SU1195282A1 - Method of determining resistance of alternating current machine and transformer windings - Google Patents

Abstract

The invention relates to a measurement technique and is intended to control the parameters of electric machines, their temperature and load modes of operation. The purpose of the invention is to expand the functionality. A constant component is formed from the alternating current of the primary winding by connecting in series with one of the windings a controlled asymmetrical resistive two-pole network. Simultaneously with the constant component, the variable component of the current is formed with a frequency that is a multiple of the frequency of the current of the supply network. The values of the constant component of the current, the voltage drop across the windings, the amplitude of the voltage harmonics, the amplitudes of the in-phase and the quadrature components of the current-generated harmonics are measured. According to the representation (Lenna in the description (the formula determines the resistance of the primary windings and the reduced resistance of the secondary windings of the electric machine 1 Cp f-ly 7 or v. I

Description

The invention relates to measuring technique, in particular to measuring the active resistances of the windings of electrical AC machines and transformers during normal operation, and is intended to control the parameters of the machines, as well as their temperature and load conditions.

The purpose of the invention is the expansion of functionality by providing the ability to determine the active resistance of the secondary windings.

The method of determination consists in the fact that without disconnecting the electric machine or transformer from the supply network, a small constant component is formed from alternating current flowing through the primary windings by switching in series with one of the windings of a controlled asymmetric resistive two-terminal network, and simultaneously with the constant component, an alternating current component with frequency that is a multiple of the frequency of the current supply network (for example, with three times, five times, η-fold frequency), for which control the value conductivity of a two-terminal network. Then measure the value of the DC component of the current

1 ₀ and the magnitude of the voltage drop U _o on the windings caused by the flow of this component, measure the amplitude of the voltage harmonic due to the generated alternating current component, measure the in-phase amplitudes of 1 _p and the quadrature components of the formed current harmonic. It is calculated by sampling so as to preserve the conditions of the normal operating mode of the electric machine, for example, equal to 1-2% of the magnitude of the amplitude of the supply current.

Figure 1-3 shows options for switching on the primary windings of an electric machine and measuring instruments, figure 4 shows a controlled asymmetric resistive bipolar, figure 5 shows a five-element T-shaped phase equivalent circuit of an alternating current electric machine and a transformer. fundamental current harmonics with

15. frequency o » _e , in Fig.6 is an equivalent circuit for the DC component of the current, Fig.7 is a phase equivalent circuit of an electric machine for the nth harmonic of a current of increased frequency ω _η = ηω ₀ .

2Q Scheme (Figs. 1-3) contains a sensor 1 for measuring the DC component of the current and amplitudes of the in-phase and quadrature components of the generated harmonic current, sensor 2 measure 25 for the DC component voltage _; the amplitudes and amplitudes of the generated voltage harmonic, controlled asymmetrical resistive bipolar 3, primary windings 4-6 of an electric machine.

The controlled asymmetric resistive bipolar (Fig. 4) contains contacts 7 and 8 of the control circuit, transistors 9 and 10, diodes 11-15.

³³ On the equivalent circuit (Figs. 5-7), R and Rj are the primary resistance and the reduced resistance of the secondary winding of the electric machine, L ₁ , the leakage inductance and the verified values of the primary resistance of the primary windings R _n and the reduced active resistance. R ₂ secondary windings of an electric machine according to the formulas:

_R _ _k But ^R < ^K Ip 9 (1) p '_ ^R 2 ^K 4. ² + H Uo. I / ’ (2) oi. n _r 0 fifty

where K is a coefficient that takes into account the switching circuit of the primary windings of an electric machine (K = 2/3 for switching on the windings according to the star circuit ”, K = 1 for a star circuit with zero, K = 1/2 for a 55 triangle circuit).

The values of the formed constant and variable component currents are the scattering inductance of the primary and secondary windings, respectively, at the fundamental frequency ω ₀ , WpL ^ is the inductive resistance of the magnetizing circuit.

Use two main provisions.

