RU127549U1 - SINGLE-PHASE-THREE-PHASE SEMICONDUCTOR SWITCH LED BY A SINGLE-PHASE AC NETWORK - Google Patents

Abstract

A single-phase-three-phase semiconductor switch, driven by a single-phase AC network, equipped with semiconductor switches connecting the windings of a three-phase asynchronous motor to a single-phase AC network, with the beginning of the first winding of a three-phase asynchronous motor connected to the phase, and its end to zero of the single-phase AC network, the beginning the second and third windings are connected to zero single-phase AC network, the first semiconductor switch based on a bipolar transistor is connected to the phase of a single-phase the alternating current network and the end of the second winding of a three-phase induction motor, and the second semiconductor switch is connected to the phase of the single-phase AC network and the end of the third winding of the three-phase induction motor, characterized in that two bipolar transistors and two diodes are used as the first semiconductor switch the collector of the first bipolar transistor is connected to the cathode of the first diode and to the phase of the single-phase AC network, the collector of the second bipolar transistor is connected to the cathode in of the second diode and with the end of the second winding of a three-phase asynchronous motor, the emitters of the first and second bipolar transistors are combined and connected to the anodes of the first and second diodes, two thyristors and two diodes are used as the second semiconductor switch, while the anode of the first thyristor is connected to the cathode of the third diode and with the phase of a single-phase AC network, the anode of the second thyristor is connected to the cathode of the fourth diode and to the end of the third winding of a three-phase asynchronous motor, the cathodes of the first and second thyristors are

Description

The proposed utility model relates to reversible semiconductor switches driven by a single-phase AC network, and can be used in an unregulated AC drive to power three-phase asynchronous motors from a single-phase network.

A device is known for supplying a three-phase asynchronous motor from a single-phase network using a capacitor shift in the stator circuit, supplying power from a single-phase network of a three-phase asynchronous motor with windings connected to a star, in which one winding of a three-phase asynchronous motor is connected to a single-phase network through a capacitor to obtain a rotating stator field , and the other two windings - directly to a single-phase network (Voldek A.I. Electrical machines. A textbook for students of higher technical educational institutions tions / A.I.Voldek -. L .: Energy, 1974. - S.612, ris.30-7).

The main disadvantage of the described device for supplying a three-phase asynchronous motor from a single-phase network using a capacitor shift in the stator circuit is the need to use large-capacity paper capacitors, as a result of which the motor torque usually decreases by a factor of three, and the motor power drops to 40% of the nominal value.

The closest to the proposed utility model in terms of technical nature and the achieved result (prototype) is a single-phase three-phase transistor reversing switch, driven by a single-phase network, containing two semiconductor switches that connect the windings of a three-phase asynchronous motor to a single-phase AC network. The beginning of the first winding of a three-phase asynchronous motor is connected to the phase, and its end to zero of the single-phase AC network. The beginning of the second winding and the third winding are connected to zero single-phase AC network. The first semiconductor switch is connected to the phase of the single-phase AC network and the end of the second winding of the three-phase asynchronous motor and the second semiconductor switch is connected to the phase of the single-phase AC network and the end of the third winding of the three-phase asynchronous motor. As semiconductor switches used bipolar transistors. In the first semiconductor key, the emitter of the first bipolar transistor is connected to the phase of a single-phase AC network, the collector of the first bipolar transistor is connected to the end of the second winding of a three-phase asynchronous motor. In the second semiconductor key, the emitter of the second bipolar transistor is connected to the phase of the single-phase AC network, the collector of the second bipolar transistor is connected to the end of the third winding of the three-phase asynchronous motor (patent RU 109356, Н02Р 27/16 (2006.01)).

The main disadvantages of the described single-phase-three-phase semiconductor switch, driven by a single-phase network, are low reliability due to increased heating due to the consumption of control current in the key mode due to the operation of bipolar transistors on alternating current, as well as the complexity of the control system due to the need to take into account the polarity of the voltage passing through transistor at every moment in time.

The proposed utility model solves the problem of increasing the reliability and simplifying the control system of a single-phase-three-phase semiconductor switch, driven by a single-phase AC network.

