RU136265U1 - SINGLE-PHASE-THREE-PHASE TRANSISTOR REVERSE SWITCH LED BY A SINGLE-PHASE NETWORK - Google Patents

Abstract

A single-phase-three-phase transistor reversing switch, driven by a single-phase network, equipped with two semiconductor switches, which are two transistors that connect the windings of a three-phase asynchronous motor to a single-phase AC mains, and the beginning of the first winding of a three-phase asynchronous motor is connected to the phase, and its end is to zero the single-phase AC mains, the emitters of the first and second transistors are connected to the phase of the single-phase AC mains, and the collector The first and second transistors are connected to the second and third windings of a three-phase induction motor, respectively, characterized in that the collector of the first transistor is connected to the beginning of the second winding of the three-phase asynchronous motor, and the collector of the second transistor is connected to the beginning of the third winding of the three-phase asynchronous motor, while the ends of the three windings three-phase induction motor connected to a common zero point, which is connected to zero single-phase AC power supply.

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 induction 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 / AI Voldek -. L .: Energy, 1974. - S. 612, Figure 30-7)..

The main disadvantages 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 paper capacitors of large capacity, as a result of which the motor torque is usually reduced to three times, the motor power drops to 50% of the nominal.

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 semiconductor switches connecting the windings of a three-phase asynchronous motor to a single-phase AC mains. 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 mains. The beginning of the second and third windings of a three-phase asynchronous motor are connected to zero single-phase AC mains. The first semiconductor switch is connected to the phase of the single-phase AC mains and the end of the second winding of the three-phase induction motor. The second semiconductor switch is connected to the phase of the single-phase AC network and to the end of the third winding of the three-phase induction motor. Two transistors are used as semiconductor switches. In this case, the emitters of the first and second transistors are connected to the phase of a single-phase AC mains, and the collectors of the first and second transistors are connected to the ends of the second and third windings of a three-phase asynchronous motor, respectively (patent RU 109356, IPC Н02Р 27/16 (2006.01).

The main disadvantages of the described single-phase-three-phase transistor reversing switch is a narrow scope due to the creation of an elliptical electromagnetic rotating field of the stator, which provides a low value of the moment on the motor shaft, and due to the possibility of the device and the motor operating at only one speed at a frequency of a single-phase AC network of 50 Hz due to the inclusion circuit of the windings.

The proposed utility model solves the problem of expanding the scope of use of the device in connection with the creation of a circular rotating magnetic flux of the stator field in comparison with the creation of an elliptical electromagnetic rotating field of the stator in the device selected as a prototype, which provides a higher value of the moment on the motor shaft and improved energy characteristics, and in connection with ensuring the operation of the device and the engine at different speeds at a frequency of a single-phase AC network of 50 Hz, due to Foot proposed scheme incorporating windings.

To solve this problem, in a single-phase-three-phase transistor reversing switch, driven by a single-phase network, equipped with two semiconductor switches, which are two transistors connecting the windings of a three-phase induction motor to a single-phase AC mains, and the beginning of the first winding of a three-phase asynchronous motor is connected to the phase , and its end - to zero the single-phase AC mains, the emitters of the first and second transistors are connected to the phase of the single-phase power AC networks, and the collectors of the first and second transistors are connected to the second and third windings of a three-phase asynchronous motor, respectively, according to a useful model, the collector of the first transistor is connected to the beginning of the second winding of a three-phase asynchronous motor, and the collector of the second transistor is connected to the beginning of the third winding of a three-phase asynchronous motor. At the same time, the ends of the three windings of a three-phase asynchronous motor are connected to a common zero point, which is connected to zero of a single-phase AC mains.

The proposed utility model is illustrated by drawings, where in FIG. 1 shows a circuit diagram of a single-phase-three-phase transistor reverse switch driven by a single-phase network; in FIG. 2 is a vector diagram of a circular rotating field of a motor stator, which consists of six fixed positions of the magnetic flux; in FIG. 3-directions of the magnetic flux and current flowing through the stator windings of the motor in accordance with the vector diagram depicted in FIG. 2; in FIG. 4 - phase-by-phase voltage variation in the stator windings of the motor in accordance with the vector diagram depicted in FIG. 2; in FIG. 5 is a vector diagram of a circular rotating field of an engine stator, which consists of six fixed positions of the magnetic flux in the reverse direction of rotation of the engine; in FIG. 6 shows the directions of the magnetic flux and the current flowing through the stator windings of the motor in accordance with the vector diagram depicted in FIG. 5; in FIG. 7 - phase-by-phase voltage variation in the stator windings of the motor in accordance with the vector diagram depicted in FIG. 5.

In addition, the drawings show the following:

- Φ is the phase;

- 0 - zero;

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

- VT1 and VT2 are transistors.

- 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 marked with Roman numerals - the direction of the magnetic flux vector of the circular rotating field of the motor stator;

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

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

t1-t5 are the times of switching transistors.

The single-phase-three-phase transistor reversing switch, driven by a single-phase network, is equipped with two semiconductor switches, which are used as two transistors that connect the windings of a three-phase asynchronous motor to a single-phase AC mains.

