SU817850A1 - Method of compensating for capacitances of power transmission line - Google Patents

Description

(54) METHOD OF COMPENSATION OF CAPACITIES OF ELECTRICAL TRANSMISSION LINES

By means of shunt reactors, and interphase capacitances, by inductances of compensating reactors, a change in the value of the power transmitted along the power line is recorded, a control signal is formed from the obtained value, and the inductance of the compensation reactor is proportional to it, and the control boundaries are determined at the time maximum and minimum transmitted power.

. In the normal state of the line, power P is transmitted through it. When a single phase short circuit occurs on the line at that moment. The make-up current flowing through the arc channel after the line is disconnected in the OAPV cycle consists of the sum of the electrostatic and electromagnetic components. In this case, the electrostatic component in all modes is constant, and electromagnetic depends on the magnitude of the transmitted power. Consequently, the degree of line compensation in each specific case must be chosen in such a way as to ensure the flow of the minimum total make-up current through the arc channel in the OAPV cycle. This is achieved by the fact that with constant compensation of interphase capacitances of the line and, accordingly, with a constant value of the electrostatic component of the make-up current, compensation of the capacitance of the disconnected line phase to earth and, accordingly, the magnitude of the electromagnetic component are adjusted so that the total make-up current is minimal. In order to fulfill the condition of the minimum of the make-up current in all modes, a constant control over the value of the transmitted power is exercised.

With an increase in the power flow through the line, the degree of compensation is reduced, and with a decrease, respectively, it is increased, and the change is made according to a predetermined dependence. This dependence for each specific line is unambiguous. It is determined by the capacitive and injective parameters of the given line and gives the range of variation of the degree of compensation of the line depending on the magnitude of the transmitted power.

When using the specified dependency single-phase switching off k.z. on the line at any moment of time and with any power flow, the minimum supply current through the arc channel is accompanied by the flow, which ensures, in turn, the minimum IADC pause and its high efficiency.

The drawing shows a block diagram illustrating the implementation of the proposed method for one end of the line.

The block diagram contains a high-voltage switch, power line SEN 2; transformer 3 voltage; a current transformer 4, a group of shunt reactors 5, a power control unit 6, a control unit 7 and a compensation reactor 8 with adjustable inductance.

The performance of the inductance of the compensation reactor is controlled by

by any known method, for example, by means of taps from its winding, by moving the magnetic circuit, by closing it on the alternating resistance of its secondary winding, etc.

As a control unit, it is possible to use, in particular, a device for regulating the voltage under load (RNP) of a power transformer, used as a compensation reactor, or changing the number of concrete

reactors that serve as a load on the secondary winding of a transformer. Regulation can be carried out either automatically or manually. The execution of the power control unit does not present technical difficulties, since it can be performed with

using conventional wattmeter devices.

The effectiveness of the proposed method consists in more rapid and reliable extinguishing of the arc of feeding with a single-phase short-circuit. on

line, which allows you to get the minimum PADS with any power flow over the line. For some lines that have phase asymmetry in capacitive parameters, additional control of the compensation level may be required.

at occurrence short-circuit on different phases.

Claims (2)

1.Knudsen "Single-phase transitions of the secondary arc. CIGRE, 1962, drawing 310. 2. Haubrich H. I., Hosemann G., Thomas R. Singiepole autoreclosing in EHV systems. CIGRE, 1974, drawing 31-09.