240D4
1-1/2 Amp
240D10 or 240A10
1/4 HP
240D25 or 120A25
1/3 HP
240D45
3/4 HP
240-Volt Single-Phase
Reversing Motors
PAGE
18
SSR CURRENT RATING
SSR Model
MOTOR RATING
480D10-12
1/4 HP
480D15-12
1/4 HP
240 Volt Rating
SSR CURRENT RATING
LAMP RATING
2-Amp
200 Watt
4-Amp
800 Watt
10-Amp
2 Kilowatt
25-Amp
4 Kilowatt
45-Amp
6 Kilowatt
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Heater Loads
Single-Phase Reversing Motor Control (cont.)
The following table is a guide to selecting the proper SSR for a
given heater load.
Nominal SSR
Current Rating
Maximum
Recommended
Heater Current
2-Amp
1½-Amp
4-Amp
2½-Amp
10-Amp
7½-Amp
25-Amp
18-Amp
45-Amp
35-Amp
10 480V
8-Amp
10 480V
8-Amp
The resistors are unnecessary if the control circuit is designed
to ensure that one SSR is off before the other SSR is on.
Three-Phase Motor Control
Solid-State Relays
Care should be taken in selecting a SSR for driving a heater
load if the load is cycled on and off in a continuous manner as
might occur in a temperature control application. Constant
cycling can cause thermal fatigue in the thyristor chip at the
point where the chip bonds to the lead frame. Opto 22
employs a thick copper lead frame for mounting the SCR chips
in the power series SSRs to eliminate thermal fatigue failures.
In addition, Opto 22 recommends operating any SSR at 75%
rated current for cycling heater loads to ensure complete
reliability.
Single-Phase Reversing Motor Control
The circuit diagram below illustrates a typical 1 Ø motor
winding inductance and the phase shift capacitor can cause
twice-line voltage to appear across the open SSR. A 240-volt
SSR should be used for a 120-volt line. During the transition
period when one SSR is turned on and the other SSR is going
off, both SSRs may be on. In this case, the capacitor may
discharge through the two SSRs, causing large currents to
flow, which may destroy the SSRs. The addition of RL as shown
will protect the SSRs from the short circuit capacitor discharge
current.
Three-phase motors may be controlled by solid-state relays as
shown. A third SSR as shown is optional, but not necessary.
The control windings may be connected in series or parallel.
Care should be taken to ensure that the surge current drawn
by the motor does not exceed the surge current rating of the
SSR.
240 Volt Three-Phase Motor
3/4 HP
240D10
3/4 HP
240A10
3/4 HP
240D25
2 HP
240A25
2 HP
240D45
3 HP
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
MOTOR
Z240D10
DATA SHEET
SSR MODEL
PAGE
19
Solid-State Relays
480 Volt Three-Phase Motors
FAQ: SSR Applications
SSR MODEL
MOTOR
Q : What is a solid-state relay?
480D10-12
1-½ HP
480D15-12
1-½ HP
A: A solid-state relay (SSR) is a semiconductor device that can
be used in place of a mechanical relay to switch electricity to a
load in many applications. Solid-state relays are purely
electronic, normally composed of a low current “control” side
(equivalent to the coil on an electromechanical relay) and a
high-current load side (equivalent to the contact on a
conventional relay). SSRs typically also feature electrical
isolation to several thousand volts between the control and
load sides. Because of this isolation, the load side of the relay is
actually powered by the switched line; both line voltage and a
load (not to mention a control signal) must be present for the
relay to operate.
Form 0859-140606
DATA SHEET
Solid-State Relays
Three-Phase Reversing Motor Control
PAGE
20
Three-phase reversing motor control can be implemented
with four SSRs as shown in the connection diagram. The SSRs
work in pairs with SSR1 and SSR3 operated for rotation in one
direction and SSR2 and SSR4 operated for rotation in the
reverse direction. The resistor R1 as shown in the connection
diagram protects against line-to-line shorts if SSR1 and SSR4
or SSR3 and SSR2 are on at the same time during the reversing
transition period. Use the following table as a guide to the
proper selection of an SSR for this application.
Resistor for
120V line
Resistor for
240V line
Q : What are the advantages of using an SSR over a
mechanical relay?
