SU1282258A1 - Device for controlling voltage and reactive power - Google Patents

Abstract

The invention relates to electrical energy distribution systems and is intended to regulate and stabilize an alternating voltage, compensate for voltage fluctuations, and can also be used as a static source of reactive power. The purpose of the invention is to improve the accuracy of voltage stabilization, increase the speed of its regulation and expand the range of control of reactive power. The primary winding 2 of the transformer-reactor 1 is connected in series with the load 3. The secondary winding: 4 is connected in series with the capacitor battery 5 to the supply voltage. Parallel to the capacitor battery 5 is connected a branch consisting of a reactor 6 and a thyristor switch 7. An increase in the current of the secondary winding 4 causes an increase in the voltage across the load 3 with a capacitive current pattern and a decrease in the voltage on the load 3 with inductive. The regulation of reactive power is carried out not only by changing its consumption by inductive elements of the device, but also by changing its generation by a capacitor battery. 1 il. ( (ABOUT

Description

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The invention relates to the field of electrical engineering, in particular to electrical energy distribution systems, and is intended to control and stabilize alternating voltage, compensate for voltage fluctuations, and can also be used as a static source of reactive power.

The purpose of the invention is to improve the accuracy of voltage stabilization, increase the speed of its regulation and expand the range of control of reactive power.

The drawing shows a device for controlling voltage and reactive power.

A device for controlling voltage and reactive power contains a transformer-reactor 1, the primary winding 2 of which is connected in series with the load 3, and the secondary winding 4 is connected in series with the capacitor battery 5 to the supply voltage, and the beginning of the winding 4 is connected to the network between the end the primary winding 2 and the load 3. Parallel to the capacitor battery 5, a branch is connected, consisting of a reactor 6 and a thyristor switch 7 connected in series.

When changing the angles of unlocking of the thyristor switch 7 and, accordingly, the current in its branch, the EMF of mutual induction in the primary winding 2 changes from the current of the secondary winding 4, as well as the voltage drop in the network and the primary winding 2 as a result of a change in the compensation of reactive power load 3. And the increase in the current of the secondary winding 4 causes an increase in the voltage on the load 3 at the capacitive nature of the current and a decrease in the voltage on the load 3 at the inductive.

The device regulates reactive power simultaneously with voltage regulation at load 3 when the unlocking angle of the thyristor switch 7 changes. Moreover, an increase in the current of the reactor 6 leads to a decrease in the current of the capacitor battery 5, i.e. the regulation of reactive power is not only due to a change in its consumption inductive elements of the device, but also due to a change in its generation by a capacitor battery 5.

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When the thyristor switch 7 is completely locked, the voltage at the load 3 and the degree of compensation of its reactive power have the maximum value, and when fully open, the minimum value. If the resistance of the reactor 6 is less than the resistance of the capacitor bank 5, then when the thyristor switch 7 is completely locked, the current of the secondary winding 4 will be inductive in nature, and the device will consume reactive power. In the range of changing the angles of unlocking the thyristor switch 7, simultaneous and inertia-free regulation of the voltage across the load 3 and the reactive power of the device occurs.

The reactive power and voltage on the load 3 are regulated in the device not only by adjusting the unlocking angle of the thyristors, but also by the inductive coupling between windings 2 and 4. So, with the capacitive nature of the current of the secondary winding 4, the increase in load current increases voltage in the supply network and due to inductive coupling between windings 2 and 4 increases the voltage on the capacitor battery 5, which in turn causes an increase in capacitive current in the winding 4, an increase in the positive voltage additive and on winding 2 and compensation of the voltage drop in the network.

The choice of the parameters of the transformer-reactor 1 and the capacitor bank 5 is based on the required maximum voltage addition in the mode with the thyristor switch 7 fully locked. Moreover, the same voltage additive at load 3 can be obtained with different ratios of the transformer-reactor parameters and capacitor bank 5.

Voltage oscillations are regulated and compensated at the same time and with equal accuracy by adjusting the current in the thyristor switch 7 branch, both under the influence of individual disturbing factors — change in the supply voltage, change in the supply network resistance or load current, and their combination.

Claims (1)

Claims An apparatus for regulating voltage and reactive power, comprising a transformer-reactor, the primary winding of which is connected in series with the load, and the secondary winding is connected in series with the capacitor battery to the power supply network, and the beginning of this winding is connected to the network between w12822584 The primary winding and the load, characterized in that, in order to increase the voltage stabilization accuracy, increase the speed of its control and extend the range of reactive power control, a branch consisting of a reactor and a thyristor 10 key connected in series is connected parallel to the capacitor battery .