RU2637111C1 - Device for powering synchronous hysteresis motor with amplitude-phase over-excitation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device contains an inverter, a master generator, a frequency divider with a pulse distributor. A synchronous hysteresis motor is connected to the inverter via a filter compensating device based on the LC-filter. The over-excitation control pulse is supplied to the control input of the inverter output voltage and to the input of the frequency control assembly of the master generator, to the other input of which the power voltage of the synchronous hysteresis motor is supplied. The output of the mentioned assembly is connected to the frequency control input of the master generator, whose output is connected is connected to the control input of the power inverter switches via the frequency divider with the pulse distributor.

EFFECT: reduction of installed power, level of electromagnetic interference and simplification.

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Description

The claimed invention relates to electrical engineering, namely to electric drives with synchronous hysteresis motors (SRS).

High energy characteristics of the SRS can be obtained only by using the over-excitation mode, which means that the magnetization of the material of the rotor drive disk in the synchronous operation of the SRS increases further, and then the supply voltage of the SRS decreases from the nominal value to the value at which the SRS works with the necessary margin by tipping power (out of synchronism).

Currently, there are several ways to overexcite SRS:

- a temporary increase in the supply voltage of the SRS with its subsequent decrease to a nominal level or lower (Delektorsky B.A., Tarasov V.N., “Controlled hysteresis drive.” M .: Energoatomizdat, 1983) [1];

- a temporary increase in the supply voltage of the SRS with the manipulation of the phase of this voltage ("Method of overexcitation of synchronous hysteresis motors", USSR author's certificate, No. 674181, IPC Н02Р 7/44, priority date 11/29/1971) [2];

- temporary disconnection of SRS from an alternating power source and its connection to a constant voltage source (“Method for overexcitation of a hysteresis electric motor”, USSR author's certificate No. 577632, IPC Н02Р 1/30, priority date 02.07.1971) [3];

- the imposition of voltage pulses in a certain phase on the SRS supply voltage (“Device for pulsed overexcitation of a hysteresis electric motor”, USSR author's certificate No. 455429, IPC Н02К 19/08, Н02Р 7/36, priority date 03/31/1972) [4].

The above methods have the following disadvantages:

- an increase in the supply voltage or the imposition of pulses on the supply voltage is possible not in all SRS power sources;

- the imposition of voltage pulses on the supply voltage requires improved quality of the electrical insulation of the stator windings of the SRS, and the edges of the voltage pulses cause degradation of the insulation;

- violation of the symmetry of the supply voltage of the SRS (the appearance of pulses in the supply voltage of the SRS, disconnection of one or several phases, a rapid change in the phase of the supply voltage of the SRS causes an impact on the rotor, which negatively affects the SRS resource, especially considering that the rotors of the SRS in ultra-fast drives work on tensile strength).

Closest to the claimed technical solution is the device described in RF patent No. 2375813 "Method for two-zone amplitude-phase overexcitation of synchronous-hysteretic electric motors" (IPC Н02Р 21/05, НОР 6/00, priority date 04/02/2008) [5] .

In this device for supplying an SRS containing a rectifier, a controlled volt-additive unit, a pulse-width modulated voltage inverter, a master oscillator, a frequency divider, a phase regulator, a pulse distributor, the over-excitation mode is created for a short time (within 3-5 periods of the inverter output voltage ) increasing and then lowering the voltage supplied to the SRS. Simultaneously with increasing and decreasing this voltage, the phase of the inverter output voltage changes.

With increasing inverter output voltage, the phase regulator rotates the phase of this voltage by an angle of 15-20 g. email against the direction of rotation of the rotor of the SRS, and when the voltage is reduced, the phase of the voltage is rotated by the same angle in the direction of rotation of the rotor of the SRS. The rotation of the inverter output voltage vector during overexcitation reduces the oscillations of the SRS rotor and further increases the magnetization level of the material of the drive disk of the SRS rotor. The increase in the output voltage of the inverter during overexcitation is achieved by turning on the controlled volt-additive block in series with the output voltage of the rectifier.

The disadvantages of this device for supplying SRS with amplitude-phase overexcitation include the increased number of power elements that make up the controlled volt-additive block, the increased installed inverter power, and the increased level of electromagnetic interference generated when the volt-additive block is turned on and off. In addition, the phase inverter voltage pulse-width modulation has a rather complicated scheme.

The objectives of the claimed invention are to simplify the device, reducing the installed power of the device, reducing the level of electromagnetic interference.

These tasks are solved due to the fact that in the inventive device for supplying an SRS with amplitude-phase overexcitation, including an inverter, a master oscillator, a frequency divider with a pulse distributor, the SRS is connected to the inverter through a filter compensating device based on an LC filter, and an overexcitation control pulse is supplied to the input of the inverter output voltage control and to the input of the frequency control unit of the master oscillator. The voltage of the synchronous hysteresis motor is supplied to the other input of the frequency control unit of the master oscillator, the output of this node is connected to the frequency control input of the master oscillator, the output of which is connected to the control input of the inverter's power keys via a frequency divider with a pulse distributor.

