Protection and Relay Schemes

1. Protection and Relay Schemes

2. Agenda • Introduction of Protective Relays • Electrical System Protection with Protective Relays • Conclusion

3. What are Relays? • Relays are electrical switches that open or close another circuit under certain conditions.

4. Advantages for Using Protective Relays • Detect system failures when they occur and isolate the faulted section from the remaining of the system. • Mitigating the effects of failures after they occur. Minimize risk of fire, danger to personal and other high voltage systems.

5. Relay Types • Electromagnetic Relays (EMRs) • EMRs consist of an input coil that's wound to accept a particular voltage signal, plus a set of one or more contacts that rely on an armature (or lever) activated by the energized coil to open or close an electrical circuit. • Solid-state Relays (SSRs) • SSRs use semiconductor output instead of mechanical contacts to switch the circuit. The output device is optically-coupled to an LED light source inside the relay. The relay is turned on by energizing this LED, usually with low-voltage DC power. • Microprocessor Based Relays • Use microprocessor for switching mechanism. Commonly used in power system monitoring and protection.

6. How a Relay Works

7. Sold-State Relay

8. Advantages/Disadvantages • Electromagnetic Relays (EMRs) • Simplicity • Not expensive • Mechanical Wear • Solid-state Relays (SSRs) • No Mechanical movements • Faster than EMR • No sparking between contacts • Microprocessor-based Relay • Much higher precision and more reliable and durable. • Improve the reliability and power quality of electrical power systems before, during and after faults occur. • Capable of both digital and analog I/O. • Higher cost

9. Why A System Needs Protection? • There is no ‘fault free’ system. • It is neither practical nor economical to build a ‘fault free’ system. • Electrical system shall tolerate certain degree of faults. • Usually faults are caused by breakdown of insulation due to various reasons: system aging, lighting, etc.

10. Electrical Faults • majority are phase-to-ground faults • phase-to-phase • phase-phase-phase • double-phase-to-ground

11. Protective Devices Comparison

12. Protective Devices Comparison Circuit Breakers V.S. Relays • Relays are like human brain; circuit breakers are like human muscle. • Relays ‘make decisions’ based on settings. • Relays send signals to circuit breakers. Based the sending signals circuit breakers will open/close.

13. Transformer Protection • Gas and Temperature Monitoring • Differential and Ground Fault Protection

14. Transformer Protection Gas Monitoring Relays: • These relays will sense any amount of gas inside the transformer. A tiny little amount of gas will cause transformer explosion. Temperature Monitoring Relays: • These relays are used to monitor the winding temperature of the transformer and prevent overheating.

15. Transformer ProtectionGround Fault • For a wye connection, ground fault can be detected from the grounded neutral wire.

16. Transformer ProtectionGround Fault and Differential Relay

17. Conclusion • Relays control output circuits of a much higher power. • Safety is increased • Protective relays are essential for keeping faults in the system isolated and keep equipment from being damaged.

18. Reference: • IEEE Red Book (IEEERecommended Practice for Electric Power Distribution for Industrial Plants) • Principles of power system by V.K Mehta