SU764095A1 - Device for controlling single-phase static converter - Google Patents

Description

thyristor assistance, which contains a ring; an interactive circuitry connected by ICO with the inputs of the main matching elements, a master oscillator and a current sensor connected to the inputs of the auxiliary match elements, a trigger whose input is connected to the output of the master oscillator, and an output to the inverter control unit, additional inputs elements of coincidence and two frequency dividers, with the inputs of two groups of basic elements of coincidence connected to the trigger outputs connected via the first frequency divider with ring scaling circuit, their outputs are with leads for connection to the control electrodes of the thyristors and with auxiliary elements of the match, the outputs of the additional elements of the match are connected respectively to the auxiliary elements of the match with the sequence number 2.3 ... 2i, and their inputs to the cells of the ring scaling circuit with the sequence number 1.2 ... (2i-l) and the second additional frequency divider connected to the master oscillator, while the current sensor is connected to the terminals for connection to the inverter power supply circuit.

FIG. 1 shows a diagram of the device; in fig. 2 - voltage diagrams on individual circuit elements.

The device for controlling a single-phase static converter contains a master oscillator 1, a trigger 2 with a divider 3 frequencies, auxiliary elements 4-15 matches; 16-27, the basic elements 28-39 ,. 40-5 times, ring scattering circuit 52-63 on cells, current sensor 64, additional elements 65-69, 70 74 coincidence, frequency divider 75, inverter control unit 76.

The power part of the converter contains an inverter 77, a cyclo-inverter 78-89 on thyristors connected to the secondary windings of the 90-95speed transistor “atopa”, and the load 96.

Outputs of the rear end of the Göner Torus 1 | forming uni-polar short pulses are connected to a subsequently connected trigger-2 and frequency divider 3 in all 11 with elements 4-15 and 16-27 bays, the outputs of which are connected to the control circuits of the cyclojvertor and their inputs to the corresponding signals. -39 and 40-51 matches, connected to a ring scatter circuit 52-63 on the cells and tfasifcM trigger outputs, and k. . additional elements 65-69, 7074 coincidence, the inputs of which are connected by the corresponding cells of the ring scaling circuit and the second frequency divider 75 additionally inputted to the generator, the inverter control unit 76 being connected to the trigger, and the current sensor 64 is connected to the power circuit inverter 77. A cycloconverter on thyristors 78-89 is connected to secondary windings m 90-95 s: a sludge transformer. ...

Claims (2)

Consider the operation of a device for controlling a single-phase static converter when operating at an actively inductive load. The master oscillator 1 generates unipolar signals 97 with a frequency equal to the operating frequency of the inverter (a higher frequency link. The duration of these pulses is chosen equal to the recovery time of the cycloconverter thyristors. On the falling edge of the signal 97, a trigger 2 is triggered, the output of which produces a square-shaped voltage, which is supplied to an inverter control unit 76. Inverter 77 forms a rectangular voltage 98 (Fig. 2). Simultaneously, a frequency divider 3 is connected to the output of trigger 2, the output of which is The signal is h times lower than the operating inverter 77 (in this case, the number of subintervals in the clock interval is 4.) The voltage 99 from the output of the divider 3 frequencies goes to an annular counting circuit with m cells (in the considered variant), which are formed at the output of rectangular signals of equal duration (at the output of the first cell 52 a signal of duration tg-t is formed, at the output of the second cell 53 - t j-tgiHa the output of the third cell 54 - tg-t, H, etc.). Further, these signals from the ring scaling circuit 1 and the signal from the trigger goes to the main elements 28-39, 4051 coincidence. From the outputs of which the signals 100-111 go to the control electrodes of the cycloconverter thyristors, respectively output, for example, 84 thyristor 84, etc.) In this circuit, each output voltage stage is formed by several pulses (four) due to cyclic connection of, for example, two identical windings 93 and 92, and the control unit generates the necessary signal events. The law of control ensures the efficiency of the converter to the load, in which the current lags behind the voltage of no more than one clock subinterval. To supply a load with a smaller power factor, it is necessary to form a certain sequence of additional control pulses (narrow 100: 111 in Fig. 2 with the duration of the pulses setting the generator pe). So by the time .. time C, the load passes through zero in the third output voltage 112 (FIG. 2), it is necessary to transfer current from valve 83 (although control is supplied to valve 82 but current flows through valve 83) to valve 85. This is achieved by supplying the control signal 107 to the specified valve at the moment redstavle ny in FIG. 2. Due to this, at the time of the pulse of the master oscillator, a blocking voltage is applied to the valve 83 and it turns off, and the load current goes to the thyristor 85. Now the next main control signal is applied at time t | will not lead to the formation of a short-circuited circuit, etc. The formation of narrow pulses (not all of the auxiliary elements 4-15 and 16-27 are matched, the inputs of which are associated with the main elements of the match, the master oscillator, which determines the duration of the additional pulses , a current sensor providing information about the magnitude of the phase shift between the load current and the voltage. The current sensor 64 is connected to the inverter power supply and generates a signal 113 at the output, the fronts of which are associated with the moment of current transition or voltage This output signal is easily realized due to the fact that in the inverter and rectifying modes the current in the power supply circuit changes its direction. Thus, at the output of the auxiliary elements of the coincidence, the signal appears when there is a signal from the current sensor generator and the main element of coincidence. At the time of the end of the clock interval, in addition, it is necessary to form additional signals to transfer the load current from the valves that form, for example, the first stage, voltage, to the valves no second stage of this tension. For this purpose, a frequency divider is introduced, at the output of which signals of a lower frequency, similar to the master oscillator, are generated and fed to additional matching elements 65-74. At the same time, another input of these coincidence elements is connected respectively to the cells of the ring scaling circuit with the serial number 1.2 .. (2i-1), and their outputs to the inputs of the auxiliary elements coincide with the serial number 2, ... 2 where 1 is the number of clock intervals in the half-period of the output voltage {in our case). Such a construction allows the formation of additional control pulses at the end of each clock interval. How . seen, for example, until time t; at the same time, control impulses are transmitted to thyristors 83 and 81. However, in this case, thyristor 81 is turned on, since its potential is higher than the potential of thyristor 8.3, and the load current goes into it, and a second output voltage level is formed on the load at a subsequent time point etc. Thus, the proposed device for controlling a static converter allows operating at any load regardless of the form of the inverter voltage, which will make it possible to effectively use such structures of power units applicants for generating voltage of any low frequency. Apparatus of the Invention A device for controlling a single-phase static converter with a multi-stage output voltage by switching secondary transformer windings using thyristors, comprising an annular scaling circuit connected to the inputs of the main coincidence elements, a driver and a current sensor connected to the inputs of the auxiliary coincidence elements the trigger, whose input is connected to the output of the master oscillator, and the output to the inverter control unit, is hindered by the fact that Ensuring the converter operates on a load with any power factor, it is equipped with additional matching elements and two frequency dividers, with the inputs of the main matching elements connected to the trigger outputs connected via the first frequency divider with a ring scaler, and their outputs . To the thyristor control electrodes and with matching elements, the outputs of additional elements of matching are connected respectively to the auxiliary elements of matching. With a sequence number of 2.3 ... 2 I, and their inputs .- to the outputs of a ring scaling circuit with pores d-. 1.2 ... () and the second additional frequency divider connected to the master oscillator j with the current sensor connected to the terminals for connection in the power circuit to the inverter power supply. Sources of information taken into account in the examination 1. USSR author's certificate in application No. 2525693 / 24-07, cl. H 02 R 13/18, 1978. 2. Authors certificate of the USSR 517133, cl. H 02 R 13/18, 1974.