CS243506B1 - High voltage and extra high voltage measuring transformers' transformation simultaneous measuring connection with principal frequency and its arbitrary multiple - Google Patents

Abstract

The connection is usable in bulk remote control in power and measurement harmonics in networks. It's being measured it means the size of the tone voltages in high networks and very high voltage. Primary winding the voltage transformers being measured are in parallel connected to grounded output windings an increasing voltage transformer, whose input winding is connected in parallel with a 50 Hz power supply and auxiliary voltage transformer in parallel connected voltmeter whose input the winding is parallel to the source tone frequency. Secondary windings measured voltage transformers are divided and their parts are serially connected to two grounded circuits, one in common, the other in the opposite, in the series of everyone circuit is connected to a voltmeter.

Description

(54) Wiring for simultaneous measurement of the conversion of high and very high voltage voltage transformers at base frequency and any multiple thereof

The wiring is useful for mass remote control in power engineering and for measuring harmonics in networks. It measures the magnitude of tone voltages in high and very high voltage networks. The primary windings of the measured voltage transformers are connected in parallel to the grounded output windings of the boost voltage transformer whose input winding is connected in parallel to a 50 Hz power supply and the auxiliary voltage transformer with a parallel connected voltmeter whose input winding is connected in parallel to the tone frequency source. Secondary windings of measured voltage transformers are divided and their parts are connected in series to two grounded circuits, one in common, the other in the opposite sense, in series of each circuit is connected voltmeter.

BACKGROUND OF THE INVENTION The present invention relates to circuitry for simultaneous measurements of the conversion of high and very high voltage voltage transformers at fundamental frequency and any multiple thereof.

At present, a mass remote control is being introduced in the energy sector, which uses energy networks to transmit tone pulses superimposed on the fundamental harmonic with a frequency of 50 Hz.

The amplitude of this applied voltage at a higher frequency should not exceed 5% of the fundamental harmonic value, but must always be higher than the start-up value of the ripple control receivers.

The magnitude of the tone voltages in low voltage networks can be measured directly by selective instruments, the detection of these values in high voltage and very high voltage networks can only be ensured by transforming the measured values with voltage transformers.

For this purpose, the actual transmissions or errors of the measuring transformers at the tone frequencies must be known, and it is desirable to calibrate them simultaneously with the basic mains frequency for correct measurements.

Performing these measurements encounters considerable difficulties for both manufacturers and users of measuring transformers, so it is practically only performed at 50 Hz and the same conversion is assumed for higher frequencies.

Said drawbacks are substantially eliminated by wiring for simultaneous measurement of the conversion of the high and very high voltage voltage transformers at the base frequency and any multiple thereof according to the invention.

Its essence is that an output winding on the other side of a grounded boost voltage transformer is connected to two identical high voltage or very high voltage terminals of the voltage transformers connected in parallel to the input winding of which a 50 Hz power supply is connected.

The first voltmeter and the output winding of the auxiliary voltage transformer are connected between the remaining high voltage or very high voltage terminals of the voltage transformers to be measured.

This winding is symmetrically divided and the center of the winding is grounded. A tone frequency source is connected to the input winding of this auxiliary voltage transformer. The secondary windings of both voltage transformers are connected to two-series circuits of identical windings, the first circuit in the common and the second circuit in the opposite sense.

A second voltmeter is connected in series with the first circuit and a third voltmeter in series with the second circuit. Each circuit is grounded at one point.

The main advantage is the fact that the measurement is practicable in practically every test room, but also in already installed transformers with arbitrarily adjustable ratio of the given quantities for tone and operating frequency. The measurement can also be extended for measurements with different loads, which are connected to the secondary terminals of the measuring transformers.

An example of a circuit for simultaneous measurement of the transformers of the high and very high voltage voltage transformers at the fundamental frequency and any multiple of the invention is schematically drawn in the attached drawing.

The output winding of the boost voltage transformer 2 is connected to two identical parallel connected high voltage terminals M or very high voltage terminals of the primary winding of the voltage transformers 2.

This winding is, on the other hand, grounded. A power supply source 50 Hz is connected in parallel to the input winding of this transformer. Between the remaining high voltage terminals N or the very high voltage terminals of the primary winding of the voltage transformers 6, a first voltmeter 61 is connected and parallel to it the output winding of the auxiliary voltage transformer 6, which is symmetrically divided and has a grounded and grounded center 7.

A tone frequency source 6 is connected in parallel to its input winding. Each of the voltage transformers 3 has two identical secondary windings. The first secondary windings of the two voltage transformers 8 are connected to the series first circuit 8 in a corresponding sense, i.e. their terminals m and their second terminals n are connected.

The second secondary windings of the two voltage transformers 2 are connected to the serial second circuit 2 in the opposite sense, i.e. the terminal r of one winding is connected to each other with a terminal with the other winding.

In the first series circuit 2 ^e 3 second voltmeter 62 connected to the second series circuit 2, third voltmeter 62 · Each of the circuits 2 »2 3 ^ev one point grounded.

The principle of the invention is the fact that two identical voltage transformers 2 are measured using two independent sources 6, 6 with both mains and selected frequency, each measuring voltage transformer 2 being connected to the same frequency of 50 Hz, but the tone voltage of one transformer 2 measured, the voltage is rotated 180 [deg.] with respect to the other, i.e. in a counter-phase.

In this way, values of only the tone frequency are measured at the terminals m, n and r, £ in a series of connected secondary leakages.

The invention has been tested. It is supposed to be used for mass remote control in power engineering and for measurement of higher harmonics in networks.

Claims (1)

SUBJECT OF THE INVENTION Circuit for simultaneous measurement of the conversion of high and very high voltage voltage transformers at base frequency and any multiple thereof, characterized in that an output winding is connected to two identical high-voltage terminals (M) or very high voltage terminals of the transformer windings (3). of the boost voltage transformer (2) on the other side grounded, to whose input winding the power supply source (1/50 Hz) is connected, while the first voltmeter / is connected between the remaining high voltage terminals (N) or very high voltage terminals 61) and parallel to it the output winding of the auxiliary voltage transformer (4), which is symmetrically divided and has a grounded and grounded center (7), to whose input winding is connected a tone frequency source (5), voltage is u is connected to two serial circuits (8, 9) of the same windings, the first circuit (8) in common and the second circuit (9) in the opposite direction when a second voltmeter (62) is connected in series with the first circuit (8); in series with the second circuit (9) the third voltmeter (63) and each circuit (8, 9) is grounded.