RU2457499C1 - Method for diagnostics of electric equipment current conductor insulation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: electric voltage is supplied to the electric winding current conductor outputs with the current conductor ohmic resistance value measured. Then one measures the value of the current conductor ohmic resistance at reverse polarity of the electric voltage supplied. One calculates the value of absolute magnitude of the difference between the measured values of the current conductor ohmic resistance in the modes of direct and reverse polarity of electric voltage. One compares the calculated value with the values of absolute magnitude of the difference between the current conductor ohmic resistances corresponding to specific types of the current conductor insulation damages. By the comparison result one identifies the insulation damage type. This enables provision of recommendations on maintenance and operation of the winding diagnosed.

EFFECT: extension of functionalities due to the possibility to detect the insulation damage type.

5 cl, 1 tbl, 1 dwg

Description

The invention relates to methods for diagnosing insulation of electrical equipment conductors and can be used to determine the dielectric properties of insulation of electric windings of electric motors.

Known methods for monitoring the state of insulation of the windings of electric motors by measuring the electrical insulation resistance (for example, RU 2028639, published 09.02.1995). These methods do not allow to recognize the type of insulation damage.

Closest to the proposed one is a method of monitoring the state of insulation of the motor windings, in which a rectangular signal is applied to the winding and the diagnostic parameters are used to judge the insulation state of the motor windings, the diagnostic parameters are the amplitudes of the first and second half periods and the magnitudes of the first and second periods of the damped oscillatory process , when comparing the values of which with the reference diagnostic parameters, they make a conclusion about the state of insulation of the windings (RU 2208236 C2, published 02.20.2003). However, this method also does not allow to recognize the type of insulation damage.

The technical result, to which the present invention is directed, is to expand the functionality of the method, due to the possibility of recognizing the type of damage to the insulation of the current conductor of electrical equipment, in particular the electrical winding of the traction motor.

The above technical result is achieved due to the fact that the method for diagnosing insulation of the electrical winding of an electrical equipment is characterized in that electrical equipment supplies electrical voltage to the electrical leads of the electrical conductor of the electrical winding, measures the value of the ohmic resistance of the conductor, then measures the value of the ohmic resistance of the conductor with reverse polarity applied voltage, calculate the value of the absolute values difference measurement values ohmic tokoprovodnika resistances in the normal and reverse polarity electrical voltage applied to the electrical leads tokoprovodnika is corresponded to the calculated value with the values of the absolute value of the difference ohmic resistances tokoprovodnika corresponding to certain types of damage to the insulation tokoprovodnika, according to the result of comparison identify the presence and type of insulation failure. This allows you to issue recommendations for the maintenance and operation of the diagnosed winding.

In this case, the state of the insulation of the winding, corresponding to the absolute value of the difference between the measured ohmic resistances of the conductor, equal to or less than 4-5% of the value of the ohmic resistance of the conductor, measured in the modes of direct or reverse polarity of the electrical voltage, is identified as a damp insulation of the conductor, which has no damage and fault violations, and the state of insulation of the winding, corresponding to the absolute value of the difference of the measured ohmic resistances oprovodnika, more than 5-6% of the values of the ohmic resistance tokoprovodnika measured in the forward or reverse modes polarity voltage is identified as the wet insulation or damage, characterized by the disturbance of continuity, structure, partial breakdown of the insulation.

In particular, damage to the insulation of the winding, corresponding to the absolute value of the difference between the measured ohmic resistances of the conductor, equal to 7-10% of the value of the ohmic resistance of the conductor, measured in the modes of direct or reverse polarity of the electrical voltage, is identified as wet insulation, and damage to the insulation of the winding corresponding to the value of the absolute value of the difference between the measured ohmic resistances of the current conductor, more than 10-12% of the value of the ohmic resistance Ia tokoprovodnika measured in the forward or reverse modes polarity voltage is identified as a violation insulation layers or partial breakdown.

The proposed method is intended to diagnose the insulation state of electric machines (stator, rotor, armature, excitation, additional poles), coils, reactors, etc., in which the conductors of the windings are made of copper alloys, and the cores on which the winding is located are made of electrical become. This method is applicable both to the traction engines of railroad locomotives, and to general industrial electric motors, electric generators, transformers and reactors.

The proposed method is aimed at diagnosing the insulation state of the windings of electric machines (stator, rotor, armature, excitation, additional poles), coils, reactors, etc., in which the conductors are made of copper alloys, and the cores on which the winding is wound, from electrical become.

The invention is illustrated in figure 1, which shows a diagram of a measurement of the ohmic resistance of a current conductor of an electrical winding. Figure 1 shows a current conductor 1 of electrical equipment having electrical leads (contacts) 2 and 3, as well as an insulation monitoring device 4 (for example, an ohmmeter) with measuring probes 5 and 6.

The actual aspects of the proposed method for diagnosing the insulation of an electric winding, the current-carrying conductor of which is made of a copper alloy, and the core on which the winding is wound, is made of an iron alloy (electrical steel), the following processes and phenomena.

