SU957184A1 - Three-phase circuit quality parameter calibrator - Google Patents

Description

(54) CALIBRATOR QUALITY PARAMETERS

THREE PHASE CHAIN

Claims (2)

The invention relates to electrical engineering and can be used to create exemplary sources of quality parameters of a three-phase circuit (voltage deviation and fluctuation, weights, neutral neutrality, non-sinusoidal): the individual quality parameters and measuring-computing complexes required as a means for checking measuring instruments complex definition of the mentioned parameters. A three-phase parameter calibrator is known that contains a single-phase voltage converter from an autonomous source to a three-phase one and is carried out using various transducers of the number of phases ij. The disadvantage of this device is low accuracy. Closest to the proposed one is a calibrator containing a single phase voltage converter in three phase with a neutral wire, adjustable in a phase converter in two phases, an alternating voltage regulator with a change in transmission coefficients and an output rotator in each phase, as well as a symmetry indication circuit, including an adder, a selective amplifier, and an irdikator 2. The disadvantages of the known device are low accuracy, caused by pickups and power supply voltage, voltage instability of the phase converter of single-phase voltage to three-phase, nonlinearity of characteristics of said converter, adder, amplifier and other analog devices included in the calibrator, instability of analog devices and their elements, low precision manual adjusting phase shifters and setting transfer rates for tepees, as well as low productivity, due to the need for manual adjustments and the inability to back All quality parameters such as voltage & tension, non-sinusoidal. The purpose of the invention is to increase the accuracy of setting the parameters of the three phase circuit and expanding the functionality. The goal is achieved by introducing a trigger trigger, a control unit, a rectangular Toutuls generator, a logic element, a phase counter, a sampling clock, a divider clock into the three-phase circuit quality parameter calibrator. goths, counting values, a quality parameter counter, a permanent storage node, a phase decoder, buffer registers and digital-to-analog converters according to the number of phases, the trigger trigger is connected to the output unit and the first input of the logic element, the second input of which is connected to the generator output pulses, the output is logical. element is connected to the gate input of the phase decoder and to the counting input of the phase counter, the overflow output of which is connected to the counting input of the sampling counter, the overflow output of the counting meter is connected to the counting input of the value indicator, through a frequency divider, the overflow output of the counting value is connected to the counting input of the counter parameters, the zero inputs of the counters, the frequency divider, the buffer registers are connected to the output of the control unit, the inputs of the parallel enrollment and the output Blocks of the counter of the frequency divider, the value counter, the parameter counter are connected to the corresponding outputs of the control unit, the parallel outputs of the phase counters, the sampling of values and parameters are connected to the address inputs of the permanent storage node, the outputs of which are connected to the information inputs of the buffer registers, for each phase clock inputs-buffer registers are connected with the corresponding. outputs of the phase decoder, the inputs of the latter. with parallel outputs of the phase counter, the outputs of the buffer registers for each phase are connected to the inputs of digital-to-digital converters, the outputs of which are connected to the inputs of output transformers. In drawing PJ), a block diagram of a quality parameters calibrator is provided in a three-phase system. The input bus Reset is connected to the control unit 1 and to the installation input of Of trigger 2, the installation input of which 1 is connected to the Start bus. The output of trigger 2 is connected to the control unit and to the first input of logic element 3, the second input of logic element 3 is connected to the generator 4 output of rectangular pulses, and its output is gated to the input of the decoder 5 phases and to the counting input of the phase counter 6. The parallel outputs of the phase counter 6 are connected to the corresponding inputs of the phase decoder 5 and the younger part of the address input of the permanent storage node 7, and the overflow output of the phase counter 6 is connected to the counting input of the sampling counter 8. The overflow output of the sampling counter 8 is connected to the input of the frequency divider 9, the output of which is connected to the counting INPUT of the counter 10 quality parameter values, the overflow output of the 10 value counter is connected, in turn, to the counting input of the counter 11 parameters. The parallel outputs of counters 8, 1О and 11 are connected, respectively, to the higher part of the address input of node 1) whose outputs (for comparison readings are shown conventionally with one bus) are connected to information inputs of buffer registers 12, 13 and 14 (12 is intended for storing values of phase A in binary code, 13 phase B and 14 phase C), the clock inputs of which are connected to the corresponding outputs of the decoder 5 phases. The outputs of the buffer registers 12, 13 and 14 are connected for each phase with digital to analogue converters 15, 16 and 17, the outputs of which, in turn, are connected to the corresponding inputs of the output transformers 18, 19 and 2O. The outputs of transformers 18, 19 and 2O are measured for quality in the form of a three-phase voltage system. Vx: odes of installation in O counters 6, 8, 1O and 11 of the divider 9 and buffer registers 12, 13 and 14 are connected via bus 21 to the control unit 1. The parallel input inputs and the blocking inputs of the account are connected to the outputs of the control block 1, respectively, via buses: 22 and 23 for counters 11, 24 and 25 parameters for counters 1O, 26 and 27 values for counter 8 discretization. Consider the operation of the quality parameter calibrator as a source of calibrated values of voltage for the corresponding measuring instruments. The bus Reset is given a signal that sets the main calibrator nodes to their original positions, including counters 6, 8, 10, 11, divider 9, and buffer registers 12, 13, and 14. The control unit of block 1 dials the parameter codes, voltage deviations and its values, which are entered on buses 24 and 22, respectively, into a 10 value counter, and into the counter 11 parameters, which determine, in turn, the array address of the node G where are stored with binary codes of voltage deviation values for each phase. At the same time, the network inputs, the counter of 10 values and the counter of 11 parameters are blocked by block 1 via buses 25 and 23. Then, a start signal is given to the bus that sets trigger 2 in one state, which makes it possible to pass generator 4 pulses through logic element 3 to the counting input of the counter 6 phases and the gate input of the decoder 5 phases. A phase 6 counter for three states at the first moment of time forms the first address of the node 7. By which the binary code of the first value of the voltage deviation of phase A is stored. This code is entered in the buffer register. 