CS274403B2 - Connection of asynchronous motors' and direct-current voltage transformers' winding resistance measuring conver in operation - Google Patents

Description

The invention relates to the connection of an in-line DC resistance measuring transducer of an asynchronous motor and a transformer in operation, comprising a serial DC power source comprised of a DC power source bridged by a load resistor.

The DC / DC winding transducer is needed to test asynchronous motors and transformers in research in electrical laboratories and to optimize the interaction of induction motors with rectifiers as well as to check the winding temperature of asynchronous motors and transformers in operation.

According to the recommendations of the International Electrotechnical Commission, all known connections for measuring the winding resistance of AC electrical equipment under operating voltage are based on the principle of two measurement methods, namely the volt-ammeter method, called the technical method, and the bridge method.

Circuits based on the technical measuring method allow calculation of the winding resistance value to be measured according to the voltmeter or millivoltmeter and ammeter or milliamperimeter data.

Similarly, the bridge method circuitry allows direct reading of the winding resistance measurement result, but not when the bridge is manually leveled.

The disadvantages of the previously known circuits based on the two methods are that they do not give a continuous result of the winding resistance measurement and are therefore not suitable for analogue processing of the winding resistance into a DC signal for the test equipment under voltage.

The most commonly used bridge method, as well as those published in IEC. 279, is a circuit according to Polish patent specification no.

719 of 1959. Improvements have been made in the country in the following years and patents 50 129, 59 024, 83 681 have been granted in Poland,

186 and 95 407. The connections of these patents are intended for the occasional measurement of the resistance of the windings of AC electrical machines and transformers during operation. They are measuring circuits that operate on the principle of using the Thomason bridge and according to the superposition method, in which direct current is introduced into the alternating current working circuit.

The disadvantage of these circuits is that they are not suitable for continuous measurement of winding resistance and less so for converting this resistance into voltage or direct current. In addition, this wiring cannot be used especially if the device under test is a three-phase induction motor or a star-connected transformer without access to the zero point. There is a great difficulty here in adapting these wiring to high power electrical devices, since it is necessary to connect the DC power supply to the AC operating voltage in parallel.

It is known to solve this problem by replacing the parallel DC power supply with a serial power supply. Here, a series DC current source resistor is formed, which is connected in series to the working current line and on which, in addition to the AC voltage drop, a DC voltage drop also occurs from the full-wave rectifier mains supply line.

The disadvantage of this solution, however, is that such a supply line does not solve the problem of the considerable amount of direct current required to determine the winding resistance of large electrical devices.

The latest winding resistance measuring device is a device consisting of a 2227 digital microohmmeter, a 5257 power supply line, and a 5910 type measuring adapter. This device, known since 1977, 3 is used to quickly measure the winding resistance of transformers without operating voltage. This device is working

CS 274 403 B2 by numerically realizing the ratio of two DC voltages, that is, one voltage proportional to the voltage drop of the measured winding and the other voltage proportional to the direct current flowing through the measured winding, whereupon the resistance value of the measured winding is indicated numerically. .

The disadvantage of this device is that it cannot be used to measure the winding resistance of transformers under operating voltage, that is, in the operating state.

Finally, a measuring transducer for measuring the resistance of an operating voltage-supplied electric circuit is known according to Polish patent No. 100,552. This transducer processes the resulting resistance of the AC circuit to a DC voltage, which in the case of an induction motor or transformer is the sum of the winding resistance and the active iron losses.

The disadvantage of this known device, however, is that it cannot be used to measure and control the winding resistance of the motor and transformer and the subsequent possible measurement and temperature control of the winding.

The above-mentioned disadvantages of the prior art are largely eliminated by the wiring of a resistance converter of the windings of asynchronous motors and transformers to DC voltage during operation, consisting of a serial DC power supply consisting of a DC power supply bridged by a load resistor. and the load resistor is coupled via the burner resistor to the third input terminal of the device under test and to the third input terminal of the artificial zero circuit, the shunt resistor terminals being individually connected to the second input terminals of the analog DC converter. cascaded three-pole switch connected to the first to third input terminal of the tested device, where the analog The DC input consists of the first low-pass filter connected by its input terminals to the first input terminals of the analogue DC 2-inverter and its output terminals through the first DC amplifier to the input terminals of the first galvanic isolation circuit. and with an input of a first limit signaling circuit, and a second output terminal of which is coupled to the output terminals of the first limit signaling circuit and the second limit signaling circuit, to a second output terminal of the analog splitter circuit of the analogue separation converter connected to its first output terminal with the input terminal of the second limit signaling circuit and with the second input terminal of the anologic split circuit and its input terminals through the second DC amplifier with output terminals and a second low-pass filter, the input terminals of which are the second input terminals of the two-voltage anologue converter, the first output terminal of the analog splitter circuit being the first output terminal of the two-voltage analog converter.

