SU957128A1 - Transmission factor determination device - Google Patents

Description

(54) DEVICE FOR DETERMINING COEFFICIENTS

one

The invention relates to a measurement technique and can be used in the power engineering industry during commissioning works on power supply systems for complex objects.

A digital complex transfer coefficient meter is known in which the input of the first integrator is connected to the output of the second integrator, the input of which is connected to an additional automatic switch, the control input of the switch is connected to the output of the control unit, and the signal inputs are one directly, and the other through the inverter is connected to the output full-wave rectifier, the input of which is connected to the output of the quadrupole, with the second amplifier-limiter and through the phase shifter - with the third amplifier-limiting chitelem, wherein the limiting amplifiers outputs are connected to inputs of the control unit and the input of the first limiting amplifier connected to the input terminal of the device.

The disadvantages of this meter are its narrow functionality due to the lack of measuring capability. TRANSMISSION

neither the pulsation coefficient and the low accuracy of the measuring channels, which determine the components of the transmission coefficient.

The closest in technical essence to the invention is a device for determining the transmission coefficient of a quadrupole comprising a control generator, a control object, input and output signal detectors, a control

, (j attenuator, comparator, indicator, pulse driver, scaling circuit, input device, control unit, frequency mark comparator and logic gate.

In the device, the voltage difference between the input and output signals is converted into a time interval, which is converted into a code and indicated by 2.

The disadvantages of this device are narrow functionality, so

jQ as there is no possibility of determining the ripple coefficient characterizing the quality of electric power, and the low accuracy due to the presence of a scaling circuit, an input device and a frequency comparator

tags that give significant errors when converting the difference in voltage in the time interval and code, respectively.

The aim of the invention is to enhance the functionality by determining the ripple factor and improving the accuracy of the device.

This goal is achieved in that the device contains. control object, registration unit, pulse shaper, control unit and logic gate, switching unit, two frequency multipliers, two keys, two voltage-code converters, two quadrs, code transfer unit, two summing counters, reversible counter, two extraction units the root unit, the registration unit and the logometer, the first input of the meter is connected to the output of the test object through a second root extraction unit connected in series, a reversible counter, a second quadrant, a voltage-code converter, a key h, frequency multiplier and pulse shaper, as well as a switching unit; the second input is connected through a second summing serially connected counter, a code transfer unit, a second quadrant and a voltage converter — a code whose output is connected to the second input of a second summing counter; the third input of the logometer is connected to the input of the control object through a series-connected first extraction unit, a root, a summing counter, a quadrant, a voltage-code converter, a key, a frequency multiplier and a driver and the switching unit, the third input of which is connected to the first output of the control unit, the second and third outputs of which are connected to the second inputs of the keys, the fourth to the second inputs of the code transfer unit and the reversible counter, the fifth connected to the outputs of the voltage converters - code through the logic gate, the fourth input of the logometer is connected to the second input of the registration unit and to the fifth output of the control unit, the inputs of which are connected respectively to the outputs of the pulse formers, and the output of the logometer is connected to first entry b of registration.

The drawing shows a block diagram of an apparatus for determining rectifier transmission coefficients.

The device contains a control object 1 (rectifier), a switching unit 2, shapers 3 and 4 pulses when the signal under study passes through zero values, multipliers 5 and 6 pulse frequency, keys 7 and 8, control block 9, converters 10 and 11 voltage - code, logic gate 12, quadrants 13 and 14, transfer code block 15, counting 4HKij 16 and 17, reversible counter 18, square root extractor blocks 19 and 20, logometer 21, registration block 22.

The device works in the modes of determining the transmission and pulsation coefficients of the control object (rectifier).

In p (gzhime transfer ratio calculation, the device operates as follows.

The investigated values of the voltage from the input and output of the control object 1 through the switching unit 2 are fed to the inputs of the formers 3 and 4 and to the second inputs of the converters 10 and 11 directly. The output pulses of the formers 3 and 4 are fed to frequency multipliers 5 and 6, as well as to control block 9, which contains a "reference frequency generator". The control unit 9 opens the keys 7 and 8 for the time of one half period of the voltage under investigation. During the measurement time, keys 7 and 8 pass through the inputs of the transducers 10 and 11 and pass through impulses (n is the multiplication factor of the digital multiplier). These pulses trigger the converters of 10 and 11 instantaneous voltage values to digital codes. The code sequences from the outputs of the manufacturers 10 and I are fed to the inputs of quadrants 13 and 14. The squared codes are used:; the signals under study are summed in counters 17 and 18. During the measurement time they contain codes proportional to half; they are squares of effective values for example wives

After extracting the square root of the obtained voltages, blocks 19 and 20, the codes under study are transferred to the registers of the logometer 21, in which the code proportional to the transmission coefficient of the object is determined.

