RU2283503C1 - Device for estimating technical state of isolation of windings of electric motor - Google Patents

Abstract

FIELD: measuring equipment engineering, possible use for diagnostics of isolation of windings of three-phased electric motors.

SUBSTANCE: device contains generator of rectangular impulses, synchronization block, periods detector, first and second analog commutators, period duration counter, clock impulse generator, first and second amplitude detectors, first and second generators, controlled by voltage, control block, decoder-counter, liquid-crystalline indicator. Synchronization device and periods detector are serially connected to output of winding of electric motor. Input of synchronization block is connected to output of electric motor winding, while output of synchronization device is connected to input of periods detector. First inputs of first and second analog commutators are connected to output of synchronization block, and second inputs are connected to first and second outputs of periods detector.

EFFECT: expanded functional capabilities.

1 dwg

Description

The invention relates to instrumentation and can be used to diagnose the insulation of the windings of three-phase electric motors.

A device for diagnosing the windings of electric machines, containing a rectangular pulse generator that generates and delivers rectangular pulses with specified parameters to the winding of the studied electric machine, three differentiators that process the received signal, a key, an output unit and a voltmeter that displays the measurement result. The output of the rectangular pulse generator is connected to the beginning of the winding. The end of the winding of an electric machine is connected to the input of the first differentiator. The output of the first differentiator is connected to the input of the second differentiator and the first input terminal of the key. The output of the second differentiator is connected to the input of the third differentiator and the second input terminal of the key. The output of the third differentiator is connected to the third input terminal of the key. The output terminal of the key is connected to the input of the output unit. From the output unit, the measuring information is fed to a voltmeter (see Belousova N.V., Kalyavin V.P., Mozgalevsky A.V. Experience in test diagnosis of windings of electric machines. - L.: LDNTP, 1989. - P.19-21, fig. 6).

This device allows you to obtain a diagnostic parameter, with which, after mathematical processing, such characteristics as the resistance and capacity of the winding of an electric machine relative to the housing are determined. At the same time, the state of insulation mainly depends on the parameters of inter-turn insulation, such as inter-turn resistance and inter-turn capacitance. Therefore, it is preferable to measure the parameters of the wave attenuating process with high accuracy, which would make it possible to more simply and with less complexity evaluate the values of various parameters of the electrical insulation system of electric motors and generalized diagnostic parameters.

A device for assessing the technical condition of the insulation of the motor windings, used as a prototype, contains a rectangular pulse generator designed to connect to the beginning of the studied motor winding, an amplifier-limiter, a period meter, a peak detector, a control unit, a mode indicator, an analog signal storage unit, a voltmeter . The beginning of the motor winding is connected to the output of the rectangular pulse generator, and the end of the motor winding is connected to the parallel inputs of the amplifier-limiter and peak detector. The output of the amplifier-limiter is connected to the input of the period meter. The first, second and third inputs of the control unit are connected respectively to the outputs of the period meter, peak detector, and square-wave generator. The first and second outputs of the control unit are connected respectively to the inputs of the analog signal storage unit and the indication unit. The voltmeter is connected to the output of the analog signal storage unit (see RF patent No. 2208234, IPC ⁷ G 01 R 31/14).

This device allows you to measure parameters - diagnostic insulation parameters, such as the amplitude of the first positive half-cycle, the amplitude of the second positive half-cycle, the value of the first and second periods. However, the significant disadvantages are the increased complexity of the measurement and the need to use an external measuring device to indicate the results and conditionality of the indication of the values of the periods, since a digital or analog voltmeter displays the measurement in volts. In addition, the accuracy of the results of assessing the technical condition of the insulation of the motor windings may be affected by the circuit parameters from the output of the device to the voltmeter - contact resistance, wire resistance.

The present invention solves the problem of reducing the complexity, improving accuracy and providing an indication of the results of evaluating the technical condition of the insulation of the motor windings in named units.