The inverter output voltage using pulse width modulation has a high level of higher harmonics, which heat the SRS and reduce the torque. To reduce the level of higher harmonics to an acceptable value, the SRS is connected to the inverter through a filter compensating device based on an LC filter. In addition, the filter compensating device is designed to increase the Cosφ load to values close to unity.

The invention is illustrated in the drawing, which shows a structural diagram of the inventive device for supplying SRS with amplitude-phase overexcitation.

The inventive device for supplying SRS with amplitude-phase overexcitation contains an inverter (1) connected to it through a filter compensating device based on an LC filter (2) SRS (3). An overexcitation control pulse is supplied to the inverter output voltage control input (1) and to the input of the frequency control unit of the master oscillator (4), the other input of which is supplied with the SRS supply voltage (3), the output of this node is connected to the frequency control input of the master generator (5) the output of which is connected through a frequency divider with a pulse distributor (6) to the inverter power switch control input (1).

The inventive device for supplying SRS with amplitude-phase overexcitation works as follows. When an overexcitation control pulse is applied to the inverter output voltage control input (1), its output voltage together with the SRS supply voltage (3) will begin to increase to the maximum value. When the supply voltage of the SRS (3) reaches the lower threshold of operation of the frequency control unit of the master oscillator (4), the frequency of the master oscillator (5) decreases by a predetermined amount, which will lead to a change in the phase of the inverter output voltage (1) so that the angle of the magnetic field lag rotor from the magnetic field of the stator (θ) SRS (3) will begin to decrease. As a result of this, the power consumed by the SRS (3) will decrease, the transmission coefficient of the filter compensating device (2) will begin to increase, the voltage across the stator windings of the SRS (3) will increase, which will lead to additional magnetization of the material of the drive disk of the SRS rotor (3). When the supply voltage of the SRS (3) reaches the level of the upper threshold of operation of the frequency control unit of the master oscillator (4), the frequency of the master oscillator (5) increases to the initial value, and the angle θ begins to increase to the value at which the electromagnetic moment of the SRS (3) becomes equal to the moment of resistance on its shaft.

To reduce the oscillations of the rotor of the SRS (3), the rate of phase change and increase the supply voltage of the SRS (3) is chosen so that the voltage increases to a maximum value during a time equal to several hundred periods of supply voltage of the SRS (3), but is an order of magnitude less than the period of natural oscillations SRS rotor (3).

It is known [1] that, in order to reduce the oscillations of the SGD rotor (3), it is advisable to increase the voltage of the SRS (3) further by gradually reducing this voltage, therefore, the voltage reduction time is selected by an order of magnitude longer than the period of natural oscillations of the SGD rotor (3).

The rise time and the maximum value of the SRS supply voltage (3) during amplitude-phase overexcitation are determined by the duration of the overexcitation pulse supplied to the frequency control input of the master oscillator (5), the slope of the frequency control characteristic of this generator, and the LC filter parameters of the filter compensating device (2). It is not recommended to reduce the angle θ to zero, since the SRS will switch to the generator mode of operation and the capacitor self-excitation of the SRS will occur.

The inventive device for supplying SRS with amplitude-phase overexcitation has the following advantages compared to analogues and prototype:

- a simpler scheme;

- allows to reduce the installed power of the inverter;

- does not cause additional energy losses from the power source;

- creates a lower level of electromagnetic interference during overexcitation than existing devices.

Information sources

1. Delektorsky B.A., Tarasov V.N. Controlled hysteresis drive. M., Energoatomizdat, 1983, pp. 78-79.

2. USSR author's certificate No. 674181, IPC Н02Р 7/44, priority date 11/29/1971

3. USSR author's certificate No. 577632, IPC Н02Р 1/30, priority date 07/02/1971

4. USSR author's certificate No. 455429, Н02К 19/08, Н02Р 7/36, priority date 03/31/1972

5. RF patent No. 23758813, IPC Н02Р 21/05, НОР 6/00, priority date 04/02/2008

Claims (1)

A device for powering a synchronous hysteresis motor with amplitude-phase overexcitation, containing an inverter, a master oscillator, a frequency divider with a pulse distributor, characterized in that the synchronous hysteresis motor is connected to the inverter through an LC filter-based filter compensating device, and the overexcitation control pulse is fed to the input control the output voltage of the inverter and the input of the frequency control unit of the master oscillator, to the other input of which the supply voltage synchronous hysteresis motor, the output of this node is connected to the input of the frequency control of the master oscillator, the output of which through the frequency divider with the pulse distributor is connected to the control input of the inverter power keys.

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