To solve this problem, in a single-phase-three-phase semiconductor switch, driven by a single-phase AC network, equipped with semiconductor switches that connect the windings of a three-phase asynchronous motor to a single-phase AC network, and the beginning of the first winding of a three-phase asynchronous motor is connected to the phase, and its end to zero single-phase AC network, the beginning of the second and third windings are connected to zero single-phase AC network, the first semiconductor switch based on a bipolar tr the nsistor is connected to the phase of the single-phase AC network and the end of the second winding of the three-phase asynchronous motor and the second semiconductor switch is connected to the phase of the single-phase AC network and the end of the third winding of the three-phase asynchronous motor, according to the utility model, two bipolar transistors and two diodes are used as the first semiconductor switch the collector of the first bipolar transistor is connected to the cathode of the first diode and to the phase of a single-phase AC network, the collector of the second bipole a transistor is connected to the cathode of the second diode and to the end of the second winding of a three-phase induction motor, the emitters of the first and second bipolar transistors are combined and connected to the anodes of the first and second diodes, two thyristors and two diodes are used as the second semiconductor switch, while the anode of the first thyristor is connected with the cathode of the third diode and with the phase of a single-phase AC network, the anode of the second thyristor is connected to the cathode of the fourth diode and with the end of the third winding of a three-phase induction motor, atody first and second thyristors are combined and connected to the anodes of the third and fourth diodes.

The increase in reliability and simplification of the control system for a single-phase-three-phase semiconductor switch, driven by a single-phase AC network, is due to the use of two bipolar transistors and two diodes as the first semiconductor switch, passing current in both directions, and two thyristors and two diodes as the second semiconductor switch without the need to take into account the polarity of the supply voltage applied to them.

The proposed utility model is illustrated by drawings, where Fig. 1 shows a circuit diagram of a single-phase-three-phase semiconductor switch driven by a single-phase AC network; figure 2 is a vector diagram of a circular rotating field of the stator of the engine, which consists of six fixed positions of the magnetic flux; figure 3 - the direction of the magnetic flux and the flowing current through the windings of the stator of the motor in accordance with the vector diagram shown in figure 2; figure 4 - phase-by-phase voltage change in the stator windings of the motor in accordance with the vector diagram shown in figure 2.

In addition, the drawings show the following:

- f - phase;

- 0 - zero;

- C1-C6 - conclusions of stator windings of a three-phase asynchronous motor;

- VT1-VT2 - bipolar transistors;

- V1-V2 - thyristors;

- VD1-VD4 - diodes;

- I, II, III, IV, V, VI - sequential fixed positions of the magnetic flux vector of the circular rotating field of the motor stator;

- straight lines with arrows - the direction of the magnetic flux vector of the circular rotating field of the stator of the motor;

- straight lines with arrows along the stator windings of the motor - the direction of magnetic flux and current in the stator windings;

- U network = f (t) - change in supply voltage in time;

- t0-t5 are the times of switching transistors.

A single-phase-three-phase semiconductor switch, driven by a single-phase AC network, is equipped with two semiconductor switches that connect the windings of a three-phase asynchronous motor to a single-phase AC network. The beginning of the first winding of a three-phase asynchronous motor is connected to the phase, and its end to zero of the single-phase AC network. The beginning of the second and third windings are connected to zero single-phase AC network. The first semiconductor switch, which uses two bipolar transistors and two diodes, is connected to the phase of a single-phase AC network and to the end of the second winding of a three-phase asynchronous motor. In the first semiconductor key, the collector of the first bipolar transistor is connected to the cathode of the first diode and to the phase of the single-phase AC network, the collector of the second bipolar transistor is connected to the cathode of the second diode and to the end of the second winding of the three-phase asynchronous motor, emitters of the first and second bipolar transistors are combined and connected to first and second diodes. The second semiconductor switch, which is used as two thyristors and two diodes, is connected to the phase of a single-phase AC network and to the end of the third winding of a three-phase asynchronous motor. In the second semiconductor key, the anode of the first thyristor is connected to the cathode of the third diode and to the phase of the single-phase AC network, the anode of the second thyristor is connected to the cathode of the fourth diode and to the end of the third winding of the three-phase induction motor, the cathodes of the first and second thyristors are combined and connected to the anodes of the third and fourth diodes.

An example of a single-phase-three-phase semiconductor switch, driven by a single-phase AC network.

In the first semiconductor key, the collector of the first bipolar transistor 1 (VT1) is connected to the cathode of the first diode 2 (VD1) and to the phase of the single-phase AC network, the collector of the second bipolar transistor 3 (VT2) is connected to the cathode of the second diode 4 (VD2) and to the end of the second windings 5 (C4) of a three-phase induction motor, emitters of the first bipolar transistor 1 (VT1) and the second bipolar transistor 3 (VT2) are combined and connected to the anodes of the first diode 2 (VD1) and the second diode 4 (VD2).

