RU2283501C1 - Device for estimating and predicting 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: for achieving current result, device contains rectangular impulse generator, synchronization block, analog-digital converter, microcontroller, external data memory, external program memory, keyboard and liquid-crystalline indicator. First input of analog-digital converter and input of synchronization block are serially connected to output of electric motor winding. First, second, third, fourth and fifth inputs of microcontroller are connected respectively to outputs of analog-digital converter, rectangular impulse generator, external data memory, external program memory and keyboard. First, second, third and fourth outputs of microcontroller are connected respectively to second input of analog-digital converter, to inputs of rectangular impulse generator, external data memory and liquid-crystalline indicator.

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. In this regard, the diagnostic results using the device in question have low reliability and accuracy in assessing the state of insulation. In addition, this device does not have the function of predicting the residual life of the diagnosed object.

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, with the outputs of the period meter, peak detector, and square-wave generator. The first and second outputs of the control unit are connected, respectively, with the inputs of the storage unit of the analog signal and the display unit. The voltmeter is connected to the output of the analog signal storage unit (see RF patent No. 2208234, IPC ⁷ G 01 R 31/12, 31/14).

This device allows you to measure parameters such as the amplitude of the first positive half-cycle, the amplitude of the second positive half-cycle, the magnitude of the first and second period. At the same time, it is difficult to determine the technical state of the insulation of an induction motor on the basis of an analysis of the values of these four parameters, and it is difficult to provide diagnostics and forecasting the residual life of the insulation of the electric motor. Information and visibility that could be provided if there was a function for predicting the residual life of the work and expressing the results in absolute units — hours, days, months, this device does not have. At the same time, the use of a voltmeter as an external measuring element of the device leads to a decrease in the accuracy of assessing the technical condition of the insulation of the motor windings due to the fact that the parameters of the used elements of the device — the presence of contact transition resistance, resistance of conductors, the accuracy class of the voltmeter are far from the reference values.

The present invention solves the problem of ensuring the diagnosis and prediction of the residual life of the insulation of the motor, as well as improving the accuracy of assessment and prediction of the technical condition of the insulation of the motor.

To achieve this technical result, a matching unit, an analog-to-digital converter, a microcontroller, an external data memory, an external program memory, a keyboard and a liquid crystal indicator are introduced into the device for assessing and predicting the technical state of the insulation of the motor windings. In this case, the first input of the analog-to-digital converter and the input of the matching device are connected in series with the output of the motor winding. The first, second, third, fourth and fifth inputs of the microcontroller are connected respectively to the outputs of the analog-to-digital converter, a rectangular pulse generator, external data memory, external program memory and keyboard. The first, second, third and fourth inputs of the microcontroller are connected respectively to the second input of the analog-to-digital converter, with the inputs of a rectangular pulse generator, an external data memory, and a liquid crystal indicator.

Diagnostics and prediction of the residual life of the motor insulation is achieved by introducing an analog-to-digital converter, a microcontroller, an external data memory, and external program memory to convert the analog diagnostic signal into digital form and make the necessary arithmetic calculations. Diagnosis and prediction of the residual life of the insulation of the motor winding implies the use of one of the mathematical models, for which the device is equipped with the function of independent calculations of varying degrees of complexity. It is implemented in the inventive device using a microcontroller, which operates according to the program stored in the external program memory. In addition, to assess the residual life of the insulation of the electric motor, it is necessary to have information about the design features of the electric motor, its operation mode and microclimate parameters. An external data memory is used to store this information. This information and the programs that the microcontroller operates on are entered into the external data memory and external program memory using the keyboard. Through the use of a liquid crystal indicator, the visibility of the measurement results and the receipt of necessary instructions by the operator are ensured. By converting the diagnostic signal from an analog form to a digital one with a high sampling rate, high accuracy is achieved in estimating and predicting the residual life of the motor insulation by improving the accuracy and reliability of measurements of diagnostic parameters, which include, for example, the amplitudes of the first and second positive half-periods and the period of damped oscillations in winding arising when a rectangular pulse is applied to it. This is realized by introducing an analog-to-digital converter into the device.

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

The device contains a rectangular pulse generator 1, designed to connect with the beginning of the winding of the studied motor 2, matching unit 3, analog-to-digital converter 4, microcontroller 5, external data memory 6, external program memory 7, keyboard 8, liquid crystal indicator 9. One from the terminals of the motor winding 2 is connected to the output of the rectangular pulse generator 1, and the other output is connected to the input of the matching unit 3. The output of the matching unit 3 is connected to the first input of the analog-to-digital converter For 4. The first, second, third, fourth, fifth inputs of the microcontroller 5 are connected, respectively, with the outputs of the analog-to-digital converter 4, a rectangular pulse generator 1, external data memory 6, external program memory 7, keyboard 8. First, second, third , the fourth outputs of the microcontroller 5 are connected, respectively, to the second input of the analog-to-digital converter 4, the inputs of the rectangular pulse generator 1, an external data memory 6, a liquid crystal indicator 9.

