RU100633U1 - DEVICE FOR TESTING SINGLE-PHASE MEASUREMENTS OF ELECTRIC POWER AND ENERGY - Google Patents

Abstract

 A device for checking single-phase electric power and energy measuring instruments, comprising a “dummy” power source, a reference meter, a voltage transformer including one primary winding and several secondary windings, the voltage channel output of the “dummy” power source is connected to the transformer primary winding, the output of each secondary winding a voltage transformer is connected to a parallel circuit of each verified instrument, the output of the current channel of the source of "fictitious" power is connected to Flax reference meter circuit and connected to the series connected sequential circuits calibrated measuring means, characterized in that additionally introduced a switch control output of which is connected to any of the secondary windings of the transformer, the parallel circuit a reference counter connected to the control output.

Description

The inventive device relates to the field of measurement technology and is intended for use in group verification of single-phase means of measuring electric power and energy, which have a galvanic connection between parallel and serial circuits. Such measuring instruments include, for example, single-phase electric energy meters, hereinafter referred to as the midrange, whose current sensor is based on a shunt.

Group verification of single-phase measuring instruments for electric power and energy of any kind is carried out at calibration facilities by comparison with a reference device. For verification of the midrange, for example, a reference counter is used. During verification, isolated voltage and current signals from the source of “fictitious” power are supplied to the inputs of the devices under test, and then the source. Moreover, in the case of verification of the midrange, errors additionally arise due to two reasons. The first reason is that through the serial MF circuits that are connected closer to the source, the consumption current of those MFs that are connected further from the source flows. The second reason is that when the source current flows through successive midrange circuits, a voltage drop occurs on them. In this case, the reference meter controls the power determined by the output voltage and the output current of the source. It is possible to control the power when connecting the reference meter to other places in the voltage and current circuits of the calibration setup, but, fundamentally, this does not change the situation. Due to these two reasons, an error is introduced into the results of determining the errors of the midrange. The exclusion of this error can be achieved by compensating for the flowing currents of the midrange consumption and compensating for the voltage drops on their serial circuits or by galvanically isolating the voltage signal supplied to each midrange from the source voltage output signal. If these measures are not taken at the calibration installation, only one MF can be verified correctly.

A well-known galvanic isolation unit for group verification of the midrange [1], which is an analogue, with which the current consumption of the midrange is compensated and the voltage drop across the serial circuits caused by the source current is compensated.

The disadvantage of this device is that in the event of a situation in which there is no electrical contact at the point of connecting the serial circuit of one of the midrange to the source current circuit, the transformer of the device is subjected to unacceptable effects. At the same time, the output voltage of the current channel of the source is supplied to one of its windings, which can lead to transformer failure or to a change in its characteristics. A situation in which there is no contact between the serial circuit of the midrange and the current circuit of the calibration installation, in the production of the midrange or during calibration, happens quite often, including with a working calibration installation and a working midrange.

A device [2] is known, which is a prototype that provides galvanic isolation of voltage signals supplied to each midrange from the output voltage signal of the source. In this case, the above errors are excluded. Isolation is carried out by applying a voltage transformer with one primary winding, to which the voltage signal of the source is supplied, and several secondary windings to which the verified midrange are connected. The outputs of the secondary windings are the outputs of the device. The number of turns of the secondary windings of the transformer must be exactly the same. The number of simultaneously verified midrange cannot exceed the number of secondary windings. The parallel circuit of the reference meter of the calibration installation is connected to one of the windings to which the parallel circuit of one of the verified midrange is connected. The serial circuits of the reference and verified midrange are connected in series and connected to the output of the current channel of the source. The error of the device is equal to the sum of the errors of the reference counter and the errors of the secondary voltage of the transformer. Errors of the secondary voltage of the transformer are determined by the voltage difference of the secondary windings, to which only verified midrange and secondary voltage are connected, to which, in addition to the verified midrange, a reference counter is connected. Ultimately, this difference is determined by the difference in the active resistance of the wires of the windings and the nature, as well as the difference, of the capacities consumed from the secondary windings of the transformer. Moreover, the error of the secondary voltages is the greater, the more structurally removed the winding of the verified midrange from the winding of the reference counter. This difference increases with an increase in the number of secondary windings of the transformer of the device due to an increase in the difference in the lengths of the wires of the windings.

The disadvantage of the prototype device is that the reference meter is always connected to one of the secondary windings of the voltage transformer. Online switching of the reference counter is difficult. With a variable number of verified midrange, this leads to an increase in the error of the device or the appearance of unproductive time spent on changing the wiring diagram of the device.

The purpose of the claimed device is to increase the accuracy and performance of calibration facilities.

The inventive device eliminates the disadvantage of a prototype device. The galvanic isolation of voltage signals for each verified instrument for measuring electric power and energy from the output voltage signal of the source is carried out, as in the prototype device, by using a voltage transformer with one primary winding and several secondary windings.