The solution to this problem is achieved by the fact that in the device for assessing the technical condition of the insulation of the motor windings, containing a rectangular pulse generator for connecting to the motor winding, according to the invention, a matching unit and a period detector are connected in series with the output of the motor winding, and the input of the matching unit is connected to the output of the motor winding, and the output of the matching unit is connected to the input of the period detector, the first and second analog switches, the first inputs of which are connected to the output of the matching unit, and the second inputs to the first and second outputs of the period detector, a period duration counter, the first input of which is connected to the third output of the period detector, a clock pulse generator, the output of which is connected to the second input of the period duration counter , the first and second amplitude detectors, the inputs of which are connected to the outputs of the first and second analog switches, respectively, and the outputs - with the inputs of the first and second generator a voltage-controlled ditch, a control unit and a counter-decoder, the first input of a counter-decoder connected to the output of the control unit, the second input of a counter-decoder with an output of a duration counter, the third and fourth inputs of a counter-decoder with outputs of the first and second generators controlled by voltage, respectively, and the output of the counter-decoder is connected to the input of the liquid crystal indicator introduced into the device.

Reducing the complexity, increasing accuracy and providing an indication of the results of assessing the technical condition of the insulation of the motor windings is ensured by digitally processing the selected parameters of the analog signal by introducing a period counter, voltage-controlled generators, first and second analog switches, first and second amplitude detectors, and the counter a decoder, as well as a liquid crystal indicator, as well as the absence of the need to use an external meter itelnogo device, namely a voltmeter.

The drawing shows a structural diagram of the proposed device for assessing the technical condition of the insulation of the motor windings.

A device for assessing the technical condition of the insulation of the motor windings contains a rectangular pulse generator 1, designed to connect with the beginning of the studied motor winding 2, matching unit 3, period detector 4, control unit 5, clock generator 6, period duration counter 7, first analog switch 8 , the first amplitude detector 9, the first voltage-controlled oscillator 10, the counter-decoder 11, the liquid crystal indicator 12, the second analog switch 13, the second child amplitude torus 14, the second oscillator 15, voltage controlled oscillator. One of the conclusions of the motor winding 2 is connected to the output of the rectangular pulse generator 1, and the other output is to the input of the matching unit 3. The output of the matching unit 3 is connected to the input of the period detector 4, the first input of the first 8 and the first input of the second 13 analog switches. The first, second and third outputs of the period detector 4 are connected respectively to the second input of the first analog switch 8, the second input of the second analog switch 13, the first input of the period counter 7. The output of the clock 6 is connected to the second input of the period counter 7. The output of the first analog the switch 8 is connected to the input of the first amplitude detector 9. The output of the first amplitude detector 9 is connected to the input of the first voltage controlled oscillator 10. The output of the second analog switch 13 is connected to the input of the second amplitude detector 14. The output of the second amplitude detector 14 is connected to the input of the second voltage controlled oscillator 15. The first, second, third and fourth inputs of the counter-decoder 11 are connected respectively with the outputs of the control unit 5, the counter for the duration of periods 7, the first 10 and second 15 generators, voltage-controlled. The output of the counter-decoder 11 is connected to the input of the liquid crystal indicator 12.

The rectangular pulse generator 1 provides the supply to the winding of the electric motor of pulses with a duration of 1 ms and an amplitude of 3V. Generator 1 has a powerful amplifier stage at the output, which allows you to connect the device to motors with low resistance "phase-housing", which is typical for asynchronous motors of high power. The coordination unit 3 provides the connection of the electronic part of the device to the electric motor. Block 3 is made in the form of an emitter follower, which provides it with a large input impedance and a small output impedance. This ensures that there is no distortion of the signal received from the induction motor caused by the load of the entire device. The period detector 4 is designed to determine the times at which the amplitude of the received signal is greater than the threshold 3B (positive half-waves of a damped oscillatory process), as well as to determine the gap between these signals. The control unit 5 controls the operation of the liquid crystal indicator 12 and determines the value of which parameter to display at the moment: the amplitude of the first positive half-cycle, the amplitude of the second positive half-cycle, the period of damped oscillations. The clock generator 6 is designed to create a sequence of calibrated high-frequency signals. The period duration counter 7 calculates the number of calibrated high-frequency signals during the time the signal from the period detector 4 is present and on the basis of this determines the duration of the period of the wave damped process. The first analog switch 8 provides for the selection of a positive half-wave of the first period from the wave oscillation process signal. The first amplitude detector 9 generates a constant voltage with a value equal to the amplitude of the positive half-wave of the first period of the wave damped oscillations. The first voltage-controlled oscillator 10 generates a digital signal with a frequency proportional to the voltage supplied from the first amplitude detector 9. The counter-decoder 11 calculates the number of digital pulses and converts the obtained values into a parallel digital signal suitable for controlling a liquid crystal indicator 12. The liquid crystal indicator 12 is intended to display measurement results. The second analog switch 13 provides the selection of the signal of the wave oscillation process of the positive half-wave of the second period. The second amplitude detector 14 generates a constant voltage with a value equal to the amplitude of the positive half wave of the second period of the wave damped oscillations. The second voltage controlled oscillator 15 generates a digital signal with a frequency proportional to the voltage supplied from the second amplitude detector 14.