1. In the process of the redox reaction, the transition of electrons from the reducing agent to the oxidizing agent occurs. So, in the copper-iron pair, the reaction Fe + Cu ²⁺ = Cu + Fe ²⁺ occurs. Here, the reducing agent - iron - gives up electrons - Fe-2e = Fe ²⁺ . The oxidizing agent - a copper ion - accepts electrons - Cu ²⁺ + 2e = Cu.

With this redox reaction, a galvanic EMF is formed, which can be measured for further processing and diagnosis. It is on this principle that the proposed diagnostic method is based.

2. The functioning of any galvanic cell is based on the occurrence in it of a redox reaction. During the operation of a galvanic cell, the electrons from the reducing agent pass to the oxidizing agent through an external circuit, electrochemical processes occur on the electrodes, and a directed movement of ions is observed in the solution.

3. Similar processes take place in an electric winding located on the core with wetted or broken insulation, which is galvanic vapors of iron and copper separated by an electrolyte (moisture containing various impurities, elements that pollute the insulation, conductive dust or products of insulation damage).

Since the galvanic EMF has a direction, when measuring the ohmic resistance of the conductor in direct and reverse polarity, the measured values will differ from the reference voltage by the magnitude of the galvanic EMF.

A. Measuring mode, in which the direction of the measuring current coincides with the direction of the galvanic EMF.

When measuring resistance, an ohmmeter (device 4) creates a reference (test) voltage U _ohm on the measured circuit (current-carrying conductor 1), while the current I _ohm flows through the circuit, which is determined by the equation [1].

where U _ohm is the reference voltage created by the ohmmeter. AT;

E _gal - galvanic EMF resulting from electrochemical processes described in paragraph 1, B;

R _about - the desired resistance of the winding. Ohm.

B. Measuring mode, in which the direction of the measuring current is opposite to the direction of the galvanic EMF.

When measuring resistance, an ohmmeter (device 4) creates a reference (test) voltage U _ohm on the measured circuit (current-carrying conductor 1), while the current I _ohm flows through the circuit, which is determined by the equation [2].

where U _ohm is the reference voltage created by the ohmmeter, V;

E _gal - galvanic EMF resulting from electrochemical processes described in paragraph 2, B;

R _about - the desired resistance of the winding, Ohm.

Galvanic EMF E _gal is 0.4-0.5% of the reference voltage of the ohmmeter U _ohm .

Thus, on the basis of the calculation formulas [1, 2], the current I _ohm flowing along the measured circuit with the forward and reverse polarity of the ohmmeter connection will be different, and therefore the resistance R values _{of the} measured winding calculated by the ohmmeter will also differ when a galvanic EMF occurs due to wetting of the insulation.

4. If the insulation is dry and has no damage, then galvanic EMF does not occur in it, and when measuring the ohmic resistance of the current conductor at different polarities of the connection of the diagnostic device, the readings will differ within no more than 4-5%.

5. If the insulation is wet or has damage (discontinuity, structures, partial breakdowns), then the difference appears when measuring ohmic resistance in the modes of direct and reverse polarity more than 5-6%, this difference is due to the fact that when measured in direct polarity mode The reference voltage generated by the diagnostic tool is added to the galvanic emf of the insulation, and in the reverse polarity mode it is subtracted, as shown above.

The process of diagnosing the insulation of an electrical winding based on a comparison of the instantaneous values of the ohmic resistance of the windings (current conductors) of the controlled electrical equipment consists of the following steps (see figure 1):

1. Connection of insulation control device 4 (diagnostic tool - ohmmeter) to terminals 2 and 3 (electrical contacts 2 and 3) of current-conducting device 1 of the controlled equipment (winding input and output, cable start and end, points of different voltage on the electric circuit, etc.) , measurement is carried out by probes 5 and 6.

2. Measurement of instantaneous values of the ohmic resistance of the investigated conductors 1, respectively, in direct and reverse polarity (figure 1) - this operation is performed by a diagnostic device 4.

3. Calculation of the absolute value of the difference between the measurements - this operation is performed by the diagnostic tool 4.

4. Issuing recommendations on the operation of the electric winding - the need for drying, electrical insulation coating or partial replacement of insulation coatings or layers.

For measurements, the voltage is applied to the electrical contacts 2 and 3 in the forward and reverse directions.

In an undamped insulation that does not have damages and violations of oversights, the difference in the measured instantaneous ohmic resistance values is not more than 4-5%, and the insulation is wet or with a violation of the continuity of the structure, with partial breakdowns, the specified difference is more than 5-6%. In particular, wetted insulation has a difference of the measured values at the level of 7-10%, and insulation with violation of layers or partial breakdown, respectively, more than 10-12%.

The diagnostic method is implemented as follows.

In electrical equipment, an electrical winding is detected, the insulation of which is subject to diagnostic control. An electrical voltage is applied to the electrical terminals 2, 3 of the current conductor 1 of the detected winding, the ohmic resistance value of the current conductor 1 is measured and stored, and then the ohmic resistance value of the current conductor 1 is measured and stored at the reverse polarity of the applied electrical voltage. The value of the absolute value of the difference in the stored measured values of the ohmic resistances of the conductor in the modes of direct and reverse polarity of the electric voltage supplied to the electrical terminals 2, 3 of the conductor 1 is calculated. The calculated value is compared with the values of the absolute value of the difference in the ohmic resistances of the conductor corresponding to certain types of damage to the insulation of the conductor, and by the result of the comparison, they identify the type of damage to the insulation of the current conductor and issue a recommendation ndatsii maintenance and operation of the electrical winding diagnosed.

