RU121670U1 - SHORT-CLOSED ROTOR ASYNCHRONOUS ELECTRIC MOTORS - Google Patents

Abstract

A control device for asynchronous electric motors with a squirrel-cage rotor, containing a DC power supply unit, the input of which is connected to an AC source, a DC power filter unit, an autonomous voltage inverter unit, a low-current DC power supply unit, a unit for generating control multiphase sinusoidal signals of variable frequency and a matching unit, wherein the first output of the DC power supply unit is connected to the input of the DC power filter unit, the output of which is connected to the first input of the autonomous voltage inverter unit, the second output of the DC power supply unit is connected to the first input of the low-current power supply unit direct current, the output of which is connected to the input of the block for generating control polyphase sinusoidal signals of variable frequency and the first input of the matching block, the second input of which is connected to the first output of the block generating control polyphase sinusoidal signals of variable frequency, the second output of which is connected to the second input of the low-current DC power supply unit, the output of the matching unit is connected to the input of the autonomous voltage inverter unit, the DC power supply unit is configured to convert AC to DC without regulation of the value DC voltage at its output, the unit of a low-current DC power supply is configured to regulate the output voltage depending on the frequency of the control

Description

The utility model relates to the field of variable frequency drives (CREP) and can be used in electric transport.

A control device for squirrel-cage asynchronous electric motors is known, in which the first input of the power rectifier unit, with an adjustable output voltage, is connected to an AC source, and the first output of the power rectifier unit is connected to the input of the filter unit, where the DC oscillations are smoothed, the output of which is connected to the first input of the power block of an autonomous voltage inverter (AIN) - to the collectors of power transistors AIN, the output of the AIN block is connected to the input of the asynchronous electric a squirrel-cage rotor (ADC), into which the multipurpose sinusoidal signals of variable frequency amplified by the AIN block enter, varying over a wide range, the second output of the power rectifier block is connected to the input of the block of a low-current DC power supply with an unregulated output voltage supplying the block forming the control multiphase sinusoidal signals of variable frequency, the input of which is connected to the output of the low-current power supply unit, the first output of the unit forming control phase sinusoidal signals of variable frequency, connected to the second input of the AIN block, where these signals are amplified and fed to the ADKR block as controlling the rotational speed of the ADKR rotor, the second output of the block forming the controlling multiphase sinusoidal signals of variable frequency is connected to the second input of the power rectifier block, where the output power voltage of the power rectifier unit is regulated depending on the frequency generated by the unit forming the control multiphase sinusoidal signals of changes frequency, the lower the frequency, the lower the output voltage of the power rectifier unit, and vice versa, the higher the frequency of the unit generating control multiphase sinusoidal signals of variable frequency, the higher the output voltage of the power rectifier unit. At the rated frequency, the voltage of the power rectifier unit is equal to the nominal U _H (see Means for optimizing power consumption. AV Klevtsov, Solon-press, 2004. Figures 3.7, 3.13, 3.20, 3.21, 4.7, 4.8, 4.9, 4.11) .

However, this motor control device has several disadvantages, which are as follows.

In electric railway transport, as well as in a whole series of industrial production, especially heavy industry, several powerful electric motors operate in parallel in synchronous mode, for example, in electric locomotives, up to eight electric motors operate in parallel with more than one MW each, therefore it is necessary to ensure synchronous operation of all engines with single management.

A power supply unit that provides powerful current transistors with constant current AIN is developed with an output voltage that is regulated depending on the frequency of the control signals of the unit, which generates control multiphase sinusoidal signals of variable frequency, which greatly complicates the power supply itself, and also leads to additional losses of electric energy in him.

The closest technical solution is a squirrel-cage induction motor control device according to the RF patent for invention No. 2441775, IPC B60L 9/16, B60L 15/20, Н02Р 27/00, 02/10/2012, containing a DC power supply unit, the input of which connected to an alternating current source, a DC power filter block, N blocks of autonomous voltage inverters, a low-current DC power supply block and a block for generating control multiphase sinusoidal signals of variable frequency, In this case, the first output of the DC power supply unit is connected to the input of the DC power filter unit, the output of which is connected to the first input of each of the N blocks of autonomous voltage inverters, the output of which is connected to the input of the unit for generating control multiphase sinusoidal signals of variable frequency.

