SINGLE PHASE CURRENT SOURCE INVERTER (C.S.I)

Transcription

1 Power Electronics Laboratory SINGLE PHASE CURRENT SOURCE INVERTER (C.S.I) OBJECT: To study the gate firing pulses. To observe and measure the voltages across the Thyristors and across the Load for a current source Inverter (CSI). To study the effect of the isolating diodes. To study the effect of the commutating inductance L. Study of a voltage source inverter (V.S.I). APPARATUS: 1. Experimental setup. 2. D.C regulated Power supply. 3. Oscilloscope. 4. Volt meter MC - 60V, MC Ammeter 0-3 Amps., Volt meter MI 60V, MI Ammeter 0 3 Amps. 5. A single phase variac or a variable inductance, 50Ω rheostat. Study of gate firing pulses. PROCEDURE: 1. Switch on power to the trigger circuit only. / 2. Clip on ground leads of probes to cathodes of Th 1 and Th 1 Live leads are to be connected to the respective gates. Observe the details of the firing pulses. / 3. Shift probe s from Th1 to Th2. Observe and measure the details of the pulse and their relative timings. / 4. Repeat (3) with Th 1 and Th 2. Switch the firing pulses to all the SCRs. Indicating their relative timings. Remove all probes. Observation of load and thyristor voltages (for a Cuircuit Source Inverter (C.S.I) 1. Connect a resistive load (50Ω, 4.1 Amp.) on the load. Switch on trigger circuit. Next switch on DC supply to power circuit (about 30V). (If the circuit performs properly a low buzz will be heard from the DC line chowk). 2. Clip ground lead of oscilloscope to X and the two line leads to Y and Z. Trace *1 gives load voltage and trace *2 the voltage across the Thyristor Th Switch both the waveform in details. 4. Adjust oscilloscope concentrate on the turn off time offered by the circuit. Th 1 (mainly adjust time base and triggering of oscilloscope).

2 5. Vary load resistance and measure input current, load current, input voltage output dv voltage and turn off time ' t q 's ' and of reapplied forward voltage. dt 6. Repeat B1 and B5 with an inductance in series with the load. Study of effect of Isolating diodes 1. Connect the isolating diodes as shown in fig Connect a resistive load (50Ω) and repeat B5. Observe also the voltage across the commutation Capacitor C1 and C2. Compare t of B-5 & C-2 the equal value of DC supply voltage and load resistance. 3. Repeat B-6. To study the off set of the commutation inductance 1. Connect a variable inductance L in series with the DC. Supply voltage, 0.1 ohm shunt is connected in series. Connect the Power circuit as in Fig. 1. dv 2. With load resistance and DC supply voltage kept constant observe t q and for dt dv various values of the inductance. Tabulate t q Vs. (Ground leads of dt oscilloscope probes are connected to Z and Live1 to P and Live2 to X to simultaneously observe the two quantities). Study of a Voltage source Inverter (VSI) 1. Connect up power circuit as per fig. 3. The load is the 50Ω resistance. 2. Observe voltage waveform across the capacitors, the load resistance and the thyristor. Note dv/dt of reapplied forward voltage. 3. Measure di/dt through any of the thyristors by connecting the 0.1 ohm in series with it and observing voltage waveform across it. Questions: 1. Why do the firing pulse at the gate of the thyristor change their shape and amplitude when the thyristor conducts? 2. Why does the load voltage increase when the load is reduced? 3. What is the relationship between the triggering period T and the R-C time constant it the maximum voltage across the capacitor (C.S.I.) is twice the supply voltage? di dv 4. Compare the, ratings of the thyristors in similarly rated C.S.I. and V.S.I. dt dt

3 Experiment No.12: Study Of Single Phase ASCI Current Source Inverter Fig.1: Suppose initially load current was flowing through Th2, D2, D2 and Th2.i.e. Here we have assumed v L is remaining constant at v L0 in the commutation period. As the load is of lagging power factor v L0 is negative. Now Th1 and Th1 are triggered. For making those on C1 and C2 should have the polarity shown below. Fig.2: As soon as Th1 and Th1 are on negative voltage will come across Th2 and Th2. So these will stop conducting.

4 Mode I Fig.3: Current will follow this path until D1 and D1 are forward biased. Capacitor voltage will decrease linearly as discharge current is constant. Here as and as it was conducting. When then all for diodes will start conducting. Mode II Fig.4:

5 Here C1 and C2 are connected in parallel fashion. Hence ; and ; as C1=C2.Now, From these two equations we get, By solving this we have, When current starts flowing through Th1, D1, D1 and Th1.Capacitor voltage remains fixed at that value. Fig.5:

6 Resistive load: Fig.6: 1. Connect the circuit as shown above. 2. Check the current waveforms through the load and C1 and voltage waveform across C1. Study the waveforms during commutation period. Here mode I is absent. 3. During commutation period: Fig.7:

7 Here, From these two equations we get, By solving this we get, Fig.8:

8 R-L load: 1. Connect inductance in series with the R load. 2. Check the waveforms stated above. Commutation time will increase in this case. Mode I Fig.9: When Mode II Fig.10: then four diodes will start conducting. Here,

9

10

11