Solid State Relays
Because of their semiconductor technology-based design, SSRs provide a higher degree of reliability, longer life and reduced electromagnetic interference (EMI), as well as faster response times and vibration and shock resistance, when compared to the EMR counterparts. This is due to the fact that SSRs have no mechanical contacts to wear out or arc, which is the primary cause for EMR failure.
A curve without heatsink is given for the SO/SC or SG type of solid state relays. When mounted on the back plate of a cabinet, the relay/plate contact must be correct. An aluminium back plate of 150mm x 150mm x 3 mm corresponds to approximately 4°/W An aluminium back plate of 300mm x 300mm x 3 mm corresponds to approximately 2°/W In all cases, it is recommended to perform a test and measure the heat dissipation. A steel plate will have greater thermal resistance..
The relay will only turn on when the mains (output) voltage is near zero.
When the control voltage is on the relay will switch on at the same moment, whatever the mains voltage value.
Zero-cross relays are used with resistive loads while random turn-on relays are used with inductive loads (motors, transformers, coils etc.).
- Relay leakage current too high compared to the load holding current
- Short circuit relay
- Leakage current on the control device of the solid-state relay
- Relay undersized in voltage
Synchronous relay and continuous control: rectified unfiltered control Solution: put capacitor on order
Check that there is a connection between terminals 5 and 6 of the control terminal block.
This is not possible because of the technology used. In fact current will always go through one SSR only
This is possible but you should respect some conditions: This must be done for thermal reasons only (in fact each SSR should be specified to switch alone the load current) This is better to use DC SSRs with low turn-on time: SOM range is more suitable
For "heating" applications, it is preferable to use 2 or 3 single-phase relays. Our SGT / SVT in 75, 95, and 125A are suitable for applications with non-permanent peak currents (lamps, motors, ...) or for better protection.
Altitude affects insulation and heat dissipation, both of which decrease as altitude increases.
There are several ways to ensure the grounding of Solid State Relays: - solid state relays have an earth connection; or - their construction ensures a good connection to their mounting support (Din rail, plate, panel, etc.) which itself has an ensured earthing.
The easiest way is certainly to unplug the control and place an ammeter clamp on the power wire that goes to the load. On the control, you apply the required voltage in DC with a battery or an independent cell, or in AC with a power supply independent of the installation, the voltage sources having been checked beforehand. If you have a current without the control present, the relay is short-circuited, and if you have no output current while the control is applied, the relay does not work..
SVTA range is designed for tranformer control. The starting ramp must be adapted to the load (of the transformer) to avoid current pulse. In the worst case with a full conduction switch ON, the current can increase up to 30*In, in your case, the SVTA4694 will support this current pulse according to Non-repetitive peak overload current, but the margin of safety with this thyristor rating is not very important. Regards
The following is a list of common parameters that are helpful to know ahead of time for proper SSR selection :
■Line voltage
■Load type
■Load rating
■Switching mode
■Control voltage
■Control current
■Mechanical packaging
■Ambient temperature
....
Technical tricks : Here is an example of questionnaire to use : https://www.celduc-relais.com/wp-content/PDF/Questions_AC_UK.pdf