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POWER ELECTRONICS INTRODUCTION TO SCR GWCET, NGP

POWER ELECTRONICS INTRODUCTION TO SCR GWCET, NGP. SCR / Thyristor. Circuit Symbol and Terminal Identification. SCR / Thyristor. Anode and Cathode terminals as conventional pn junction diode Gate terminal for a controlling input signal. SCR/ Thyristor.

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POWER ELECTRONICS INTRODUCTION TO SCR GWCET, NGP

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  1. POWER ELECTRONICSINTRODUCTION TO SCRGWCET, NGP

  2. SCR / Thyristor • Circuit Symbol and Terminal Identification

  3. SCR / Thyristor • Anode and Cathode terminals as conventional pn junction diode • Gate terminal for a controlling input signal

  4. SCR/ Thyristor • An SCR (Thyristor) is a “controlled” rectifier (diode) • Control the conduction under forward bias by applying a current into the Gate terminal • Under reverse bias, looks like conventional pn junction diode

  5. SCR / Thyristor Anode • 4-layer (pnpn) device • Anode, Cathode as for a conventional pn junction diode • Cathode Gate brought out for controlling input P N Gate P N Cathode

  6. Equivalent Circuit ANODE P N N GATE P P N CATHODE

  7. Apply Biasing With the Gate terminal OPEN, both transistors are OFF. As the applied voltage increases, there will be a “breakdown” that causes both transistors to conduct (saturate) making IF > 0 and VAK = 0. VBreakdown = VBR(F) IF IC2=IB1 IC1 = IB2 IF

  8. Volt-Ampere Characteristic IF Holding Current IH VBR(F) VAK Breakdown Voltage

  9. Apply a Gate Current For 0 < VAK < VBR(F), Turn Q2 ON by applying a current into the Gate This causes Q1 to turn ON, and eventually both transistors SATURATE VAK = VCEsat + VBEsat If the Gate pulse is removed, Q1 and Q2 still stay ON! IF IC2 = IB1 IB2 VG IF

  10. How do you turn it OFF? • Cause the forward current to fall below the value if the “holding” current, IH • Reverse bias the device

  11. SCR Application – Power Control When the voltage across the capacitor reaches the “trigger-point” voltage of the device, the SCR turns ON, current flows in the Load for the remainder of the positive half-cycle. Current flow stops when the applied voltage goes negative.

  12. Input / Output Voltages

  13. Look at the LOAD Current Conduction time  Conduction Angle = 180 -  “Firing” time  Firing Angle ()

  14. Average Load Current

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