In the second semiconductor key, the anode of the first thyristor 6 (V1) is connected to the cathode of the third diode 7 (VD3) and to the phase of the single-phase AC network, the anode of the second thyristor 8 (V2) is connected to the cathode of the fourth diode 9 (VD4) and to the end of the third winding 10 (C6) a three-phase induction motor, the cathodes of the first thyristor 6 (V1) and the second thyristor 8 (V2) are combined and connected to the anodes of the third diode 7 (VD3) and the fourth diode 9 (VD4).

The beginning of the first winding 11 (C1) of a three-phase asynchronous motor is connected to the phase, and its end 12 (C2) is connected to zero of the single-phase AC network. The beginning of the second winding 13 (C3) and the third winding 14 (C5) are connected to zero single-phase AC network.

Thus, the first semiconductor switch is connected to the phase of the single-phase AC network and the end of the second winding 5 (C4) of the three-phase induction motor and the second semiconductor switch is connected to the phase of the single-phase AC network and the end of the third winding 10 (C4) of the three-phase asynchronous motor,

The operation of a single-phase-three-phase semiconductor switch, driven by a single-phase AC network, is as follows. Initially, no opening current is applied to the bases of transistors 1 (VT1) and 3 (VT2) and control electrodes of thyristors 6 (V1) and 8 (V2). Vector-algorithmic control is carried out by supplying current to the base of transistors 1 (VT1) and 3 (VT2) and control electrodes of thyristors 6 (V1) and 8 (V2) in a given sequence. To ensure rotation of the magnetic flux vector of the circular rotating field of the stator of the motor in accordance with the vector diagram shown in figure 2, in the sequence I-II-III-IV-V-VI, it is necessary to supply current to the base of transistors 1 (VT1) and 3 (VT2) and control electrodes of thyristors 6 (V1) and 8 (V2) in the following sequence:

- at the initial instant of time t0, when a positive half-wave of the supply voltage passes, a current is applied to the base of transistor 1 (VT1) - I fixed position of the stator field magnetic flux vector;

- at time t1, current is supplied to the thyristor 6 (V1) control electrode, transistor 1 (VT1) remains open - II fixed position of the stator field magnetic flux vector;

- at time t2, current is removed from the base of transistor 1 (VT1), thyristor 6 (V1) remains open - III fixed position of the stator field magnetic flux vector;

- at time t3, when a negative half-wave of voltage passes, thyristor 6 (V1) closes, current is supplied to the base of transistor 3 (VT2) - IV fixed position of the stator field magnetic flux vector;

- at time t4, current is supplied to the control electrode of thyristor 8 (V2), transistor 3 (VT2) remains open - V fixed position of the stator field magnetic flux vector;

- at time t5, current is removed from the base of transistor 3 (VT2), thyristor 8 (V2) remains open - VI fixed position vector of the magnetic flux of the stator field.

Starting from time t6, the sequence of current supply to the base of transistors 1 (VT1) and 3 (VT2) and control electrodes of thyristors 6 (V1) and 8 (V2) is repeated.

Thus, the proposed utility model has advantages over the known ones due to the increased reliability and simplified control system.

Claims (1)

A single-phase-three-phase semiconductor switch, driven by a single-phase AC network, equipped with semiconductor switches connecting the windings of a three-phase asynchronous motor to a single-phase AC network, with the beginning of the first winding of a three-phase asynchronous motor connected to the phase, and its end to zero of the single-phase AC network, the beginning the second and third windings are connected to zero single-phase AC network, the first semiconductor switch based on a bipolar transistor is connected to the phase of a single-phase the alternating current network and the end of the second winding of a three-phase induction motor, and the second semiconductor switch is connected to the phase of the single-phase AC network and the end of the third winding of the three-phase induction motor, characterized in that two bipolar transistors and two diodes are used as the first semiconductor switch the collector of the first bipolar transistor is connected to the cathode of the first diode and to the phase of the single-phase AC network, the collector of the second bipolar transistor is connected to the cathode in of the second diode and with the end of the second winding of a three-phase asynchronous motor, the emitters of the first and second bipolar transistors are combined and connected to the anodes of the first and second diodes, two thyristors and two diodes are used as the second semiconductor switch, while the anode of the first thyristor is connected to the cathode of the third diode and with the phase of a single-phase AC network, the anode of the second thyristor is connected to the cathode of the fourth diode and to the end of the third winding of the three-phase induction motor, the cathodes of the first and second thyristors are united and connected to the anodes of the third and fourth diodes.

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