SU1465853A1 - Apparatus for determining the coefficient of scale-type voltage converter - Google Patents

Abstract

This invention relates to electrical and radio measuring technology. The purpose of the invention is to simplify, increase accuracy and expand the frequency range. Using zero-indicators 3, 4, and 5, the nominal output voltages of each section of the certified scale converter are compared with the output voltage of the transformer driver 6 of the reference voltage with the same nominal value. Using the compensating voltage formers 7, 8, and 9, the readings of the zero-indicators 3, 4, and 5 are adjusted to zero. The presence of equipotential: screens excludes the leakage currents from the measuring circuits and the error component associated with them. 1 Il.

Description

The invention relates to electrical and radio metering technology and can be used to determine the scale factor of high-precision voltage scale converters in the frequency range when certifying measuring voltage transformers, voltage dividers. And other high-precision measuring means.,

The purpose of the invention is to increase the accuracy and expansion of the frequency range when determining the scale converter factor and simplify the device.

The drawing shows a functional diagram of the device.

The device contains sockets for connecting certified voltage converter (AMP) 1 voltage, auxiliary scale converter (PMF) 2 voltage, zero-indicators (NO) 3-5, transformer driver voltage 6 reference voltage (TFON) and drivers 7- 9 compensating strain (FKN). The inputs of the certified and auxiliary scale converters 1 and 2 are connected, their first codes are connected to the common bus, to which the output of the first generator 7 of the compensating voltage is connected, and the second output of the certified scale converter 1 voltage through the zero. The second driver 8 of the compensating voltage is connected to the second output of the auxiliary oil-voltage converter 2, the third output of which through the third driver 9 of the compensating voltage and zero indicator 5 oedinen third output transducer 1 Appraisee scale voltage. The first output of the output winding of the transformer driver 6 of the reference voltage through the zero indicator 3 is connected to the outputs of the zero indicator 4 and the second driver -8 of the compensating voltage so that the screens of the zero indicator 3 and 4 and their connecting conductors, as well as and screens of conductors connecting the second output of the scaleable converter 1 being certified with the null indicator 4 and the null indicator 3 with the first output of the output winding of the transformer driver 6 of the reference voltage, are connected to the output of the second form Ate 8 compensating 5 voltages and null indicators 3 and 4, the second output of the output winding of the transformer driver 6 of the reference voltage is connected to the null indicator 5 and the third O former of the compensating voltage generator 9 so that the screen of the null indicator 5 and screens of conductors connecting with it the third output of the certified large-scale converter 1, s the second output of the output winding of the transformer driver 6 of the reference voltage and the third driver 9 of the compensating voltage, are connected to the output of the third form peacemaker 9 of the compensating voltage, to which the zero indicator 5 and the second output of the output winding of the transformer driver 6 of the reference voltage are connected, the screen of which 5 is connected to the screens of the zero-indicators 3 and 5, Second input of the winding of the transformer driver 6 of the reference voltage It is connected to the inputs of the certified and auxiliary scale converters 1 and 2, and the first input through the first driver 7 of the compensating voltage is connected to the common bus, to which the screen of this winding is also connected.

- The device works as follows.

 The compensating voltage formers 7-9 provide the variation of the voltage vector g in amplitude and phase. Inputs NI4 and NI5 are connected to one of the AMG11 sections, for example, to its outputs second and third, and the inputs of FKN8 and FKN9 to the same 5 outputs of VMP2. With the help of FKN7, FKN8 and FKN9, zero readings of NI 3, NI 4 and N 5 are achieved. which corresponds to the equality of the output voltage TFON6 voltage on the AMP section 1, located between the second and third outputs. Then, at a constant voltage supply of the entire device and the voltage on the FKN 7, the inputs NI 4 and NI 5 are sequentially connected to the outputs of each section of the AMP 1, and the inputs of the FKN 8 and FKN 9 to the similar outputs of the VMP 2, With the help of the FKN 8 and FKN 9 achieve zero readings of NI 4 and NI 5, and according to NI indications 3 determine the differences

five

0

five

the output voltages on the AMP I sections by the values of which judge the AMP 1 error. Capacities per e-capacitance between the elements and leakage resistors, which usually affect the measurement accuracy, in this case are the load of PCF 8, PCF 9 and VMP 2, and APM 2 at zero readings of NI 4 and NI 5 operate in idle mode. The measuring circuit (NI 5, NI 4, NI 3, TFON 6 output winding and conductors connecting them to each other and AMP outputs) is enclosed in equipotential shields, which excludes leakage currents from the measuring circuit and the error component associated with them , The most accurate methods for independent certification of scale converters, i.e., e, without using samples of scale converters, are methods based on measurements of the ratio of compared voltages. These methods are most suitable for certification of equidistant large-scale converters. The essence of them is that the nominally equal voltages of each section are compared with one voltage with the same nominal value. Comparing two voltages of similar amplitude and phase using voltage comparators makes it possible to determine the errors of the dividers with an accuracy of the order of 0.01-0.001%. Creating voltage comparators with higher accuracy (0.0001-0.00001%) is a very complex task. This is due to the fact that the comparator itself must have measuring elements (amplifiers, transducers, etc.), which are characterized by appropriate accuracy.

These distinctive features allow to increase the accuracy of the device, especially when it is operating in the frequency range, where the influence of the parasitic currents on the certification level is most pronounced. The use of the invention makes it possible to certify the means of measuring the stresses of highest accuracy in a wide range of frequencies and with the necessary accuracy.

Claims (1)

Formula invented and Device for determining the scale converter factor voltages containing three null inikator in equipotential screens connected by inputs certified and auxiliary scale voltage converters, the first outputs of which are connected to the common bus to which the output of the first compensating voltage generator is connected, and the second output of the certified scale voltage converter through the second zero-indicator and the second compensating voltage driver connected to the second output auxiliary scale voltage converter, the third output of which is connected to the third through the third compensating voltage driver and the third zero-indicator attested scale voltage converter, characterized in that, in order to simplify, increase, accuracy and extend the frequency range, transformer of the reference voltage with equipotential screens input and output windings, the first output of which through the first null indicator is connected to the input of the second compensating voltage generator, the second output of the output voltage of the transformer voltage reference transformer is connected to the input of the third the compensating voltage driver, the second input winding of the transformer reference voltage driver is connected to the input voltage. ladies certified and auxiliary large voltage converters, and the first input is connected to the input of the first compensating voltage driver, while the equipotential screen, which encloses the third null indicator, the output winding of the transformer reference voltage driver and the measuring circuit connecting the third output of the attested scale voltage converter and the input of the third compensating voltage driver are connected to the input of the last, equipotential screen, which encloses the first and second zero Indicators and measuring circuit between the second output of the certified scale voltage converter and the first output of the output winding. Transformer form driver 5U658536 The horo voltage {I, is connected to the input, the input winding screen of the second transformer is used to compensate for the go-driver of the reference voltage, and the equipotential voltage is connected to the common bus.