RU2082277C1 - Device for control of two-phase induction motor in oscillation mode - Google Patents

Abstract

FIELD: electric drives in which executing member performs oscillating, vibrating and reciprocal movements. SUBSTANCE: oscillator in frequency converter is connected to frequency divider which provides both varied and constant division factor. This results in possibility to feed stator windings with alternating currents of different frequencies one of which is generated by multiplication of another one by constant factor. Stability of oscillations of executing member is determined by bit- length of counters and reaches 0.01%. EFFECT: increased precision of control. 2 dwg

Description

 The device relates to the field of electrical engineering, in particular to special electric drives where the executive body performs oscillatory, vibrational and reciprocating movements.

 A device [1] containing a two-phase motor with a stator and a rotor is known, the stator windings are connected to two alternating current sources of different frequencies. The rotor has two windings connected in parallel with the stator windings. However, the use of two power frequency converters (generators) complicates the device circuit. Using the voltage of the network as one of the generators is impossible, since the fluctuations will be unstable since the frequency of the network is unstable.

In the device [2] containing a cosine-sine voltage source, rotary transformers, phase and amplitude regulators, a two-phase asynchronous motor, maintaining the law of oscillation accuracy is possible in the range of 3 5%
The reproduction accuracy of the given law of oscillations in this case is determined by the stability of rotation of rotary transformers and nonlinear distortions in the frequency range 0.5–5 Hz reach 20%. For low-frequency oscillations requiring high control accuracy, these drawbacks are all the more noticeable [3]
The closest in technical essence is a device for creating oscillatory movements of the shaft of an induction motor using a frequency converter [4]
The device comprises an AC source and a frequency converter, including a phase detector, first and second frequency dividers, a voltage-frequency converter connected by an output to the inputs of the frequency dividers, an input with an output of a phase detector, the inputs of which are connected to an AC source and the output of the first divider frequency, and the output of the second divider is connected to the control input of the inverter.

 The output frequency of the inverter changes in proportion to the mains frequency. The accuracy of maintaining the oscillation frequency in this case cannot be better than 1%, which is a disadvantage of this device.

 The proposed device is aimed at expanding the operational capabilities of the drive by increasing the stability of the oscillation frequency and expanding the range of operating frequencies. This is achieved by introducing a transformer, a reference frequency generator, a comparator, a frequency divider with a constant division coefficient, a frequency divider with an adjustable coefficient, a pulse counter, a frequency divider with a variable coefficient, the counting input of which is connected to the output of the divider with a constant division coefficient, and the input of setting the division factor with the output of the pulse counter, the counting input of which is connected to the output of the frequency divider with an adjustable division factor, and the input of the resolution of the counting a comparator and a step-down transformer to the motor field winding; the input of the frequency divider with a constant division coefficient and the counting input of the frequency divider with an adjustable division coefficient are connected to the reference frequency generator; control winding along the circuit amplifier, filter, trigger connected to the output of the frequency divider with a variable division ratio.

 The essence of the device is illustrated by the block diagram shown in Fig. 1, where 1 is an AC source, 2 an induction motor with an excitation winding 3 and a control winding 4; the field winding is connected to an alternating current source 1. The output signals of the corresponding blocks are shown in Fig. 2. The engine control circuit consists of a transformer 5, a comparator 6, a reference frequency generator 7, a frequency divider with an adjustable division ratio 8, a frequency divider with a constant division coefficient 9, a pulse counter 10, a frequency divider with a variable division coefficient 11, trigger 12, a filter 13 and amplifier 14; moreover, the transformer 5 is connected directly to the network by the primary winding, the secondary winding serves to power the circuit and is connected to the input of the comparator 6, the output of which is connected to the enable input of the pulse counter 10, the counting input of which is supplied from the output of the adjustable frequency divider 8, the counting input of this divider , as well as the divider 9 is connected to the output of the reference frequency generator 7. The output of the divider 9 is connected to the counting input of the divider with a variable division factor 11, a variable reference code (from pulse counter 10 ) goes to the input of the setting of the code of the divider with a variable division coefficient 11, the output of which through the trigger 12-filter 13 amplifier 14 circuit is connected to the control winding 4 of the engine.

The device operates as follows, the field winding 3 of the motor 2 is powered from the source 1 by the current of the mains frequency f _c . The control winding on the amplifier amplifier filter trigger circuit is connected to a divider with a variable division ratio of 11.

The output of the reference frequency generator 7 is connected to the inputs of the frequency dividers 8 and 9, the first of which is a divider with a constant division coefficient n ₁ , the second with an adjustable n ₂ . The frequency f ₁ equal to f ₀ / n ₁ (f _{0 the} frequency of the generator), from the output of the divider 8 is fed to the counting input of the counter 10, the operation of which is determined by the comparator 6 (Fig. 2). The comparator is used to determine the period of time during which there is a count of pulses of frequency f ₁ . The result of the counter operation is the number N, this is the number of frequency pulses f ₁ in each half-cycle (half a period is taken for high accuracy of tracking changes in the network frequency) of the voltage supplying the motor excitation winding.

Число N является переменным коэффициентом задания (его переменность обусловлена нестабильностью частоты сети) для делителя с переменным коэффициентом деления, на счетный вход которого подается частота f₂, равная f₀/n₂, с делителя 9. В результате деления получим:

То есть
f₃ k•f_c.

The number N is a variable task coefficient (its variability is due to the instability of the network frequency) for a divider with a variable division coefficient, the counting input of which is supplied with a frequency f ₂ equal to f ₀ / n ₂ from divider 9. As a result of division, we get:

I.e
f ₃ k • f _c .

The coefficient k depends only on n ₁ , since n ₂ const.

 Thus, the stator windings of an induction motor are thus powered by alternating currents of different frequencies, one of which is obtained by multiplying the other frequency by a constant coefficient. The oscillation frequency of the shaft is controlled by changing the multiplication factor k.

Claims (1)

 A device for controlling a two-phase asynchronous motor in an oscillatory motion mode, comprising an induction motor with an excitation winding connected to an AC source and a control winding connected to a frequency converter, characterized in that a transformer, a reference frequency generator, a comparator, a divider are introduced into the frequency converter frequencies with constant division factor, frequency divider with adjustable division coefficient, pulse counter, frequency divider with variable coefficient ohm division, trigger, filter, amplifier, moreover, the control winding along the amplifier, filter, trigger circuit is connected to the output of the frequency divider with a variable division coefficient, the counting input of which is connected to the output of the divider with a constant division coefficient, and the input of setting the division coefficient with the output of the pulse counter , the counting input of which is connected to the output of the frequency divider with an adjustable division coefficient, and the input of the resolution of the count through the comparator and step-down transformer to the excitation winding of the motor, divide the input I with a constant frequency division factor and the count input of the frequency divider with adjustable division ratio connected to the reference oscillator.

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