The advantage of such a solution to connect the winding resistance converter of asynchronous motors and transformers to DC voltage in operation is that it continuously processes the winding resistance of electrical equipment of any rated power and over a large frequency range of operating voltages and allows manual, e.g. remotely switching the range of resistance change without interruption or interference in the AC and DC auxiliary circuits. Furthermore, the measuring transducer according to the invention makes it possible to interconnect an AC circuit with a DC easily, without interfering with these circuits, and makes it possible to easily filter out significant AC components from small DC voltages.

The invention is illustrated by way of example in the drawings, in which: FIG

CS 274 403 B2 is a block diagram of a winding resistance converter common to a three-phase device to be measured, and FIG. 2 shows a bias voltage circuit.

Fig. 1 shows a block diagram of a winding resistance measuring transducer according to the invention, consisting of a two-phase DC voltage converter, to whose first input terminals a three-pole switch 3 is connected via an artificial zero circuit 2 and whose second input terminals are bridged by a shunt resistor 4 and connected in series to a parallel circuit connected to the second shunt resistor 4 and consisting of a serial DC power supply 5 and a load resistor 6. The three-pole switch 2 is further coupled to the first and second input terminals of the device 7, the terminal of the test device 7 is connected to the third terminal of the artificial zero circuit 2 and with the first terminal of the shunt resistors χ. The DC power converter χ consists of the first low-pass filter 8, the input terminals of which are the first input terminals of the DC power converter χ, and whose output is connected via the first DC amplifier 12 to the input terminals of the first galvanic isolation circuit 10 which the first output terminal is. connected to the first input of the analog splitter circuit 14 and to the input of the first limit signaling circuit 15. The second output terminal of the first galvanic isolation circuit 10 is coupled to the output terminals of the first overcurrent signaling circuit 15 and the second overcurrent signaling circuit 16, to the second output terminal of the analog two-phase AC voltage divider 14 and the second galvanic isolation circuit 11. it is connected by its first output terminal to the input terminal of the second limit signaling circuit 16 and to the second input terminal of the analog dividing circuit 14. The second input terminals of the analog DC power converter χ are connected to the input terminals of the second lowpass filter 9 which is over the second DC the amplifier 13 is connected to the input terminals of the second galvanic isolation circuit 11. The first output terminal of the analog splitter circuit 14 is the first output terminal of the analog converter χ of the two DC voltages.

FIG. 2 shows the first or second limit signaling circuit 15 or 16, the input of which is connected to a resistive reference voltage divider formed by the series connection of the first resistors 17 and the second resistors 18. The first resistor 17 is connected between the inverting input of the first operational amplifier. 19 and the non-inverting input of the second operational amplifier 20. The non-inverting input of the first operational amplifier 19 and the inverting input of the second operational amplifier 20 are connected to each other and form an input terminal of the wiring. The output of the first operational amplifier 19 is coupled to the anode of the first rectifier diode 21, the cathode of which is connected to the cathode of the first diode 22, the cathode of which is connected to the cathode of the second rectifier diode 23 and the first coil terminal of the first relay 24. connected to the anode of the third rectifier diode 25, the cathode of which is connected to the anode of the second light-emitting diode 26, connected by its cathode to the cathode of the fourth rectifier diode 27 and to the first coil terminal of the second relay 28; , and the anode of the second rectifier diode 23 and the anode of the fourth rectifier diode 27. The first input circuit of the winding resistance measuring transducer, consisting of an artificial zero circuit 2 and a three-pole switch 3, is a voltage circuit and circuit 2 of artificial zero, with called the input of the reader. The second input circuit of the winding resistance measuring transducer, consisting of a shunt resistor 4 and a load resistor 6, to which a serial DC power supply 5 is connected in parallel and, in an exemplary embodiment a three-phase AC six-wave rectifier. The two DC voltages to which this input circuit is connected is called the denominator input.

CS 274 403 B2

The operation of the circuit according to the invention will now be described.

The DC voltage generated at the output of the analog splitting circuit 14 is the output voltage of the winding resistance measuring converter 1. The value of this voltage is proportional to the value of the winding resistance of the measured device 7, which is below the three-phase operating voltage, during the operation of the measuring converter.