Damage to the insulation of the winding, corresponding to the absolute value of the difference between the ohmic resistances of the current conductor, measured in the forward and reverse polarity modes of the electric voltage applied to the electrical terminals 2, 3 of current conductor 1, equal to or less than 4-5% of the value of the ohmic resistance of current conductor 1, measured in modes of direct or reverse polarity of the electrical voltage applied to the electrical terminals 2, 3 of the current conductor 1, is identified as a damp insulation that has no damage eny and discontinuities.

Damage to the winding insulation corresponding to the absolute value of the difference in the ohmic resistances of the conductor, measured in the forward and reverse polarity modes of the electric voltage applied to the electrical leads 2, 3 of the current conductor 1, equal to 5-6% of the value of the ohmic resistance of the current conductor, measured in the direct or the reverse polarity of the electrical voltage applied to the electrical terminals 2, 3 of the conductor 1 is identified as wet insulation or as damage characterizing a violation of continuity, structure, partial breakdowns of isolation.

Damage to the insulation of the winding, corresponding to the absolute value of the difference between the ohmic resistances of the current conductor, measured in the forward and reverse polarity modes of the electric voltage applied to the electrical terminals 2, 3 of the current conductor 1, equal to 7-10% of the value of the ohmic resistance of the current conductor, measured in the direct or the reverse polarity of the electrical voltage applied to the electrical terminals 2, 3 of the conductive 1 is identified as wet insulation.

Damage to the winding insulation corresponding to the value of the absolute value of the difference between the ohmic resistances of the current conductor, measured in the forward and reverse polarity modes of the electric voltage applied to the electrical leads 2, 3 of the current conductor 1, equal to 10-12% of the value of the ohmic resistance of the current conductor, measured in the direct or the reverse polarity of the electrical voltage supplied to the electrical terminals 2, 3 of the conductive 1 is identified as insulation with violation of layers or partial breakdown.

An example of a technological process for diagnosing the insulation state of windings of traction motors of electric locomotives:

1. Connecting the diagnostic tool 4 to the electrical contacts 2 and 3 (terminals) of the controlled winding of the traction motor (performed on the terminal rail of the reversing switch);

2. Measurement of instantaneous values of the ohmic resistance of the winding of the traction motor in direct and reverse polarity;

3. Calculation of the absolute value of the difference between the performed test measurements and the issuance of recommendations on the possibility of operating a controlled traction motor and the need to carry out its drying, electrical insulation coating or partial replacement of insulation coatings or layers.

The measured values of ohmic resistances are presented in the table, which also provides conclusions on the detected damage.

Thus, the proposed method for diagnosing the insulation of electrical windings of electrical equipment allows you to recognize the type of damage to the insulation.

Claims (5)

1. A method for diagnosing insulation of an electrical winding of electrical equipment, which consists in supplying electrical voltage to the electrical terminals of a winding conductor, measuring the value of the ohmic resistance of the current conductor, then measuring the value of the ohmic resistance of the conductor with the reverse polarity of the supplied electrical voltage, calculating the value of the absolute value of the difference the measured values of the ohmic resistances of the conductor in the forward and reverse fields polarity of the voltage applied to the electrical leads tokoprovodnika, the calculated value is compared with the values of the absolute value of the difference tokoprovodnika ohmic resistances corresponding to certain types of damage to the insulation tokoprovodnika, according to the result of comparison identify the presence and type of insulation failure. 2. The method according to claim 1, characterized in that when the absolute value of the difference between the ohmic resistances of the conductor, measured in the forward and reverse polarity of the electric voltage, equal to or less than 4-5% of the value of the ohmic resistance of the conductor, measured in the forward or reverse polarity of electrical voltage, identify wetted insulation that does not have damage and violations of errors. 3. The method according to claim 1, characterized in that when the absolute value of the difference between the ohmic resistances of the conductor, measured in the forward and reverse polarity of the voltage, more than 5-6% of the value of the ohmic resistance of the conductor, measured in the forward or reverse polarity electrical voltage, identify wet insulation or damage, characterized by a violation of continuity, structure, partial breakdowns of insulation. 4. The method according to claim 3, characterized in that when the absolute value of the difference between the ohmic resistances of the conductor, measured in the forward and reverse polarity of the voltage equal to 7-10% of the value of the ohmic resistance of the conductor, measured in the forward or reverse polarity voltage, identify wetted insulation. 5. The method according to claim 3, characterized in that when the absolute value of the difference between the ohmic resistances of the conductor, measured in the forward and reverse polarity of the electric voltage, more than 10-12% of the value of the ohmic resistance of the conductor, measured in the forward or reverse polarity voltage, identify insulation with violation of layers or partial breakdown.