To ensure synchronous operation of parallel-running asynchronous motors with a squirrel-cage rotor, to reduce electrical energy losses in the control circuit, to reduce the overall dimensions of the electric motor control device, a matching unit is additionally introduced into it, while the first input of the matching unit is connected to the output of the low-current DC power supply unit, and the second input to the first output of the block forming control multiphase sinusoidal signals of variable frequency you, the output of the matching unit is connected at the same time to each input of the unit of an autonomous voltage inverter, the unit of a direct current power supply is made with the possibility of converting alternating current to direct without regulating the magnitude of the direct current voltage at its output, the low-current DC power supply unit is made with the possibility of regulating the output voltage depending on the frequency of the control multiphase sinusoidal signals of variable frequency, and its second input is connected to watts rum output control unit for generating multiphase variable frequency sinusoidal signals.

The main disadvantage of the known device is that each squirrel-cage induction motor is powered by one of the N blocks of autonomous voltage inverters, which complicates the control circuit and, accordingly, increases its cost.

The objective of the utility model is to simplify and reduce the cost of the control circuit, reduce the loss of electrical energy in the control circuit, reduce the overall dimensions of the motor control device while maintaining synchronous operation of the parallel-running motors,

The technical result is achieved by the fact that in the control device for asynchronous motors with a squirrel-cage rotor, containing a block of a direct current power source, the input of which is connected to an alternating current source, a block of a direct current power filter, a block of an autonomous voltage inverter, a block of a low-current direct current power source, generating control multiphase sinusoidal signals of variable frequency and a matching unit, while the first output of the power supply unit I have a DC current connected to the input of the DC power filter unit, the output of which is connected to the first input of the autonomous voltage inverter unit, the second output of the DC power supply unit is connected to the first input of the low-current DC power supply unit, the output of which is connected to the input of the control unit multiphase sinusoidal signals of variable frequency and the first input of the matching unit, the second input of which is connected to the first output of the control unit x multiphase sinusoidal signals of variable frequency, the second output of which is connected to the second input of the low-current DC power supply unit, the output of the matching unit is connected to the input of the autonomous voltage inverter unit, and the power supply unit of the direct current power supply is capable of converting alternating current to direct without regulating the magnitude DC voltage at its output, and the low-current DC power supply unit is configured to control the input voltage, depending on the frequency of the control multiphase sinusoidal signals of variable frequency, according to the proposed utility model, an additional unit for matching the output resistance of an autonomous voltage inverter unit with input resistances of asynchronous motors with a squirrel-cage rotor is additionally introduced, while the input of an additional input matching unit is connected to the output of an autonomous inverter unit voltage, and each output to the corresponding input of each asynchronous electric tor with a squirrel cage.

The essence of the utility model is illustrated by the drawing, which shows a block-functional diagram of the proposed device for controlling asynchronous motors with a squirrel-cage rotor.

The control device for asynchronous squirrel-cage rotor motors contains the following blocks:

1 - block power supply DC power with unregulated output voltage;

2 - power filter unit DC;

3 - block autonomous voltage inverter (AIN);

4 - asynchronous electric motor with squirrel-cage rotor;

5 - block low-current power source of direct current with adjustable output voltage;

6 - block generating control sinusoidal multiphase signals of variable frequency;

7 - block matching output block 6 with the input of block 3,

8 - an additionally introduced block matching output impedance of an autonomous voltage inverter unit with input resistances of squirrel-cage induction motors.

Block 1 of the power DC power supply with unregulated output voltage is connected by its input to an AC power source (not shown in the drawing). The first output of unit 1 is connected to the input of unit 2 of the DC power filter., The output of which is connected to the first input of unit 3 of the AIN. The second output of block 1 is connected to the first input of block 5 of a low-current DC power supply with a controlled output voltage depending on the frequency of the control multiphase sinusoidal signals generated by block 6. The first output of block 6 is connected to the second input of block 7 matching the output of block 6 with the input of block 3 AIN, by connecting the second input of block 3 to the output of block 7, and the second output of block 6 is connected to the second input of block 5 The output of block 5 is simultaneously connected to the inputs of blocks 6 and 7 and feeds them with direct current with a variable by the largest voltage.

The difference of the proposed control device N asynchronous motors with a squirrel-cage rotor is that it additionally includes a block 8 matching output impedance of unit 3 AIN with input resistances running in parallel, N asynchronous motors 4 with squirrel-cage rotor, while the input of the additionally entered matching unit 8 is connected to the output of the unit 3 AIN, and each its output to the corresponding input of each asynchronous electric motor 4 with a squirrel-cage rotor.