The contacts of the first and second relays 24 and 28 form two independent external circuits, which are used for remote signaling of exceeding the input voltage level. Local indication of the value of this voltage is performed by observing the illumination of the first and second LEDs 22 and 26. When the input voltage drops below the minimum received value, the second LED 26 is lit and the contact of the second relay 28 is closed. On the other hand, as the input voltage rises above the upper received limit, the first LED 22 is lit and the contact of the first relay 24 is closed. If the input voltage is between the low and high limits, the first and second LEDs 22 and 26 are off and the contacts of the first and second relays 24 and 28 are open. The upper limit value is limited by the reference voltage and the lower limit depends on the resistance ratio of the first resistors 17 and the second resistors 18. The first and third rectifier diodes -21 and 25 protect the first and second LEDs 22 and 26 against polarity reversal polarity and the second and fourth diodes 23 and 27 limit the overvoltages generated on the coils of the first and second relays 24 and 28.

After the test device 7 is connected and the AC voltage supplying the test device 7 is connected, the direct current flowing from the direct current source 5 is connected to the AC operating current. The main part of this DC current flows only through the load resistor 6 and a small portion of the DC current flows through the shunt resistor 4 and the windings of the test device 7. A mixed voltage having two components, that is AC and DC components,

7, is connected to the first filter by means of an artificial zero circuit 2 and a three-pole switch 3

8. The three-pole switch 3 is depressed if the three-phase test device 7 is internally connected to a star and the three-pole switch 3 is pulled out if the test device 7 is delta-connected. Analogously, a mixed voltage which comprises two components, namely AC and DC, and which is on the shunt resistors 4, applies to the second low-pass filter 9.

The first and second low pass filters 8 and 9 filter out the alternating components of both voltages. The output DC voltage of the first low pass filter 8, after amplification by the first DC amplifier 12, is applied to the input of the first galvanic isolation circuit 10. Analogously, a DC voltage from the second low-pass filter 9 is applied after amplification by means of a second DC amplifier 13 to the input of the second circuit 11 of the galvanic isolation. Both the first and second galvanic isolation circuits 10 and 11 serve as decoupling amplifiers whose output voltages have a common pole. The output voltage of the first and second galvanic isolation circuits 10 and 11 is applied to an analog splitter circuit 14 which divides the first voltage by the second voltage. The result of this separation is at the output of the analog separation circuit 14 a direct voltage of a value which is directly proportional to the winding resistance of the device under test 7.

The winding resistance converter of the induction motors and transformers during operation in the circuit according to the invention is intended to process the value of the winding resistance of single-phase and three-phase devices of nominal power from the smallest values, e.g. fraction watts to about 5 MW. Hz, this is when such devices are powered from AC drives.

Thanks to the electrical switching of the resistance change range and the remote signal overvoltage measurement technology of the measuring signals, this measuring converter can cooperate with mini-computer systems.

CS 274 403 B2

Asynchronous motors and transformers tested by means of a measuring transducer according to the invention can be connected in a closed open triangle or star connection with an inaccessible zero throw accessible.

Claims (1)

Connection of an in-line DC resistance measuring transducer of the induction motors and transformers, consisting of a series direct current source consisting of a DC source bridged by a load resistor, characterized in that the parallel connection of the DC source (5) and the load resistors (6) is through the burner resistor (4) connected to the third input terminal of the test device (7) and to the third input terminal of the artificial zero circuit (2), the terminals of the burner resistor (4) being individually connected to the second input terminals of the analogue converter (1) the second input terminals of which are connected to the first to third input terminals of the tested device (7) via an artificial zero circuit (2) and cascaded three-pole switch (3) connected to it, the analogue converter (1) of the Compressed by the first low-pass filter (8), connected by its input terminals to the first input terminals of the analogue DC inverter (1) and its output terminals through the first DC amplifier (12) to the input terminals of the first galvanic isolation circuit. the terminal is connected to the first input of the analog splitter circuit (14) and the input of the first limit signaling circuit (15), the second output terminal of the first galvanic isolation circuit (10) being connected to the output terminals of the first limit signaling circuit (15) and the second an over-limit signaling circuit (16) with a second output terminal of the analog splitter circuit (14), an analog two-voltage ratio converter (1), and a second galvanic isolation circuit (11) which is connected by its first output terminal to the input terminal of the second circuit ( 16) signaling of exceeding of limits and with a second input terminal of the analogue divider circuit (14) and its input terminals through a second DC amplifier (13) with output terminals of the second low-pass filter (9), the input terminals of which are the second input terminals of the analog the first output terminal of the analog splitter circuit (14) is the first output terminal of the analog two-phase voltage converter (1).