CS215598B1 - Connection to reactive current measurement - Google Patents

Abstract

The invention relates to the field of reactive current measurement and solves the problem of fixed compensation of electrical machines, devices and equipment. The connection for measuring reactive current is based on a connection with one rectifier diode and in parallel to the secondary winding of the current transformer is connected an auxiliary load branch, formed by a series connection of a shunt rectifier diode polarized oppositely to the main rectifier diode and an auxiliary load resistor. The connection according to the invention is suitable for use in devices for ensuring fixed compensation of electrical machines. The connection solution is clear from Fig. 1

Description

(54)

Connection for reactive current measurement

The invention relates to the field of reactive current measurement and solves the problem of fixed compensation of electrical machines, apparatus and devices.

The reactive current measurement circuit is based on a single rectifier diode connection and has an auxiliary load branch connected in parallel to the secondary winding of the current transformer, consisting of a serial rectifier diode polarized opposite to the main rectifier diode and an auxiliary load resistor.

The circuitry according to the invention is suitable for use in a device for providing fixed electrode compensation. machines.

The solution of the connection is clear from Fig. 1

215 598

The invention relates to a reactive current measurement circuit in which it removes the DC saturation of the transformer while maintaining a low voltage at the secondary terminals of the transformer.

The known reactive current circuits use either two rectifier diodes, one in the collector circuit of one switching transistor, or one rectifier diode connected between the current transformer and the resistors forming the center. In the first case, the diode loss is subtracted from the current generated by the resistors. an artificial center and thus a measurement bend is formed which is relatively large especially at low currents, in the latter case a DC saturation of the current transformer occurs and thus 1 bends the measurement at higher currents. In both cases, the performance can only be improved by dimensioning the transformer for greater power, which leads to increased dimensions and cost per meter.

These disadvantages are eliminated by the reactive current measurement circuit according to the invention, consisting of a phased cell, connected between the input voltage terminal and base-emitter transitions of two complementary transistors that form two branches of the measuring bridge with the other two branches formed by resistors and a voltmeter in diagonal. the terminals of the transformer are connected to the secondary and two antisera-connected Zener diodes are connected via the main diode of the measuring bridge and where the principle of the invention is that parallel to the secondary winding of the current transformer is connected opposite to the main rectifier diode and pomoid load resistance.

The main advantage of the wiring according to the invention is that the connection of the low load branch adds half-wave unbalanced transformer load, which carries the DC component of voltage and current, to pure pure wave AC voltage, thus no measurement distortion by DC saturation of the transformer at high currents. signal from resistors creating an artificial center suppressed by the loss of rectifier diodes, so there is no signal distortion at low currents

An example of a circuit according to the invention for measuring reactive current is shown by sohematics in the drawing.

The circuit for reactive current measurement according to the invention consists of a phase cell 2 »connected between input voltage terminals 1, 1 'and base-emitter transitions of two complementary transistors 4, 5 forming two branches of the measuring bridge with the other two branches formed by resistors 2» 2. ^{and a} voltmeter 10 in diagonal, wherein the primary winding of the transformer 6 is connected to the current terminals 2, 2, the secondary winding of which is connected with two antisera-connected Zener diodes 2 and 2 through a rectifier diode. In the current transformer 6, a low load branch composed of a series connection of the rectifier diode 11 polarized opposite to the main rectifier diode 8 and the resistor 12 of the load is connected.

When measuring the reactive current with the circuit according to the invention by connecting a branch of an overhead load, i.e., a rectifier diode 11 and of opposite polarity to the main rectifier diode 8 and the resistor 12 in series connection, adds a half-wave unbalanced load of the transformer 6 current, to full-wave pure alternating load. There is therefore no distortion of the measured value by the direct current of the transformer 6 at high currents and there is also no voltage signal from the resistors 2.2

A) creating an artificial center, suppressed by the loss on the main rectifier diode 8 and the auxiliary rectifier diode 11, and thus there is no signal distortion at low currents.

Said auxiliary load is applicable to phase detectors for comparing the phase of two electric signals, in particular to I sin _g reactive current meters.

Claims (1)

SUBJECT OF THE INVENTION Reactive current measurement circuit, consisting of a phasing cell, connected between input voltage terminals and base-emitter transitions of two complementary transistors, forming two measuring bridge branches with the other two branches formed by resistors and a voltmeter diagonally connected to the current terminals the primary winding of the transformer, to whose secondary winding are connected both two antisera-connected Zener diodes, and through the main rectifier diode a measuring bridge input, characterized in that an auxiliary load branch consisting of a series connection is connected parallel to the secondary winding of the current transformer (6) the auxiliary rectifier diodes (11) polarized opposite to the main rectifier diode (8) and the auxiliary load resistor (12).