The emitter of the first transistor 1 (VT1) is connected to the phase of a single-phase AC mains, the collector of the first transistor 1 (VT1) is connected to the beginning 2 (C2) of the second winding of a three-phase asynchronous motor. The emitter of the second transistor 3 (VT2) is connected to the phase of the single-phase AC mains, the collector of the second transistor 3 (VT2) is connected to the beginning 4 (C3) of the third winding of the three-phase asynchronous motor. The beginning of the first winding 5 (C1) of a three-phase asynchronous motor is connected to the phase, and its end 6 (C4) is connected to zero of the single-phase AC mains. The end 6 (C4) of the first winding of a three-phase induction motor, the end 7 (CS) of the second winding of a three-phase induction motor and the end 8 (C6) of the third winding of a three-phase asynchronous motor are connected to a common zero point 9, which is connected to zero single-phase AC mains.

The operation of a single-phase-three-phase transistor reversing switch, driven by a single-phase network, is as follows. A single-phase alternating voltage is supplied to the stator windings of a three-phase asynchronous motor by switching the corresponding semiconductor switches, which provide a rotating magnetic field of the stator. In order 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 FIG. 2, in the sequence I-II-III-IV-V-VI, it is necessary to apply a control voltage to the base of transistors 1 (VT1) and 3 (VT2) in the following sequence:

- at the initial moment of time, a current begins to flow along the first winding of a three-phase asynchronous motor, and an unlocking control voltage is supplied to the base VT2 - I - fixed position of the stator field magnetic flux vector;

- at time t1, the current continues to flow along the first winding of the three-phase asynchronous motor, and the unlocking control voltage is removed from the base of the transistor VT2 - II — the fixed position of the stator field magnetic flux vector;

- at time t2, current flows through the first winding of a three-phase asynchronous motor, and an unlocking control voltage is applied to the base VT1 - III - a fixed position of the stator field magnetic flux vector;

- at time t3, current begins to flow in the opposite direction along the first winding of a three-phase asynchronous motor, the unlocking control voltage is removed from the base of transistor VT1 and the unlocking control voltage is applied to base VT2 - IV - a fixed position of the stator field magnetic flux vector;

- at time t4, current continues to flow in the opposite direction along the first winding of a three-phase asynchronous motor and the unlocking control voltage is removed from the base of transistor VT2 - V is the fixed position of the stator field magnetic flux vector;

- at time t5, current flows in the opposite direction along the first winding of a three-phase asynchronous motor, and an unlocking control voltage is applied to the base VT1 - VI - a fixed position of the stator field magnetic flux vector.

In order to ensure rotation of the magnetic flux vector of the circular rotating stator field in the opposite direction (motor reverse) in accordance with the vector diagram shown in FIG. 5, in the sequence III-II-I-VI-V-IV, it is necessary to apply a control voltage to the base of transistors 1 (VT1) and 3 (VT2) in the following sequence:

- at the initial moment of time, a current begins to flow along the first winding of a three-phase asynchronous motor, and an unlocking control voltage is supplied to the base VT1 - III - a fixed position of the stator field magnetic flux vector;

- at time t1, current continues to flow along the first winding of a three-phase asynchronous motor, and the unlocking control voltage is removed from the base VT1 - II — the fixed position of the stator field magnetic flux vector;

- at time t2, current flows through the first winding of a three-phase asynchronous motor, and an unlocking control voltage is supplied to the base VT2 - I - fixed position of the stator field magnetic flux vector;

- at time t3, current begins to flow in the opposite direction along the first winding of a three-phase asynchronous motor, the unlocking control voltage is removed from the base VT2 and the unlocking control voltage is applied to the base VT1 - VI - fixed position of the stator field magnetic flux vector;

- at time t4, current continues to flow in the opposite direction along the first winding of a three-phase asynchronous motor, and the unlocking control voltage is removed from the base VT1 - V is the fixed position of the stator field magnetic flux vector;

- at time t5, current flows in the opposite direction along the first winding of a three-phase asynchronous motor and an unlocking control voltage is applied to base VT2 - IV, the fixed position of the stator field magnetic flux vector.

Thus, the scope of use of the device is expanded in connection with the creation of a circular rotating magnetic flux of the stator field, which provides a higher value of the torque on the motor shaft and improved energy characteristics, and in connection with ensuring the operation of the device and engine at different speeds at a frequency of a single-phase alternating network current of 50 Hz, due to the proposed circuit for switching on the windings.

Claims (1)

A single-phase-three-phase transistor reversing switch, driven by a single-phase network, equipped with two semiconductor switches, which are two transistors that connect the windings of a three-phase asynchronous motor to a single-phase AC mains, and the beginning of the first winding of a three-phase asynchronous motor is connected to the phase, and its end is to zero the single-phase AC mains, the emitters of the first and second transistors are connected to the phase of the single-phase AC mains, and the collector The first and second transistors are connected to the second and third windings of a three-phase induction motor, respectively, characterized in that the collector of the first transistor is connected to the beginning of the second winding of the three-phase asynchronous motor, and the collector of the second transistor is connected to the beginning of the third winding of the three-phase asynchronous motor, while the ends of the three windings three-phase induction motor connected to a common zero point, which is connected to zero single-phase AC power supply.

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