Thus, in the proposed device for controlling asynchronous motors with a squirrel-cage rotor, in comparison with the prototype, N electric motors are connected to one unit 3 AIN through an additionally introduced unit 8 for matching the output resistance of unit 3 AINs with input resistances of asynchronous motors 4 with a squirrel-cage rotor.

The operation of the control device of asynchronous motors with a squirrel-cage rotor is as follows.

After the unit 1 is turned on, the DC power supply is supplied, the alternating current in unit 1 is converted to unregulated high-voltage direct current. In block 2, DC ripple is smoothed out, in block 3 of the AIN control variable-frequency sinusoidal signals coming through block 7 from the output of block 6 are amplified and fed to the input of the additionally entered matching block 8. From the n outputs of block 8 - the matching block of the output resistance of the 3 AIN block with the input resistances of squirrel-cage induction motors 4 - phase voltages are applied to the stator windings of N squirrel-cage induction motors 4, i.e. control signals are fed to the bases of power transistors of unit 3 of the AIN, varying both in frequency and amplitude, and in accordance with the specified control signal, a high-voltage signal appears on the output t of unit 3 of the AIN, supplying unit 8 - matching unit for the output resistance of unit 3 of AIN with input resistances N of electric motors 4.

In block 5 of a low-current direct current source, alternating current is converted to direct current with a voltage regulated at the output of block 5 by controlling multiphase sinusoidal signals of variable frequency coming from the first output of block 6.

During the start-up of electric motors 4, the output voltage of block 5 of the low-current direct current power supply is reduced due to the low frequency generated by block 6, while the inputs (bases of power transistors) of block 3 of the AIN receive a reduced voltage and the transistors open by a small amount, limiting currents in the stator windings of electric motors 4. With an increase in the frequency of control signals generated by block 6, the output voltage of block 5, as well as matching block 7, increases, which opens up more power transistors unit 3 AIN. When forming the control frequency equal to the nominal ω _H , the output voltage of block 5 reaches the level U of the _SPS , at which the number of revolutions of the electric motors 4 also reaches the nominal frequency ω _ND , rated voltage, and other parameters. The procedure for reducing the speed of the electric motors 4 occurs in the reverse order.

The voltage regulation of block 5 - the block of a low-current DC power supply - depending on the frequency of the control signals from the output of block 6, regulates the output signals of the matching block 7 and thereby controls the degree of opening and closing of the power transistors of the AIN block 3, and, therefore, the level of supplied power , through block 8, to the stator windings of electric motors 4.

Thus, the proposed device allows from one block 3 AIN, through an additionally introduced matching block 8, to synchronously supply N parallel-acting asynchronous motors with a squirrel-cage rotor, which simplifies and cheapens the control circuit, reduces the loss of electrical energy in the control circuit, and reduces the overall dimensions of the device management.

Claims (1)

A squirrel-cage induction motor control device comprising a DC power supply unit, the input of which is connected to an AC source, a DC power filter unit, an autonomous voltage inverter unit, a low-current DC power supply unit, a unit for generating control multiphase sinusoidal signals of variable frequency and a matching unit, wherein the first output of the DC power supply unit is connected to the input of the si unit the main DC filter, the output of which is connected to the first input of the autonomous voltage inverter unit, the second output of the power supply unit of the DC power supply is connected to the first input of the low-current DC power supply unit, the output of which is connected to the input of the generating unit for generating multiphase sinusoidal signals of variable frequency and the first the input of the matching unit, the second input of which is connected to the first output of the unit for generating control multiphase sinusoidal AC signals frequency output, the second output of which is connected to the second input of the low-current DC power supply unit, the output of the matching unit is connected to the input of the autonomous voltage inverter unit, the DC power supply unit is capable of converting alternating current to direct without regulating the magnitude of the DC voltage to it output, the low-current DC power supply unit is configured to control the output voltage depending on the frequency x multiphase sinusoidal signals of variable frequency, characterized in that it additionally includes a unit for matching the output resistance of an autonomous voltage inverter unit with input resistances of asynchronous motors with a squirrel-cage rotor, while the input of an additional input matching unit is connected to the output of an autonomous voltage inverter unit, and each output - to the corresponding input of each squirrel-cage induction motor.