The calculated coefficient is fed to the input of block 22, where it is registered as a digital code in one of the registers, and is displayed on the light unit of the control block 9 after being decrypted on a light board.

In order to reserve measuring channels, a switching unit 2 is inserted into the device, which connects the input or output of object 1 to one measuring channel in the event that the first or second block sequence fails. This operation is performed at the command of the control unit 9 in the event that pulses from shapers 3 or 4 are stopped at its inputs.

In the mode of measuring the ripple voltage.

The device works as follows.

Claims (2)

The investigated voltage is fed to the input of the former 4 pulses through the switching unit 2. With the arrival of the first pulse of the driver 4 and the input of the control unit 9, it sends a command to close the key 7, which disables the output of the multiplier 5 from the converter 10. At the same time, the output pulses of the driver 4 are fed to the frequency multiplier 6 and the control block 9, which opens the key 8 for the measurement time equal to the period of the investigated signal. The pulses from the output of the multiplier 5 are fed to the input of the converter 11 and start it. Codes from the output of the converter 11 are fed to the inputs of the quadrant 14 and the counter 16. During the measurement time, the counter 16 is summed up by a code proportional to the average voltage value that goes into the cell of the logometer 21 and is fixed in it. At the same time, the quadraised codes 14 are sent to the summation to the reversible counter 18, in which over time the code is formed which is proportional to the square of the effective value of the rectified voltage. At the end of the measurement time, the impulse control unit 9 switches the counter 18 to the subtraction mode and starts the code transfer unit 15. Counter code 16, proportional to the mean voltage value, is input to quadrant 14 and, after squaring, is subtracted from counter code 18. As a result, the input of block 20 receives a code proportional to the square of the current harmonic values of the variable component. After removing the root from the obtained voltage, the required code enters the cell of the gauge 21, and after the division operation, a code is obtained that is proportional to the voltage ripple coefficient. In order to reserve a measuring channel, a logical gate 12 is provided in the device. Thus, over half the period of the signal under investigation, the device calculates the object transfer coefficient in the main mode and in the standby mode for the period. The ripple factor is determined over the period of the voltage being tested. The accuracy of determining these coefficients depends on the number of conversions and the accuracy of the voltage-code converters. In general, the accuracy of the device can be obtained at least 0.1%. Thus, the proposed device is distinguished by higher accuracy and wider functional capabilities due to the measurement of the power quality indicator - the pulsation coefficient. An apparatus for determining transmission coefficients, comprising a control object, a recording unit, a pulse shaper, a control unit and a logic gate, characterized in that, in order to extend the functionality, by determining the ripple factor and improving the accuracy of the device, a switching unit, two multipliers of partbits, a dya key, two voltage converters — a code, two quadrators, a code transfer block, two summing counters, a reversible counter, two extraction blocks root, and ratiometer registration unit, wherein the control object to the output of the first input ratiometer connected via series connected second block extracting roots, reversible counter, second squarer converter voltage - code, a key, a frequency multiplier and a pulse shaper. as well as a switching unit, the second input is connected through a second summing serially connected counter, a code transfer unit, a second quadrant and a voltage converter — a code, the output of the coordinate is connected to the second input of a second summing meter, the third input of the logometer is connected to the input of the control object through serially connected first root extraction block, summing counter, quad, voltage converter - code, key. frequency multiplier and pulse shaper, as well as a switching unit, the third input of which is connected to the first output of the control unit, the second and third outputs of which are connected to the second inputs of keys, the fourth to the second inputs of the code transfer unit and reversible counter, the fifth is connected to the outputs of converters voltage - code through a logic gate, the fourth input of the gauge is connected to the second input of the registration unit and to the fifth output of the control unit, the inputs of which are connected respectively to the outputs of the impregnator lsov, wherein ratiometer output is connected to the first input of the recording unit. Sources of information taken into account during the examination 1. USSR author's certificate No. 516975, cl. G 01 R 27/28, 1975. 2. Avtfskoe certificate of the USSR No. 525898, cl. G 01 R 27/28, 1975.