The rectangular pulse generator 1 generates rectangular pulses with a duration of 1 ms and an amplitude of 1-5 V. It has a powerful amplifier stage at the output, which allows it to be connected to motors with a low resistance of the phase-case circuit, which is typical for high-power asynchronous motors. The coordination unit 3 provides the connection of the electronic part of the device to an induction motor. The coordination unit 3 is made in the form of an emitter follower, which provides it with a large input and low 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. An analog-to-digital converter 4 converts a continuous ramp signal into its digital equivalent with a resolution of 16 bits. The sampling period for analog values is 10 μs. The microcontroller 5 performs the following functions:

- on command from the keyboard generates a start signal for the square-wave generator 1;

- starts up the analog-to-digital Converter 4 and reads a digital code from it;

- interrogates the keyboard 8 to enter the values of the reference diagnostic parameter, the diagnostic parameter obtained in the previous diagnosis, and the time elapsed since the last diagnosis;

- calculates the value of the current generalized diagnostic parameter, the operating time of the diagnosed engine before failure;

- controls the operation of the liquid crystal indicator 9 in order to display the values entered from the keyboard, the operating modes of the device and the measurement results.

External data memory 6 is used to store the results of the analog-to-digital Converter 4, intermediate results and diagnostic results. The external program memory 7 is used to store the program that controls the operation of the microcontroller 5. The keyboard 8 is a matrix of keys needed to enter the source data and control the operating modes of the device. The liquid crystal indicator 9 is designed to display information about the measurement results and instructions to the operator.

A device for assessing and predicting the technical condition of the insulation of the motor works as follows.

On command from the keyboard 8, the microcontroller 5 generates a start signal for the generator 1 of rectangular pulses. From the output of the rectangular pulse generator 1, a single diagnostic pulse is fed to one of the terminals of the motor winding 2 and to the second input of the microcontroller 5. From the other terminal of the motor winding 2, the signal is fed to the input of the matching unit 3, which ensures that this signal is not distorted, which may be caused by the claimed devices. From the output of the matching unit 3, the signal is fed to the input of the analog-to-digital converter 4. The microcontroller 5, upon receipt of the signal from the rectangular pulse generator 1, supplies a signal to the first input of the analog-to-digital converter 4, which puts it into operation. In the analog-to-digital converter 4, the diagnostic signal is converted into a digital code, which is transmitted to the first input of the microcontroller 5. The signal is read by the microcontroller 5 from the analog-to-digital converter 4 for a time equal to the duration of the pulse generated by the square-wave generator 1. At the fourth input of the microcontroller 5 commands are received from the external program memory 7. The microcontroller 5 processes in accordance with the program the information received from the analog-to-digital converter 4 and calculates the current value of the diagnostic parameter, which is transferred from its third output to storage to the external data memory 6 and from the fourth output to the liquid crystal indicator 9. The microcontroller 5 polls the keyboard 8 in order to obtain a reference value of the diagnostic parameter, the value of the diagnostic parameter, obtained during the previous diagnosis and the time elapsed since the last diagnosis. To ensure the consistent introduction of these values from the fourth output of the microcontroller 5, the control pulses are fed to the input of the liquid crystal indicator 9. Upon receipt of all the necessary data from the keyboard 8, which are temporarily stored in the external data memory 6, the microcontroller 5 calculates the remaining time until the isolation output motor failure, the value of which is transmitted from the fourth output of the microcontroller 5 to the liquid crystal indicator 9.

To assess the residual life, for example, a multi-factor deterministic forecast model developed by I.A. Gutov (I. Gutov, Prediction of the condition of electric motors based on the use of multifactor models of insulation aging: Diss .... Candidate of Engineering Sciences: 05.20 .02. - Barnaul, 1997 .-- 259 p.). Estimated service life using this model is possible by the following expressions:

t _ost = T-t;

where t _ost - residual life, months .;

T - full service life after commissioning, months .;

t - time elapsed since the start of operation, months;

F _beg - the initial value of the generalized diagnostic parameter, p.u .;

F _cr - the critical value of the generalized diagnostic parameter at which the probability of failure of the electric motor is highest, p.u .;

b and c - model parameters depending on operating conditions, p.u.

The values of the parameters b and c are stored in the external data memory 6 and are selected by the microcontroller 5 depending on the values of the parameters of the operating conditions (average air humidity, operating mode, ambient temperature). The program providing the calculation using the above formulas is stored in the external memory of programs 7. As a result of the calculations, the value of the remaining service life in months is displayed on the liquid crystal indicator 9.

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 evaluating and predicting the technical condition of the insulation of the motor windings, containing a rectangular pulse generator, designed to connect to the motor winding, characterized in that a matching unit, an analog-to-digital converter, microcontroller, external data memory, external program memory, keyboard and liquid crystal indicator, while the first input of the analog-to-digital converter and the input of the matching device are connected in series with the output of the winding ki of the electric motor, the first, second, third, fourth and fifth inputs of the microcontroller are connected respectively to the outputs of the analog-to-digital converter, the rectangular pulse generator, external data memory, external program memory and keyboard, and the first, second, third and fourth outputs of the microcontroller are connected respectively with the second input of an analog-to-digital converter, with the inputs of a rectangular pulse generator, an external data memory, and a liquid crystal indicator.