SU773901A1 - Method of starting parallel current inverter - Google Patents

Description

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The invention relates to a converter technique, and specifically to methods for starting parallel current inverters.

A known method of starting a parallel inverter consists in that they first unlock the two inverter valves, thereby setting the current in the choke and the voltage on the capacitor, and then switching the thyristors in the usual order of operation.

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The closest technical

SUMMARY OF THE INVENTION An object of the present invention is a method for starting a parallel current invertor, consisting in supplying control pulses to thyristors with a reduced frequency of 2.

The disadvantage of this start-up method is the low reliability, due to the dependence of the time provided by the power thyristors to restore their locking properties, on the load parameters.

The purpose of the invention is to increase reliability.

The goal is achieved by the fact that in the method of starting a parallel inverter current, which consists in feeding control inverter AC to the thyristors

pulses of a lower frequency, the current consumed from the power source and the load current are measured, they are compared and the indicated control pulses feed the thyristors to the inverter when these currents are equal.

Figure 1 shows the block diagram of the device; figure 2 - timing charts of the start process.

The device (inverter) contains a smoothing choke 1 and a current sensor 2 (shunt) in the DC circuit, power thyristors 3 and 4, a capacitor 5 and a load current sensor 6 (transformer) current. A load 7 is connected to the output pins of the inverter. The current sensors are connected to the inputs of the adder 8, the output of which, in turn, is connected to the input of the zero organ 9. The output of the null organ is connected to the master oscillator 10 and the amplifier of the driving pulses 11. The start of the inverter is as follows.

When the trigger pulses are initially applied to the thyristors 3 of the inverter, a circuit is formed for the flow of the input current, the capacitor current and the load current, and the shape of the capacitor current curve is nearly sinusoidal. The capacitor voltage reaches a maximum when the capacitor current is zero. At this moment, the input current and the load fOK are equal in magnitude. The moment of equality of the locks is fixed by the adder 8 and the null-organ 9, and the next control impulse is outputted, which through the amplifier 11 enters the control of the thyristor 4 transitions. Next, the processes are repeated until the inverter reaches the mode. The moment of formation of the next pulse can be determined directly by the fact that the capacitor current curve passes through zero.

Thus, with this start-up method, at the time of switching thyristors, the voltage on the capacitor is as high as possible, which allows to obtain the maximum time allowed by the thyristors to restore their locking properties during the entire start-up process, which makes it possible to increase the reliability of starting the inverter.

Claims (2)

1. Tolstov Yu.G. Autonomous current inverters. M., Energie, 1978, p.184. 2. Kovalev F.I. and others. Stabilized 2Q autonomous inverters with sinusoidal output voltage. M., Energie, 1972, p.81.