The first position is that the 'phase equivalent circuit of the electric machine for the formed constant component of the current flowing through the winding is the active resistance of this winding (Fig.6), which is determined by measuring the magnitude of the direct current 1 ₀ and the magnitude of the voltage drop U _o due to the flow of ¹ constant current component

The second main position is that the phase equivalent circuit of the electric machine for the ηth harmonic 5 of the current i _n corresponding to the nth harmonic of the generated alternating voltage U _n with a frequency ω _η multiple of the frequency pJ ₀ of the supply voltage has the form in Fig. 7 Yu (at. Therefore, the magnitude of the in-phase (active) component of the nth harmonic of the current flowing through the primary windings will be proportional to the total active 15 resistance of this equivalent circuit, i.e. R ^ + R ₂ , which can be determined according to the measured amplitude of the pth the harmonics of the generated voltage U _n and the in-phase amplitudes of 1 _Pl and quadratic 1 _p ^ of the components of the nth current harmonic

(4)

Subtracting from the obtained value

rank measured. get η ¹ H n ISSC p ^K 2 ~ t2 ₊ T2 (5) or thirty

(6)

To take into account the branching of the currents with various schemes for switching on the phase’s current of the machine among themselves (Figs. 1-3), the factor K was introduced into expressions (3) - (6).

To carry out the operation of simultaneously generating a constant 40 and alternating current components, a controlled asymmetric resistive two-terminal circuit is connected in series with the primary winding (Fig. 4), for example, two parallel opposed 45 parallel branches of 11-15 diodes with an unequal number of them in each branch, and control the conductivity bipolar, for which a given number of diodes is shunted in one of the branches with the required 50 frequency, for example, using a transistor chopper-switch (transistors 9 and 10) with gal anicheski decoupled, e.g. optocoupler controlled. 55

For the implementation of measuring operations, means are used (Figs. 1-3), for example, current and voltage measuring sensors, filters and direct current measuring instruments, in addition to current and voltage sensors, in-line and quadrature components are also measured using bandpass filters and measuring amplitude detectors or analyzers tonic harmonics SK4-57, SK4-58. The calculation operation is performed automatically using a computing device that has input analog-to-digital converters (computer lines of the type SM-2, SM-3, SM-4), or manually using a programmable microcalculator Electronics MK-56 ”. .

Claims (1)