A device for assessing the technical condition of the insulation of the motor windings is as follows.

From the output of the rectangular pulse generator 1, a diagnostic signal is fed to one of the terminals of the motor winding 2. From the other terminal of the winding of the studied motor 2, the signal is fed to the input of matching block 3, which ensures that this signal is not distorted, which may be caused by the operation of the inventive device. From the output of the matching unit 3, the signal is fed to the input of the period detector 4, the first input of the first analog switch 8, the first input of the second analog switch 13. The control signal is received at the second input of the first analog switch 8 from the first output of the period detector 4, thanks to which it is possible to isolate it for further processing the first positive half-wave of the diagnostic signal, which is fed to the input of the first amplitude detector 9. At the second input of the second analog switch 13 from the second output of the detector periods 4 receives a control signal, thanks to which it is possible to separate the second positive half-wave of the diagnostic signal for further processing, which is fed to the input of the second amplitude detector 14. In the first 9 and second 14 amplitude detectors, the largest voltage value is determined and converted to a constant voltage value, which is fed to the inputs of the first 10 and second 15 generators, respectively, controlled by voltage. In the first 10 and second 15 voltage-controlled generators, a constant voltage is converted at the input to a sequence of high-frequency rectangular pulses, the number of which is proportional to the voltage value. From the outputs of the first 10 and second 15 voltage-controlled generators, a sequence of high-frequency pulses is supplied respectively to the third and fourth inputs of the counter-decoder 11. From the third output of the period detector 4, a signal whose duration corresponds to the period duration is fed to the first input of the period-length counter 7. The counter for the duration of periods 7 supplies to the second input of the counter-decoder 11 a sequence of high-frequency rectangular pulses, the frequency of which is set by the clock generator 6 pulses, and their number is proportional to the duration of the signal period. In the counter-decoder 11, the incoming information is read and converted into a signal for the liquid crystal indicator 12. The control unit 5 supplies a signal to the first input of the counter-decoder 11, which determines the value of which of the three parameters — the amplitude of the first positive half-cycle, the amplitude of the second positive half period, period of damped oscillations - it is necessary to indicate at a given time on the liquid crystal indicator 12.

The advantages of the proposed device are simplicity, ease of use, high reliability and accuracy of the assessment of the results.

Claims (1)

A device for assessing the technical condition of the insulation of the motor windings, comprising a rectangular pulse generator, designed to connect to the motor winding, characterized in that a matching unit and a period detector are connected in series with the output of the motor winding, and the input of the matching unit is connected to the output of the motor winding, and the output of the matching unit is connected to the input of the period detector, the first and second analog switches, the first inputs of which are connected to the output of the matching unit, and the second inputs to the first and second outputs of the period detector, a period duration counter, the first input of which is connected to the third output of the period detector, a clock pulse generator, the output of which is connected to the second input of the period duration counter, the first and second amplitude detectors the inputs of which are connected to the outputs of the first and second analog switches, respectively, and the outputs are connected to the inputs of the first and second voltage-controlled generators introduced into the device, the control unit I and the counter-decoder, and the first input of the counter-decoder is connected to the output of the control unit, the second input of the counter-decoder is with the output of the duration counter, the third and fourth inputs of the counter-decoder are with the outputs of the first and second generators, voltage-controlled, respectively, and the output of the counter-decoder is connected to the input of the liquid crystal indicator introduced into the device.