SU612292A1 - Method of reducing unbalance for differential current transformers - Google Patents

Description

In addition, to connect such a construction, the primary conductors in series with the protected load are needed (a schematics. The design of such a current transformer and a terminal block is expensive, cumbersome and completely non-technological. And during installation, inconveniences arise due to the need to connect large cross-section wires to the terminal block .

These drawbacks are inherent in the design using the transposition (twist) of the primary conductors; In the manufacture of a current transformer for high load currents, the primary conductors must be made with a large cross section. It is obvious that the twisting of such wires with the preservation of the insulation properties between them, the wiring of the ends to the kleichnik and the need to connect with the installation of wires of large cross section - all this makes this design cumbersome, expensive to manufacture and inconvenient to use during installation.

Thus, the known methods for reducing the imbalance in DTT at high load currents do not give sufficient effect.

Other methods are known for changing the parameters of transformers, for example, a method of adjusting the coefficient of mutual induction of coils wound on toroidal coaxially arranged cores by turning one of the coils relative to the other (4.

However, this method of essentially physical processes cannot be used to reduce unbalance.

Magnetic amplifiers are known in which unbalance takes place and its reduction is achieved by mutual compensation of unbalances of two (or several) parts of this device. This method is based on equalizing the EMF of self-induction of the alternating current windings of two chokes, achieved by changing the magnetic permeability of the magnetic cores of the cores due to their magnetics 5. This magnetization is carried out either by a direct bias current through the special windings, or by a permanent magnet, the magnetic field of which passes through the circuit of the circuit, which is passed through the circuit of the circuit, and the magnetic field passes through the circuit of the circuit, which is passed through the magnetic circuit of the windings, or a permanent magnet, the magnetic field of which passes through the circuit of the circuit. cores. A smooth adjustment to the minimum unbalance is achieved either by adjusting the variable resistance in the bias circuit or by changing the position of the constant magnet relative to the cores of the chokes.

This method of balancing magnetic amplifiers does not reduce the unbalance of the differential current transformer.

The aim of the invention is the best detuning from the unbalance of differential current transformers.

This is achieved by the mutual compensation of the two DTT unbalance signals in the proton phase by rotating each of them relative to the primary conductors, followed by fixing the optimal position. Turning each current transformer relative to the primary conductors provides

necessary to compensate for the phase shift of the signals unbalance.

The reduction of the signal in this method is based on the following. It has been found theoretically and experimentally that when the differential current transformer rotates relative to the primary conductors, the unbalance signal changes in magnitude and in phase. In contrast, the amplitude and phase of the useful Signal does not depend on the position of the primary conductors in the window of the magnetic circuit. This makes it possible to obtain on the series-according to the included windings of the two magnetic cores (chokes) a sum of useful signals. and the difference (due to a 180 ° phase shift) of unbalance signals. The phase shift of the unbalance signals of the individual chokes is carried out by selecting the specific position of each choke in relation to the primary conductors.

The drawing illustrates one of the possible options for implementing the proposed method, where I is two current transformers, the terminals of which windings are HI ,. H2 and K1, K2 are connected in series according to; 2 - centering sleeve on which the cores of the transformers can rotate during alignment. Ke for minimum unbalance; 3 - two primary conductors with equal and oppositely directed load currents (the directions of the currents are conventionally indicated by arrows).

The configuration of such a current transformer after its assembly is performed as follows. A volimeter is connected to the secondary winding of one of the transformers, which is taken as the base transformer, by rotating this core around the primary conductors, the position at which the voltmeter reading is maximum is reached, the voltmeter is reconnected to both windings and by rotating the second core around the primary conductor to achieve a minimum voltmeter reading. Thereafter

in any way, both cores are fixed to one another.

The use in the development of differential current transformers of this spot unbalance reduction will ensure the creation of highly sensitive protection for high load currents. At the same time, it is possible to use a power cable as the primary conductor, which will lead to a reduction in the size of current transformers, exclusion of the terminal block, and an increase in the manufacturability of assembly and installation in operation.

Form, and the invention

A method for reducing the imbalance of differential current transformers, each of which contains a toroidal core, covering the primary conductors, with a secondary winding wound on the blind, the secondary windings being connected in series to one another, differing in

that, in order to increase the sensitivity of the current protection by better detuning from the unbalance, one of the cores is turned relative to the primary conductors until the maximum unbalance is reached on its secondary. winding, then turn the other (and subsequent) core relative to the same conductors to obtain a minimum unbalance on the secondary windings all; (cores. "After which the cores are fastened.

Sources of information taken into consideration in the examination:

I. Kostruba S. I. Nikolsky O. K-, Slobodsky A. X., King VF Protective-disconnecting device. “Industrial Energy, 1971, № 3.

2. Atabekov G. I., Fedoseyev A. M. Modern protection. "Goszner1z Nzdat, 1948,

3. USSR author's certificate number 181176, to. H 01 F 40/40, 1966.

4. USSR author's certificate M 124012, cl. H 01 F 29/12, 1958.

5. Fabrikant V. L., Glukhoi V.P.N. N others. Elements of devices for relay protection and automatic equipment of air conditioner and their design. “Higher scale. 1974.