SU610236A1 - Arrangement for automatic control of compensating current at alternating arc earthing in high-voltage network - Google Patents

Claims (2)

Pensation V is written as the following expression; e, where X is the network frequency. Thus, in the well-known scheme, the automatic tuning of arc-suppressing reactors during a moving arc circuit uses the frequency separation of free oscillations in the zero-sequence network loop with dead-end pauses and a reference frequency of 50 Hz. At the same time, it is known that the frequency in the network can deviate from the nominal value, and adjusting the reactor to the resonance of the zero-sequence loop at a frequency of 50 Hz will always end with some actual detuning, i.e. an additional current will always flow through the damage site and a fine tuning effect cannot be achieved. The aim of the invention is to improve the accuracy of controlling the compensation current in the intermittent arc ground circuit mode. This goal is achieved by the fact that a linear voltage frequency meter and a ne body blocking device are added to a known device containing successively connected blocking devices for neutral bias voltage, a frequency meter of free oscillations of a neutral bias voltage, a memory integrator and an executive body. the line voltage, the input of the linear frequency meter — the network voltage is connected to the network via a blocking device based on the line voltage, and the output is connected to the output Ithel free vibration frequency bias voltage and neutral to the input of the integrator memory, each frequency meter is designed as a two resonant circuits LC, which through vhoDja amplitude limiters are connected to the secondary windings of the input transformer, and the outputs - to the inputs of the rectifiers. FIG. 1 shows a diagram of the device for the automatic regulation of the compensation current during an intermittent arc arc transfer to earth in networks of 6-35 kV; in fig. 2 - output characteristics of frequency meters. The proposed device contains a blocking element 1 for bias neutral voltage, blocking organ 2 for linear network voltage, frequency meter 3 for free oscillations of neutral bias voltage, frequency meter 4 for network linear voltage, memory integrator 5, executive unit b, input transformer 7 amplitude limiters 8, 9, resonant LC circuits and rectifiers il2, 13. Interlocking bodies 1 and 2 contain a regulator switching-on circuit when an earth fault occurs through an intermittent arc. A frequency meter 3, connected via interlocking organ 1 to a neutral bias voltage, is designed to receive a signal proportional to a change in the frequency of free oscillations of the neutral bias voltage with an intermittent arc circuit. The output of frequency meter 3 is connected to the output of frequency meter 4 and to the input of memory integrator 5. Frequency meter 4, connected via block 2 to one of the line voltage voltages, is designed to receive a signal proportional to the change in voltage frequency of the network. The output of the frequency meter.4 is connected to the output of the frequency meter 3 and to the input of the memory integrator. 5, including a two-hole transfluxor with input, output and exciting windings and a driving generator. The output of the memory integrator 5 is connected to the actuator 6. The frequency meter 4 includes an input transformer 7, amplitude limiters 8 and 9, resonant LC circuits 10 and 11, and rectifiers 12 and 13. Amplitude limiters 8 and 9 are made on stabilitrons. The inputs of resonant LC circuits 10 and 11, tuned to 40 and 60 Hz, are connected via amplitude limiters 8 and 9 to the secondary windings of input transformer 7, and the outputs to rectifiers 12 and 13. Frequency meter 3 is made ana-, logically, frequency meter 4. Curve 14 (Fig. 2) depicts the dependence of the output voltage on the frequency of the frequency meter 3, and curve 15 shows the dependence of the output voltage on the frequency of the frequency meter 4. When an intermittent arc closure occurs, the neutral bias voltage is fed to the input of frequency meter 3 via block 1, passes a signal if it is in the range from 0.9 to 0.15 of the mains phase voltage, i.e. at the moment when free oscillations occur in the network zero sequence loop. At the same time, through the blocking organ 2, one of the line voltages is fed to the input of the frequency meter 4. Thus, the rectified voltage received as a result of algebraic summation of two voltages is input to the storage integrator .5, where Uj and 11 are the output voltages of frequency meters 3, respectively. The characteristics of the resonant LC-tours of tours 10 and 11 are chosen in such a way that at a voltage frequency; The input input transformer 7, equal to 50 Hz, the voltage at their output will be equal to each other and, therefore, the voltage at the output of the frequency meter after the rectifiers 12 and 13 will be zero. The voltage at the input of the frequency meter is in the case of a frequency deviation of the input signal from 50 Hz. If in the intermittent arc mode the network frequency is 50 Hz and the arc reactor is not tuned in resonance with the network capacity, it is in the loop. zero-sequence free oscillations occur at a frequency that is otlichnogo from the network frequency of 50 Hz, for example 48 Hz. As a result, the output of the frequency meter 3 shows the Wits signal (point Uj in Fig. 2). The output voltage of the frequency meter 4 will then be zero. The voltage supplied to the input of the memory integrator 5 in this mode will be equal. This signal will be tested by the device before moving the reactor to the position corresponding to the frequency of free oscillations of 50 Hz. If in this mode the mains frequency is not equal to .50 Hz and is, for example, 49.5 Hz, then the voltage U is on the Vits and at the output of frequency meter 4, as shown in; Fig. 2. The voltage at the integrator input will be equal, and therefore this signal will be tested by the device before the reactor is switched to the position corresponding to the frequency of free oscillations of 49.5 Hz, i.e. and in this case full compensation will be provided. Thus, the proposed device provides precise adjustment of compensation in the intermittent phase phase arc-to-ground mode when the network frequency deviates from the nominal value. Improving the accuracy of the compensation current control in the intermittent arc-jagged phase-to-earth mode with the aid of the proposed device allows increasing the reliability of power supply to consumers in compensated electrical networks. 6-35 sq. M. Claims; 1, Device for automatic control of compensation current when an intermittent arc circuit to earth in a high-voltage AC network contains a successively interlocking device based on voltage Neutral bias, a meter for the frequency of free oscillations of a bias voltage of a neutral, the first output of which is connected to the first input of a memory integrator, the output of which is connected to the input of the executive body, which is so that, in order to increase the accuracy of the regulation of the compensation current, it is It is equipped with a line voltage line frequency meter and a line blocking organ according to line voltage, the linear line frequency meter frequency input is connected to the network through a line voltage block body, and the first line line frequency meter meter output memory integrator, and the second - to the second output of the meter frequency of free oscillations of the bias voltage of the neutral. 2. The device according to claim 1, which means that each frequency meter is made in the form of two LC resonant circuits, the inputs of which are connected via the amplitude limiters to the secondary windings of the input transformer,. and the outputs to the inputs of rectifiers. Sources of information taken into account during the examination: 1. USSR author's certificate No. 150156, N 023 3/18, 1961. 2. Authors certificate of the USSR 296189, and 02 H 1/02, 1967. ( ll sl §