SU558350A1 - Reactive Power Compensation Device - Google Patents

Description

The switching time of a capacitor bank has a negative effect on the dynamic stability of power transmission.

Isolation of a capacitor battery must be performed on the full phase voltage of the power line, which makes the capacitor battery a very expensive element, exceeding the unit cost of the transformer together with the thyristor unit.

The aim of the invention is to expand the range of reactive power control. This is achieved by the fact that in the proposed reactive power compensation device containing a multiwinding reactor transformer, to the primary winding of which a voltage regulator is connected, a thyristor unit connected to the secondary winding of the reactor-transformer and regulator, the capacitor battery is connected to another secondary winding of the reactor transformer.

In the drawing, a single-line diagram of the device described is given.

The primary winding of the reactor-transformer 1 is directly connected to the power line 2 or buses of the highest voltage of the substation and connected to a star with a grounded neutral. One CS of the secondary windings of the reactor-transformer can be connected according to the most optimal scheme for the thyristor unit 3, the other secondary winding is connected in a triangle to compensate for current harmonics that are multiples of three. The thyristor unit 3 is connected to the phases of one of the secondary windings of the reactor transformer 1. The thyristor unit is controlled by a voltage regulator 4, the input of which is connected to the primary winding of the transformer 1. Parallel to the other secondary winding of the transformer 1, a capacitor battery 5 is turned on.

The device works as follows.

Changing the opening angle of the thyristor unit 3 under the influence of the voltage regulator 4 allows the voltage and power of the capacitor battery 5 to be varied.

In the idle and low-load modes of power transmission 2, the thyristor unit 3, under the influence of voltage regulator 4, is open for a period or a greater part of it. When this reactor-transformer 1 operates in the mode, close to a short circuit, and absorbs excess reactive

power generated by power line. In this mode, the voltage on the secondary windings of the reactor transformer 1 is low, so the capacitor battery 5 is practically out of operation.

In the mode of natural transmission power 2, the opening time of the circeptive unit 3 during each period under the action of voltage regulator 4 decreases, with

Thereby, the effective voltage on the secondary windings of the reactor transformer 1 increases to the value at which the power generated by the capacitor bank 5 compensates for the loss of reactive power in the reactor transformer.

In order to transfer the power higher than natural and increase the static stability limit, the thyristor unit 3 is completely closed. At the same time, the voltage on the secondary windings of the reactor transformer 1 rises to a value exceeding the nominal voltage of the capacitor battery 5, which makes it possible to force the power of the capacitor battery. The device generates a network

missing reactive power.

In the proposed device, in comparison with the prototype, the cost of a capacitor battery is reduced not only by reducing the voltage class, but also by

reducing the rated power of the capacitor battery and the reactor transformer.

Claims (2)

1.V. D. Venikov “Transient electromechanical processes in electrical systems, “Energy, 1964. 2.Reichert, K., et al. “Controllable Reactor Compensator for Excursive Vitalization of High Voltage Transmission Systems, CIGRE, Paper 31/04, 1974 (prototype).