RU2536810C1 - Prohibition method of automatic reclosing of main switch of line feeding transformer substation with determination of type of short circuit - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: use of the invention: in electrical engineering. The technical result consists in the enlargement of functional capabilities of the method. According to the method, from the moment of disappearance of one or all line voltages and absence of the short-circuit (SC) current at the transformer input, counting of the total time is started, which is equal to the delay time of a protection actuation and the delay time of automatic reclosing of the main switch (MS); at the end of counting of the total time the sounding pulses are sent to all wires of this line, the time is measured, during which they achieve reflection points; the distance to these points is calculated and they are compared to each other and to the distance to the MS installation place, and if the two calculated distances are equal to each other and less than the third one, which is equal to the distance to MS, then, a conclusion is made on the stable two-phase SC. If all the calculated distances are equal to each other and less than the distance to MS, then, a conclusion is made on the stable three-phase SC and a signal is supplied to prohibit automatic reclosing of the main switch of the line feeding the transformer substation.

EFFECT: proposed method allows performing prohibition of automatic reclosing of the main switch of a line feeding the transformer substation with the determination of the type of the short circuit.

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Description

The invention relates to the automation of electrical networks and is intended to prohibit automatic restart (AR) of the head switch (GV) of the line supplying the transformer substation with the determination of the type of short circuit (short circuit).

A known method of prohibiting network automatic switching on of a reserve for two-phase faults is that they control the presence of all three linear voltages, record the disappearance of one of them and, when the other two disappear, start the countdown, which is set equal to the dead time pause of the automatic reclosure of the sectioning switch. And, if at the end of the countdown the appearance of the same two linear voltages is detected, then a signal is issued to prohibit the automatic inclusion of the reserve [patent RU No. 2181920 C2 class. H02J 9/06, publ. 04/27/2002, bull. No. 12].

The disadvantage of this method is the impossibility of using it to prohibit the reclosure of a hot water supply line supplying a transformer substation with a definition of the type of short circuit.

The objective of the invention is to expand the functionality of the method by prohibiting the reclosure of the hot water supply line supplying the transformer substation with the definition of the type of short circuit.

According to the proposed method, from the moment of the disappearance of one or all of the line voltages and the absence of short-circuit current at the input of the transformer, a countdown of the total time equal to the delay time of the protection operation and the exposure time of the automatic restart of the hot water starts, at the end of the countdown of the total time, probing pulses are sent to all wires of this line, measure the time for which they reach the reflection points, calculate the distances to these points and compare them with each other and with the distance to the location of the hot water and, if two the numerical distances are equal to each other and less than the third, which is equal to the distance to the hot water, then make a conclusion about a stable two-phase short circuit, and if all the calculated distances are equal to each other and less than the distance to the hot water, they make a conclusion about a stable three-phase short circuit and feed signal to prohibit the automatic restart of the head switch of the line supplying the transformer substation.

The essence of the invention is illustrated by drawings, where:

figure 1 - presents a structural diagram containing elements for implementing the method;

figure 2 - diagrams of the signals at the terminals of the elements shown in figure 1 with a stable short circuit at point 2 (see figure 1).

The circuit (see Fig. 1) contains: a head switch 1 of the line supplying the transformer substation, a short circuit point 2, a power transformer 3, an input switch 4 of the substation buses, lines 5 and 6, extending from the substation tires, a short circuit current sensor (DTKZ) 7, element NOT 8, voltage sensor (DN) 9, elements: NOT 10, BAN 11, MEMORY 12 and 13, DELAY 14, SINGLE VIBRATOR 15, AND 16, information processing unit (BOI) 17, probe pulse generator (GZI) 18 , a probe pulse probe (PZI) 19, a recording device (RU) 20.

The signal diagrams at the outputs of the elements shown in figure 1 with a stable short circuit at point 2 (see figure 1) have the form (see figure 2): 21 - at the output of element 7, 22 - at the output of element 8, 23 - at the output of element 9, 24 - at the output of element 10, 25 - at the output of element 11, 26 - at the output of element 12, 27 - at the output of element 13, 28 - at the output of element 14, 29 - at the output of element 15, 30 - the output of element 16, 31 - at the output of element 17, 32 - at the output of element 18, 33 - at the output of element 19, 34 - in RU 20.

In addition to the output signals of the circuit elements in figure 2 also shows: t1 - the time of the disappearance of the voltage at the input of the transformer, t2 - the time of the sending of the probe pulses, t3 - the end time of the total time and AGTV GV 1

The method is as follows.