A: There are many applications that require a moderate
amount of power (W to kW) to be switched on and off fairly
rapidly. A good example would be the operation of a heater
element in a controlled-temperature system. Typically, the
amount of heat put into the system is regulated using pulsewidth modulation turning a fixed-power heating element on
and off for time periods ranging from seconds to minutes.
Mechanical relays have a finite cycle life, as their components
tend to wear out over thousands to millions of cycles. SSRs do
not have this problem; in the proper application, they could
be operated almost infinitely.
Opto 22
Relay
Motor Full
Load Rating
3-Amp
1.25-Amp
4 ohm 50 W
8 ohm 50 W
10-Amp
5-Amp
1 ohm 100 W
2 ohm 100 W
Q : What are the limitations of using an SSR?
A: SSRs have a few limitations when compared to the
capabilities of their mechanical counterparts. First, because
the relay is semiconductor-based, it will never turn all the way
on, nor off. This means that in the “on” state, the relay still has
some internal resistance to the flow of electricity, causing it to
get hot. When in the “off” state, the relay will exhibit a small
amount of leakage current, typically a few mA. This leakage
can conspire to keep some loads, especially ones with a high
impedance, from turning off! Additionally, SSRs are more
sensitive to voltage transients; while Opto 22 relays are very
well transient-protected, if a relay gets hit hard enough a
sufficient number of times, it will die or degrade. This makes
SSRs less ideal for driving highly inductive electromechanical
loads, such as some solenoids or motors. SSRs should also
never be used for applications such as safety power
disconnects, because even in the off state, leakage current is
present. Leakage current through an SSR also implies the
presence of a potentially high voltage. Even though the relay
is not conducting a large amount of current, the switched
terminal will still be “hot,” and thus dangerous.
25-Amp
8-Amp
.5 ohm 100 W
1 ohm 100 W
45-Amp
16-Amp
.25 ohm 150 W
.5 ohm 150 W
15-Amp
5-Amp
1 ohm 100 W
2 ohm 100 W
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Solid-State Relays
Q : Do you make multi-pole or multi-throw SSRs?
A: Opto 22 manufactures only single-pole, single-throw SSRs.
If multi-phase operation is required, just use a relay on each
phase. Because of the limitations on semiconductor devices of
the type used in SSRs, it is not practical to build single-device
multi-throw SSRs. However, an alternative to multi-throw
operation may be accomplished with multiple relays.
voltages and currents. Use a mechanical relay; it will work
much better.
Q : What agency approvals do your SSRs carry?
A: In general, Opto 22 relays carry UL, CSA, and CE approval.
See http://support.opto22.com. Additionally, some SSRs
contain VDE-approved optocouplers; contact Opto 22 for
more information.
A: No. There is no way to guarantee that two or more relays
will turn on simultaneously when operated in parallel. Each
relay requires a minimum voltage across the output terminals
to function; because of the optical isolation feature, the
“contact” part of the SSR is actually powered by the line it
switches. One relay turning on before the other will cause the
second relay to lose its turn-on voltage, and it won’t ever turn
on, or at least not until the first relay fails from carrying too
much current.
Q : What does a “zero-crossing” turn-on circuit refer
to?
A: An AC sine wave will be positive for the first half of each
cycle and negative for the second half of each cycle. The
voltage will cross through zero when the sine wave changes
from the positive half-cycle to the negative half-cycle, and vice
versa. So the voltage crosses through zero twice with each full
AC sine wave cycle. “Zero-crossing” turn-on means that the
SSR will only turn on when the AC sine wave passes through
zero voltage. The actual turn-on will occur at or near zero
voltage. All Opto 22 AC output solid-state relays are designed
with a zero-crossing turn-on circuit. Zero-voltage turn-on has
the benefit of minimizing electrical noise. All Opto 22 AC
output solid-state relays use a zero-current turn-off circuit as
well.
Q : Can I use an AC SSR to switch DC?
A: No. Because of the zero-crossing circuit described above,
the relay will most likely never turn on, and even if it is on, it
will most likely not be able to be turned off.
Q : Can I use a DC SSR to switch AC?
A: This is not recommended at all. First, the voltage drop across
the relay will cause signal loss. Second, the conduction
characteristics of the SSR are very non-linear at low operating
A: There is no “normal” mode of failure for SSRs. They just stop
working, by refusing to turn on or off. An improper installation
is often to blame for an SSR failure, as these are very simple,
reliable devices. If you have a failed SSR, it is important to look
at the normal operating parameters of that relay within the
larger system to make sure that the relay being used is
appropriate to the application, and that the relay is being
properly installed in the system. The three most common
causes of SSR failure are as follows:
•
SSR improperly matched to load. The relay was
destroyed by overheating from carrying too much
current too long.
