70S2-04-B-12-N Magnecraft / Schneider Electric, 70S2-04-B-12-N Datasheet - Page 26

Solid State Relays 140VAC, 30VDC, 12A 30V PM SSR

70S2-04-B-12-N

Manufacturer Part Number

70S2-04-B-12-N

Description

Solid State Relays 140VAC, 30VDC, 12A 30V PM SSR

Manufacturer

Magnecraft / Schneider Electric

Datasheets

1.70S2-04-B-12-N.pdf (3 pages)

2.70S2-01-A-05-N.pdf (32 pages)

3.70S2-04-D-03-V.pdf (22 pages)

Specifications of 70S2-04-B-12-N

Control Voltage Range

3 VDC to 30 VDC

Load Voltage Rating

24 VAC to 140 VAC

Load Current Rating

12 A

Output Device

Triac

Mounting Style

Panel

Operating Voltage Range

24VAC To 140VAC

Load Current

12A

Isolation Voltage

4000VAC

Control Voltage Type

Relay Terminals

Blade

Load Voltage Max

140VAC

Brand/series

70S2 Series

Contact Form

SPST-NO

Current, Rating

12 A

Dielectric Strength

3000 V (RMS)

Function

Zero-Switching

Mounting Type

Panel

Relay Type

Solid State

Standards

UL, CSA

Termination

Screw

Voltage, Control

30 VDC

Voltage, Rating

140 VAC

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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Application Data

(continued)

Magnecraft

Thermal Considerations

One of the major considerations when using a SSR is properly managing the heat

that is generated when switching currents are higher than 5 A� In this scenario

mount the base plate of the SSR on a good heat conductor, such as aluminum, and

use a good thermal transfer medium, such as thermal grease or a heat transfer pad�

Using this technique, the SSR case to heat sink thermal resistance is reduced to a

negligible value of 0.1 ˚C/W.

Thermal Calculations

To understand the thermal relationship between the output semiconductor junction (T

and the surrounding ambient temperature (T

drop of temperature, from junction to ambient (T

thermal resistances multiplied by the junction power dissipation�

To use the equation, the maximum junction temperature of the semiconductor must

be known, typically 125 ˚C, along with the actual power dissipation. When these two

parameters are known, the third can be found as shown in the following example:

1) Determine the maximum allowable ambient temperature, for a 1 ˚C/W heat sink

and a 10 A load (12 watts) with a maximum allowable junction temperature (T

of 100 ˚C, and assume a thermal resistance from junction to case (R

2) Determine the required heat sink thermal resistance, for 71.2 ˚C maximum

ambient temperature and a 10 amp load (12 watts):

3) Determine maximum load current, for 1 ˚C/W heat sink and 71.2 ˚C ambient temperature:

Where: T

өSA

- T

= P (R

= 12 (1.3 + 0.1 + 1.0) hence:

= 28.8

= T

= 100 - 71.2 - (1.3 + 0.1)

= 1 °C/W

= 12 watts

өJC

өCS

өSA

1.3 + 0.1 + 1.0

өJC

- T

= Junction Temperature, °C

= Ambient Temperature, °C

= Power Dissipation (I

= Thermal Resistance, junction to case, °C/W

= Thermal Resistance, case to sink, °C/W

= Thermal Resistance, sink to ambient, °C/W

100 - 71.2

өJC

- T

+ R

- (R

+ R

Solid State Relays

- T

өCS

= P (R

өJC

өCS

+ R

өSA

өJC

өCS

өSA

)

+ R

) measure the temperature gradient, or

)

hence:

- T

өCS

); which equals the sum of the

+ R

LOAD

өSA

3 E

LOAD

)

= T

= 100–28.8

= 71.2 °C

DROP

= 10 amperes

1.2

) watts

–28.8

өJC

DROP

) of 1�3:

)

70S2-04-B-12-N Magnecraft / Schneider Electric, 70S2-04-B-12-N Datasheet - Page 26

70S2-04-B-12-N

Specifications of 70S2-04-B-12-N

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