12, under the action of a pulse T mpulse, formed by a phase decoder 5, is transformed by a converter 15, and at the output of the transformer 18 has the value of phase voltage A. At the second moment of time, from the node 7, the code of the voltage deviation of the phase B is selected, entered into the buffer register 13 and fed through the converter 16 and the transformer 19 to the output. Similarly, the first sampling of the voltage deviation of the phase C is formed. The overflow impulse of the phase counter 6 sets the first counter to the 8 position of the sampler, which is maintained for the third time when the second deviation values are sampled for phases A, B, and C. The counter 8 - has N stable states and determines the sampling frequency of the period ig 50-3 N. Thus, in a time equal to 3N cycles, from the node, N voltage codes will be selected for each phase. A three-phase system of voltages with a duration of one period will be formed at the output of the calibrator. This voltage system is different from the nominal one in accordance with the codes of samples stored in node 7. In the absence of a pulse Reset, the calibrator continuously forms a three-phase voltage system with a predetermined deviation. To switch to another deviation value, it is necessary to add 10 different values to the invoice of the ir value of the previous code, which allows counters 6 and 8 of the sample from another array of node 7. Transition to another deviation value can be done automatically by unblocking the counting counter 10 via bus 25. Then the calibrator will form a three-phase system of voltages for a number of periods, where n is the divider division factor of 9, then with the help of counter 1О. Voltage drops to another deviation value, etc. The calibrator operates as a source of calibrated oscillation values, the voltage is different from the deviation driver, because in this case it is provided by divider 9, controlled by unit 1, the required rate of voltage variation in accordance with requirements of GOST 1310 9-67. The operation of the calibrator as a source of calibrated non-sinusoidal values does not practically differ from its operation as a source of voltage deviations. In this case, from node 7, codes are selected whose values consist not only of the first harmonics, but also contain one or a certain number of higher harmonics. It should be borne in mind that for non-sinusoidal meters with a digital form of processing, the number of discrete values into which the stress period is broken must be at least 2 times larger (in accordance with the Kotelnikov theorem) than the number of the highest harmonic involved in the formation non-sinusoidal. When forming other quality parameters, such as asymmetry, neutral displacement, the calibrator works in the same way. Let us consider the work of the calibrator of quality parameters of a three-phase system for the calibration of measuring and computing complexes that carry out a complex determination of parameters. In this case, the calibrator automatically forms at its output a three-phase voltage system with successively variable quality parameters and their values. Block 1 unlocks the counting inputs of all counters. In this case, the counter 6 and 8 provides the formation of a three-phase system of one parameter and one of its value during the periods, thanks to D9 on the I. Upon the expiration of the time n-i (where t is the period duration), the value counter forms new node addresses 7, thereby ensuring the Ш value of this parameter (W is the counting coefficient of the counter 10). The value overflow impulse of the value counter & niy will trigger the counter C, the parallel outputs of which will form the addresses of the arrays of node 7, where codes for other quality parameters and their values are stored. In addition, the sampling of one or another parameter and its value can be carried out at the initiative of the measuring and computing complex of control signals fed to the control unit 1. . The use of basic digital nodes according to the proposed block diagram allows one to switch on pickups, pulsations, nonlinearity of elements, etc., which in turn makes it possible to increase the accuracy of the calibrator. The elimination of manual adjustments allows a significant increase in labor productivity. when checking and setting up instruments and complexes for determining the quality parameters of electrical energy of three-phase circuits. In addition, a quality parameter calibrator extends the functional wave. the capabilities of the well-known calibrator in terms of the possibility of setting oscillations, stress and non-sinusoidality. The invention The calibrator of the quality parameters of a three-phase circuit, containing output transformers in phases, is also distinguished by the fact that, in order to increase the accuracy of setting the parameters of a three-phase circuit and expand its functional. capabilities, a trigger trigger, a control unit, a square pulse generator, a logic element, a phase counter, a sampling counter, a frequency divider, a value counter, a quality parameter counter, a fixed memory node, a phase decryptor, buffer registers, and digital-analogue converters by number phases, with the start trigger connected to the control unit with the first input (Z1 of the logic element, the second input of which is connected to the No. 1 generator of square-wave pulses, the output of the logic element connected with the strobe The input of the phase decoder and the counting input of the phase counter, the overflow output of which is connected to the counting one, the input of the sampling counter, the output of the overflow sampling are connected to the counting input of the counter of quality indicator values via a frequency divider, the overflow output of the value counter is connected to the counting input of the parameter counter, installation inputs zero counters, a frequency divider, buffer registers are connected to the output of the control unit & laziness, the parallel input inputs and the blocking outputs of the counter divider values, the parameter counter are connected to the corresponding outputs of the control unit, the parallel outputs of the phase counters, the sampling of values and parameters are connected to the address inputs of the permanent storage node, the outputs of which are connected to the information inputs of the buffer registers, for each phase the clock inputs of the buffer registers are connected to the corresponding outputs of the phase decoder, the inputs of the latter with parallel outputs of the phase counter, the outputs of the buffer registers for each phase are connected to the input and digital to analog converters, the outputs of which are connected to the output transformers shsodam. Sources of information taken into consideration. During the examination 1.Adamenko A.I. and Kislenko V.I. Transformation of a single-phase current into a multiphase, Kiev, Tekhnika, 1971p. 87-100 2. USSR author's certificate for application number 2651852/07, cl. G 05 F 1/44, 1978. 1-A- ..