The inventive device provides the ability to quickly connect a parallel circuit of the reference counter to any of the secondary windings of the device transformer using a switch. To connect the parallel circuit of the reference counter, the switch contains a control output. The control output of the switch is connected to any of the secondary windings of the transformer. This allows you to reduce the difference in secondary voltages between the winding to which the reference meter is connected and the winding of any of the verified means of electric power and energy, by choosing the optimal position of the switch switches. With the optimal position of the switches of the switch, the parallel circuit of the reference counter is connected to a winding having an approximately average length of windings to which the measuring instruments to be verified are connected, then the average winding of the involved ones. The selection of the average, from the involved windings is made by its serial number, by setting the switch switches in the appropriate position. In addition, if there is any doubt about the results of determining the errors of any of the verified measuring instruments, it is possible to quickly switch the parallel circuit of the reference meter to the winding to which the measuring instrument of interest is connected. This, the influence of the claimed device on the measurement result will be completely eliminated. An additional advantage of the claimed device is to accelerate the verification procedure when comparing the output voltages of the secondary windings of the transformer. To do this, the verified measuring instrument is connected to any of the secondary windings selected as the reference, and to the control output. By changing the position of the switches of the switch, it is possible to compare the output voltages of all windings with the voltage of the winding selected as a reference.

Common features of the claimed device and the prototype device are that the device contains a source of "fictitious" power, a reference meter, a voltage transformer containing one primary winding and several secondary windings. The output of the voltage channel of the source is connected to the primary winding of the transformer. The output of each secondary winding of the transformer is designed to connect a parallel circuit of one calibrated measuring instrument. The output of the source current channel is connected to the serial circuit of the reference meter and is intended to be connected to series-connected serial circuits of the calibrated measuring instrument.

The difference from the prototype is that the inventive device contains a control output and a switch, providing a connection of the control output to any of the secondary windings of the transformer. In this case, the parallel circuit of the reference counter is connected to the control output.

A block diagram explaining the operation of the claimed device is shown in the figure. A version of the verification of three means of measuring electric power and energy is considered, for which, for example, single-phase electric energy meters, the current sensor of which is based on a shunt, can be used. For this, a voltage transformer with three secondary windings is used. If it is necessary to increase the number of simultaneously verified midrange, the number of secondary windings must be not less than the required number.

The output of the voltage channel of source 1 is connected to the primary winding of transformer 2. Each secondary winding of transformer 2 is connected to a parallel circuit of one of the verified midrange 3, 4, 5 and to the input of switch 6. A parallel circuit of reference counter 7 is connected to the control output of switch 6. the current channel of the source 1 is connected to a chain of sequentially connected series circuits MF 3, 4, 5 and the reference counter 7.

The device operates as follows.

The output voltage of the source 1 is supplied to the primary winding of the transformer 2. The voltage of the secondary windings is fed to the parallel circuits of the verified midrange 3, 4, 5, having approximately the same impedance of the parallel circuits, and to the input of the switch 6. The approximate equality of the impedance of the parallel circuits of the verified midrange is always performed during verification counters of the same type. Verifiable meters are allowed to be connected not to all secondary windings of transformer 2. At the same time, with switch 6, its control output must be connected to any of the secondary windings to which the verified midrange is connected. The output current of source 1 is supplied to the inputs of the serial circuits of the verified midrange 3, 4, 5 and the reference counter 7. By comparison, using any of the known methods, the measurement results of the verified midrange and the reference counter 7, “dummy” power, the error of the verified midrange is determined. During the simultaneous verification of a large number of midrange, the control output by the switch 6 can be connected to any secondary winding of the transformer 2. Optimal, to obtain the minimum error in measuring power and energy, is the state of the switch 6, in which its control output is connected to the middle winding.

The use of the inventive device made it possible to simultaneously verify several tens of single-phase means of measuring electric power and energy. The voltage error introduced by the transformer 2 of the claimed device was ± 0.05 percent, the angular error was ± 1.5 arc minutes. When using a standard measuring instrument in the device with an accuracy of ± 0.05 percent, it is possible to verify single-phase measuring instruments for electric power and energy with an accuracy class of 0.5 or less accurate.

The greatest useful effect can be obtained by using the device when checking several tens of measuring instruments for electric power and energy.

The inventive device can be implemented on the basis of the following devices: as a source 1, a single-phase power supply unit can be used for calibration of electric energy meters SU001 manufactured by Energomera Concern OJSC, Stavropol; transformer 2 can be made on the basis of two OL 93 / 177-50 magnetic cores stacked together manufactured by NPF Stokma LLC, Veliky Novgorod; the switch 6 can be made on the basis of the wafer switches PGA; as a reference meter, a multi-function reference meter CE603 manufactured by Energomera Concern OJSC, Stavropol can be used.

Sources of information used:

1. RF patent №2255347 "Block galvanic isolation for group verification of shunt electricity meters", IPC G01R 35/02, 15/00, etc. 31.12.2003.

2. Technical documentation f. MTE "Testing of single-phase meters with closed IP links using voltage isolation transformers" http://www.mte.ch/inhalte/products/pdf/l_phase_closed_links_english. pdf.

Claims (1)

A device for checking single-phase means of measuring electric power and energy, containing a source of “dummy” power, a reference meter, a voltage transformer including one primary winding and several secondary windings, the output of the voltage channel of the source of “dummy” power is connected to the primary winding of the transformer, the output of each secondary winding the voltage transformer is connected to a parallel circuit of each verified instrument, the output of the current channel of the source of "fictitious" power is connected to Flax reference meter circuit and connected to the series connected sequential circuits calibrated measuring means, characterized in that additionally introduced a switch control output of which is connected to any of the secondary windings of the transformer, the parallel circuit a reference counter connected to the control output.