SU1578516A1 - Method and apparatus for measuring temperature of electric motor of electric motor winding - Google Patents

Abstract

The invention relates to temperature measurements and allows an increase in the accuracy of temperature measurements in transient conditions. With a rapid voltage change, the current in the machine winding lags behind the voltage due to the electromagnetic inertia of the winding. To compensate for the lag, the voltage signal is temporarily shifted by a time interval inversely proportional to the resistance of the winding, which is determined by dividing the voltage value on the winding by the current value in the winding. Signals from the output of block 1 of forming a current signal in the winding and from the output of block 3 of a time voltage shift, the control input of which receives a signal from the output of block 4, proportional to the resistance of the winding, are fed to the input of the winding resistance forming unit 4. 2 sec. f-ly, 1 ill.

Description

'The invention relates to temperature measurements, in particular the temperature measurement of the winding of an electric machine.

The purpose of the invention is to improve the accuracy of measuring the temperature of the winding of an electric machine in transition mode.

The essence of the method for measuring the temperature j of the winding of an electric machine is as follows.

The temperature of the winding is determined by the resistance of the winding. To determine the resistance of the winding, measure the amount of current flowing through the winding and the voltage drop across the winding. The resistance of the winding is determined by dividing the voltage value by the current value. At fast; change in voltage across the winding The current in the winding lags behind the voltage due to the electromagnetic inertia of the winding, which is inversely proportional to the resistance of the winding. In order to.-/; To compensate for this lag, they produce a temporary shift of the voltage signal by a time interval proportional to the electromagnetic constant of the winding. Since the electromagnetic constant of the winding changes when the resistance of the winding changes, during the temperature measurement, changes in the time interval of the voltage shift are inversely proportional to the change in the resistance operational amplifier 11 with a resistor 12 in the feedback circuit and input resistors 14 and 15 and a voltage divider 16 connected to the source power supply (not shown).

The block of the time shift of the voltage signal can be implemented by an inertial (aperiodic) link with an adjustable time constant. The basis of such a link is, for example, an integrating amplifier 17 with an input resistor 18, in which a resistor 20 with a resistance of 'R _{2 is} connected in parallel with the capacitor 19 in the feedback circuit. The time constant of such a link is equal to T = R ₂ C, where C is the capacitance of the capacitor 19.

In order to be able to change the time constant of this link, the multiplication block 21 is switched on sequentially by J2,> and the signal r proportional to the current value of the winding resistance is supplied to the second input of this block. The time constant of the inertial link, consisting of an integrating amplifier and a multiplication unit, varies proportionally to R ^ C / r.

The method is as follows.

The parameters A and C are chosen such that, at a nominal value of r, the value of T is equal to the value of the electromagnetic constant of the winding at the memorial (initial) temperature of the winding.

The drawing shows a block diagram of a device for implementing the proposed method.

The device comprises a current signal generating unit 1 in a winding, a voltage signal generating unit 2, on a winding, a voltage signal temporary shifting unit 3, a winding resistance signal generating unit 4 and a winding temperature signal generating unit 5 ..

The current signal generating unit 1 in the winding comprises a shunt 7 connected in series with the winding 6 of the machine and an amplifier 8 with galvanic isolation.

The voltage signal generating unit 2 on the winding comprises a voltage divider 9 and a constant current amplifier ³³ U with galvanic isolation.

The winding temperature signal generating unit 5 contains a summing

TN.

With a change in the resistance of the winding caused by a change in its temperature, the time constant of such a link will change inversely with the resistance of the winding, i.e. T = TN / r.

Claims (2)

Claim 1. The method of measuring the temperature of the winding of an electric machine, which consists in measuring the magnitude of the current flowing through the winding and the voltage drop across the winding, compensating for the current delay relative to voltage by temporarily shifting the voltage signal by a time interval inversely proportional to the winding time constant, determining the resistance winding, proportional to the value of the temperature of the winding, by dividing the voltage value by the current value 1578516, characterized in that, in order to improve the measurement accuracy in transient mode, in the process of measuring temperature, the magnitude of the time shift is changed inversely with the change in the active resistance of the winding. 2. A device for measuring the temperature of the winding of an electric machine, comprising a current measuring unit, a voltage measuring unit on the winding, the output of which is connected to the input of the time-shift unit, a winding resistance determination unit, the first input of which is connected to the output of the time-shift unit, the second input is connected to the output a current measurement unit, and the output is connected to a winding temperature signal generating unit, characterized in that, in order to increase the measurement accuracy in transient mode, the control input of the temporary the wig is connected to the output of the winding resistance determination unit.