The invention relates to the measurement of active resistances of windings of ac electric machines and transformers during normal operation, and is intended to monitor the parameters of machines, as well as their temperature and load modes of operation. The purpose of the invention is to expand the functionality by making it possible to determine the active resistance of the secondary windings. The method of determination is that if the electric machine or transformer is disconnected from the mains, the alternating current flowing through the primary windings forms a small constant component by turning on one of the windings of the controlled asymmetrical resistive two-pole one at a time. component of the variable component of the current with a frequency of multiple current frequency of the mains supply (for example, with a triple, fivefold, n-fold frequency), for which the values oh two-pole conduction. Then, the constant component of the current IQ is measured, and the magnitude of the voltage drop UQ on the windings, due to the flow of this component, is measured by the amplitude U | the voltage harmonics due to the formed variable component of the current measure the amplitudes of the in-phase and quadrature ifi components of the generated current harmonics. The resistance of the primary windings R. and the reduced resistance are calculated from the measured values. R, the secondary windings of an electric machine according to the formulas: R ,. K S. , and n I P1 Ua p - vf- ± 1 °, where K is the coefficient taking into account the switching circuit of the primary windings of the electric machine (for Star windings according to the star circuit, for the star with zero circuit, for the triangle circuit). The values of the formed constant and variable currents 82 are chosen so as to maintain the conditions of the normal operating mode of the electric machine, for example, equal to 1-2% of the amplitude of the supply current. Figures 1-3 show variants of the switching circuits of the primary windings of an electric machine and measuring instruments, figure 4 is a controlled asymmetrical resistive two-pole circuit, figure 5 is a five-element T-shaped circuit for replacing the phase of an electric AC machine and a transformer for the main harmonics of current with frequency; FIG. 6 is a replacement circuit for a constant component of current; FIG. 7 is a circuit of replacing the phase of an electric machine for the 5th harmonic of a current of increased frequency w, nug. The circuit (FIG. 1-3) contains sensor 1 constant gauge Current and amplitudes of the in-phase and quadrature components of the generated current harmonics, sensor 2 measuring the constant component of the voltage and amplitude of the voltage generated by the voltage, controlled by an unbalanced resistive two-terminal 3, the primary windings 4-6 of the electric machine. The controlled asymmetrical resistive two-pole circuit (Fig. 4) contains the control circuit contacts 7 and 8, transistors 9 and 10, diodes 11-15. In the equivalent circuit (FIGS. 5-7), R and Rj are the active resistance of the primary winding and the reduced resistance of the secondary winding of the electric machine, L, L dissipation inductance and reduced dissipation inductance, respectively, of the primary and secondary windings at the fundamental frequency W, Wjjfr, inductive resistance magnetizing circuit. Two basic positions are used. The first position is that the phase replacement circuit of the electric machine for the formed constant component of the t-eye flowing through the winding is the resistance of this winding (Fig.6), which is determined by measuring the amount of direct current Ig and the value of the voltage drop Id, due to the flow of the constant component of the current. The second main principle is that the replacement circuit of the electric machine phase for the nth harmonic of current 1, corresponding to the nth harmonic of the formed belt voltage Ur, with a frequency and a multiple of the voltage of the supply voltage, has the form shown in Fig. 7 (for iJ f-UOy. Therefore, the value of the in-phase (active) component of the n-th harmonic of the current flowing through the primary windings , will be proportional to the total active resistance of this replacement circuit, i.e., which can be determined from the measured amplitude of the nth harmonic of the generated UPI voltage and the amplitudes of the common phase 1 and quadrature I components of the nth harmonic of the current p - yj 1m li li Subtracting from this value the rank of the measured K, get 1 UI Ijij. "К-З Т2 + J2 П," п Un Ini Uo г 1п, I To take into account the branching of the currents, with different circuits for switching on the phase windings of the machine between them (Fig. 1-3), the factor K is entered in (3) - (6) In order to carry out the operation of the simultaneous formation of a constant and a variable component of the current, a control is connected in series with the primary winding to control the 1–1th asymmetrical resistive two-pole device (Fig. 4), for example, two parallel opposite branches of diodes 11–15 with an unequal number of them in each of the branches , and control the conductivity of the two-pole, d shunt in which one of the branches at the desired frequency a predetermined number of diodes, e.g., via Transistor znogo chopper commutator (transistors 9 and 10) with galvanically bound isolator e.g. optocoupler controlled. Means (Figures 1-3), such as current and voltage measuring sensors, filters and measuring instruments of direct current, are used for measuring operations. In addition to current and voltage sensors, measuring bandwidths of the in-phase and quadrature components are also used in measuring amplitudes of the in-phase and quadrature components. amplitude detectors or harmonic analyzers CK-57, CK-58. The calculation operation is performed automatically using a computing device having input analog-digital converters (computer lines of type CM-2, CM-3, CM-4), or manually using a programmable micro calculator Electronics MK-56. . Claim 1. The method for determining the active resistances of the windings of AC electric machines and transforming a jopoB without disconnecting from the supply mains, which consists in forming and measuring the constant component of the current flowing through the primary windings, measures the voltage drop and calculates active resistance of the primary windings according to the formula VK, where K is the coefficient taking into account the scheme of switching on the primary windings of the electric machine, U (, is the magnitude of the voltage drop, 3 is the magnitude of the constant component of the current, I differ from that in order to expand the functionality by enabling the determination of the active resistance of the secondary windings, in the primary windings simultaneously with the constant component and variable component of the current is generated, the frequency of the current harmonic is measured, the amplitude of the in-phase: and quadrature components of the harmonic current harmonics are measured, and the resistance of the secondary voltages is calculated. otok formula, Up hours on January 1 m voltage harmonic amplitude the amplitudes of the in-phase and quadrature components of the current-formed harmonic. 2, the method according to claim 1. 1 which implies that the values of the generated constant and variable components of the current are 1-2% of the amplitude of the supply current. )but- ar but not.5 YU d .rSL TI - TO Kt Rig5 na) oLi} 9 Vus.6 te /