In normal operation of the network, switches 1 and 4 are turned on, there is no signal at the output of DTKZ 7 (Fig. 2, Diagram 21), therefore, there is a signal at the output of element NOT 8 (Fig. 2, Diagram 22) and it will go to the first input element And 16. However, And 16 will not work, since there is a signal at the output of DN 9 (Fig. 2, Diagram 23) and there is no signal at the output of element NOT 10 (Fig. 2, Diagram 24), so the circuit is in mode control.

With a stable two- or three-phase fault at point 2, the signal disappears from the output of DN 9 (Fig. 2, diagram 23, time t ₁ ). In this case, a signal appears at the output of the element NOT 10 (figure 2, Fig. 24). This signal will arrive in BOI 17 and will be delayed in it until the time t ₂ , when probing pulses must be sent to the line, as well as to the input of the BAN 11 element (Fig. 2, diagram 25), and from its output to the input of the MEMORY 13 element , where it will be remembered (Fig. 2, Diagram 27), and it will go to the input of the DELAY 14 element. From the output of this element, the signal will appear after the total time equal to the response time of the protection plus the exposure time of the automatic recirculation gun 1. Before the total time expires (time t ₃ ) at time t2 from the third output of the BOI 17 the signal will go (figure 2, Fig. 31) in the GZI 18 and from the output of the GZI 18 into the wires of the line supplying the transformer substation, probe pulses will go (Fig. 2, Diagram 32), which, having reached the reflection points, will return back and go to the PZI 19, and from its output (Fig. 2, Diag. 33) will go to BOI 17. This element will determine the time it takes for the pulses to reach the reflection points, calculate the distance to the reflection points and compare them with each other and with the distance to the GW 1. After the total time has passed, the signal will arrive at the output of DELAY 14 input element SINGLE-VIBRATOR 15 (figure 2, diagram. 29). He will make one oscillation (Fig. 2, Diagram 29) and with his signal “discard” the memory from element 13 (Fig. 2, Diagram 27), will go to the input of the MEMORY 12 element, will be remembered by him (Fig. 2, Diagram 26 ) and, having entered the inhibitory input of the element PROHIBITION 11, will prevent the reappearance of the signal from the element NOT 10 (figure 2, Fig. 25). At the same time, the signal will go to the second input of the element And 16. It will work (figure 2, Fig. 30), since at its first input there will be a signal from the element NOT 8 (figure 2, Diagram 22), and its signal will arrive in BOI 17. At this point in time, BOI 17 will compare the calculated distances with the distance to GW 1 and, if the two calculated distances are equal to each other and less than the third, which is equal to the distance to GW 1, then a signal will go from its first output from RU 20 (Fig. .2, diag. 31), which will ensure the appearance there of information (Fig. 2, diag. 34) that there is a stable two-phase fault in the line, and this the signal will arrive at the GW 1 and prevent it from being switched back on to a stable two-phase fault. And if all the calculated distances will be equal to each other and less than the distance to GV 1, then from the second output of the BOI 17 to RU 20 a signal will go that will ensure that it contains information about a stable three-phase fault (Fig. 2, Diagram 34), and also this signal will go to GW 1 and will prevent the repeated inclusion of GW 1 to a stable three-phase short circuit.

Thus, the proposed method allows the prohibition of the reclosure of the HV 1 line supplying the transformer substation with the definition of the type of short circuit.

Claims (1)

The method of prohibiting the automatic re-inclusion of the head circuit breaker of the line supplying the transformer substation with the determination of the type of short circuit (short circuit), which consists in fixing the inrush current short circuit and in measuring the time between them, characterized in that since the disappearance of one or all linear voltages and the absence of short circuit current at the input of the transformer, the countdown of the total time equal to the delay time of the protection operation and the exposure time of the automatic restart of the hot water starts, at the end of the countdown of the total time probe pulses are sent to all the wires on this line, they measure the time it takes for them to reach the reflection points, calculate the distance to these points and compare them with each other and with the distance to the location of the hot water and if the two calculated distances are equal to each other and less, than the third, which is equal to the distance to the hot water, they conclude that a stable two-phase fault, and if all the calculated distances are equal to each other and less than the distance to the hot water, they make a conclusion about a stable three-phase fault and signal to prohibit automatic re on the inclusion of the head line of power supply to the transformer substation.

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