•
SSR insufficiently protected. Remember, a
semiconductor is less tough than a simple metal contact.
Reverse voltages exceeding the PRV rating of the relay
will cause damage. Voltage spikes on the switched line,
perhaps from inductive kickback, may have destroyed
one or more of the internal switching devices.
Remember to use snubbers, transorbs, MOVs, and/or
commutating diodes on highly inductive loads.
•
SSR improperly installed. The SSR was not mounted to
a large enough heat sink, or no thermal compound was
used, causing the relay to overheat. Also, insufficient
tightening of the load terminals can cause arcing and
ohmic heating of the relay. Opto 22 recommends 18
inch-pounds of torque on the load screw terminals.
Similar failures have also been attributed to the use of
crimp-on terminal lugs or spades; make sure such
terminals are tightly crimped, and even drip some solder
into the joint to ensure good electrical contact and
protection from corrosion.
Q : How can I test my SSR?
A: It is not possible to test an SSR by the same methods used
to test mechanical relays; a typical SSR will always show an
infinite impedance to a resistance meter placed across the
output terminals. There are a few reasons for this. First, the SSR
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
Form 0859-140606
Q : Can a DC SSR be used to switch an analog signal?
Q : My SSR does not function anymore. What may
have happened?
DATA SHEET
A: No. The semiconductor device used in Opto 22’s DC SSRs is
polarized. It may break down and conduct for the portion of
the waveform that is reversed in polarity.
FAQ: SSR Troubleshooting
Solid-State Relays
Q : Can I hook up SSRs in parallel to achieve a higher
current rating?
PAGE
21
Solid-State Relays
Solid-State Relays
requires a small amount of power to operate, derived from
whatever voltage source is placed on the load terminals. A
typical multimeter will not supply sufficient voltage to cause
the relay to change state. Second, AC SSRs contain zerovoltage turn-on and zero-current turn-off circuits. The SSR will
not be able to turn on unless there is AC voltage connected to
the output terminals. Most test equipment will supply a DC
voltage to the relay, so it will never see the zero-voltage
transition it requires to turn on. To test an SSR, it is best to
operate it at the actual line voltage it will be used at, driving a
load such as a large light bulb.
Q : I have an SSR driving a load. The load turns on
okay, but never seems to turn off, unless I remove
power from the relay entirely. What might be happening?
A: This is normally a problem when using an SSR with a highimpedance load, such as a neon lamp or a small solenoid.
Loads like these often have relatively large initial currents, but
relatively small “hold in” currents. The result is that the off-state
leakage current through the relay (see previous section) is
insufficient to cause the load to turn on to start with, but
sufficient to keep it on, once started. The solution is to place a
power resistor, sized for 8–10 times the rated maximum
leakage current for the SSR in parallel with the load. Make sure
that this resistor has a high enough power rating for the
application. For example, for a 5 mA leakage current at 120
VAC, a resistor drawing 50 mA would be desirable. Using
Ohm’s Law, the resistor value becomes 2,400 ohms. This
resistor will dissipate 6 watts, so a 7.5 or 10-watt size power
resistor should be used.
Form 0859-140606
DATA SHEET
Q : I have a new AC SSR driving a solenoid. It turns on
okay once, but will not turn on again. What is going
on?
PAGE
22
A: Some solenoids, some types of halogen lights, and some
types of strobe lights incorporate a diode in series with the coil
or filament. This causes the light to behave as a half-wave
rectifier. Opto 22 SSRs have a built-in R-C snubber circuit in
parallel with the output. The capacitor in this circuit charges
up but cannot discharge through the series diode, causing a
voltage to appear across the SSR terminals. Because the SSR
must detect the AC waveform cross through zero volts on the
load terminals, it will not be able to turn on again. The solution
here would be to put a high-value resistor (several tens of
Kohms) across the terminals of the relay, to allow the capacitor
to drain its charge.
Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • www.opto22.com
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2006–2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
More About Opto 22
Products
Opto 22 develops and manufactures reliable, flexible, easy-to-use
hardware and software products for industrial automation,
energy management, remote monitoring, and data acquisition
applications.
groov
groov puts your system on your mobile device. With zero
programming, you can build mobile operator interfaces to
monitor and control systems from Allen-Bradley, Siemens,
Schneider Electric, Modicon, and many more. Web-based groov
puts mobile-ready gadgets at your fingertips. Tag them from your
existing tag database, and they automatically scale for use on any
device with a modern web browser. See groov.com for more
information and your free trial.
SNAP PAC System
Designed to simplify the typically complex
process of selecting and applying an
automation system, the SNAP PAC
System consists of four integrated
components:
• SNAP PAC controllers
• PAC Project™ Software Suite
• SNAP PAC brains
• SNAP I/O™
SNAP PAC Controllers
Programmable automation controllers
(PACs) are multifunctional, modular controllers based on open
standards.
Opto 22 has been manufacturing PACs for over two decades. The
standalone SNAP PAC S-series, the rack-mounted SNAP PAC Rseries, and the software-based SoftPAC™ all handle a wide range
of digital, analog, and serial functions for data collection, remote
monitoring, process control, and discrete and hybrid
manufacturing.
SNAP PACs are based on open Ethernet and Internet Protocol (IP)
standards, so you can build or extend a system easily, without the
expense and limitations of proprietary networks and protocols.
Wired+Wireless™ models are also available.
PAC Project Software Suite
Opto 22’s PAC Project Software Suite provides full-featured, costeffective control programming, HMI (human machine interface)
development and runtime, OPC server, and database connectivity
software for your SNAP PAC System.
Control programming includes both easy-to-learn flowcharts and
optional scripting. Commands are in plain English; variables and I/
O point names are fully descriptive.
PAC Project Basic offers control and HMI tools and is free for
download on our website, www.opto22.com. PAC Project
Professional, available for separate purchase, adds one SoftPAC,
OptoOPCServer, OptoDataLink, options for controller redundancy
or segmented networking, and support for legacy Opto 22 serial
mistic™ I/O units.
SNAP PAC Brains
While SNAP PAC controllers provide central control and data
distribution, SNAP PAC brains provide distributed intelligence for
I/O processing and communications. Brains offer analog, digital,
and serial functions, including thermocouple linearization; PID
loop control; and optional high-speed digital counting (up to 20
kHz), quadrature counting, TPO, and pulse generation and
measurement.
SNAP I/O
I/O provides the local connection to sensors and equipment.
Opto 22 SNAP I/O offers 1 to 32 points of reliable I/O per module,
depending on the type of module and your
needs. Analog, digital, and serial modules are
all mixed on the same mounting rack and
controlled by the same processor (SNAP PAC
brain or rack-mounted controller).
Quality
Founded in 1974, Opto 22 has established a
worldwide reputation for high-quality products.
All are made in the U.S.A. at our manufacturing
facility in Temecula, California. Because we
test each product twice before it leaves our
factory, rather than only testing a sample
of each batch, we can guarantee most
solid-state relays and optically isolated I/O
modules for life.
Free Product Support
Opto 22’s California-based Product Support Group offers free,
comprehensive technical support for Opto 22 products. Our staff
of support engineers represents decades of training and
experience. Support is available in English and Spanish by phone
or email, Monday–Friday, 7 a.m. to 5 p.m. PST.
Additional support is always available on our website: how-to
videos, OptoKnowledgeBase, self-training guide, troubleshooting
and user’s guides, and OptoForums.
In addition, hands-on training is available for free at our Temecula,
California headquarters, and you can register online.
Purchasing Opto 22 Products
Opto 22 products are sold directly and through a worldwide
network of distributors, partners, and system integrators. For
more information, contact Opto 22 headquarters at 800-3216786 or 951-695-3000, or visit our website at www.opto22.com.
www.opto22.com
www.opto22.com • Opto 22 • 43044 Business Park Drive • Temecula, CA 92590-3614 • Form 1335-131203
SALES 800-321-6786 • 951-695-3000 • FAX 951-695-3095 • [email protected] • SUPPORT 800-835-6786 • 951-695-3080 • FAX 951-695-3017 • [email protected]
© 2014 Opto 22. All rights reserved. Dimensions and specifications are subject to change. Brand or product names used herein are trademarks or registered trademarks of their respective companies or organizations.
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