RU2410817C1 - Method to control variances of condition of head circuit breaker in circuit of circular network - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to automatics of electric circuits and is intended to monitor variation of condition of head circuit breaker equipped with automatic reconnection device (ARD) of single-time action and installed in line of circular network supplied from buses of double-transformer substation. According to proposed method, from the moment of detection of short circuit current surge in the beginning of sectional line of circular network, time is counted equal to time of actuation of protection of line head circuit breaker, at the same time moment of short circuit current surge termination is monitored, and if the moment of time count termination coincides with the moment of disconnection of the first short circuit current surge, then fact of disconnection of head circuit breaker is confirmed, and then, from the moment of disconnection of the first short circuit current, time count is started for delay of automatic reconnection (ARD) of head circuit breaker, as well as count of total time equal to time of head circuit breaker ARD delay and time of actuation of its protection with acceleration, at the same time appearance of the second current surge is monitored, and if at the moment of ARD delay time count termination the second current surge is not available with value of more than normal working value, but less than short circuit current or equal to short circuit current, then fact of failure of ARD of head circuit breaker of circular network line, or at the moment of termination of time of ARD delay, the second current surge is detected with value of more than normal working value, but less than short circuit current, then fact of successful ARD of head circuit breaker of circular network line is established, and if the second short circuit current surge is detected at the moment of termination of ARD delay time count, then fact of failure of ARD of head circuit breaker of circular network line is established, and further if after appearance of the second short circuit current surge, at the moment of termination of total time count there is no disconnection of the second short circuit current surge, then fact of failure of head circuit breaker is established during reconnection.

EFFECT: expansion of functional capabilities of method by obtaining information about disconnection, successful, unsuccessful or failed ARD of head circuit breaker, and also failure of disconnection in case of its repeated connection for short circuit current.

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Description

The invention relates to the automation of electrical networks and is intended to control a change in the state of the head switch equipped with a single-acting automatic reclosing device (AR) and installed in the line of a ring network powered by two-transformer substation buses.

There is a method of monitoring the successful and unsuccessful reclosure of circuit breakers in a sectioned line of a ring network powered by two-transformer substation buses, which consists in the fact that from the moment of the inrush of a short circuit current (short circuit) at the beginning of a sectioned line of a ring network, the time equal to the response time is counted protection of each circuit breaker installed in a partitioned line, at the same time control the short-circuit current inrush trip, and if the end of the protection trip time of one of the circuit breakers the same value as the short-circuit current inrush trip, then the circuit breaker is detected, and then, from the moment of the first short-circuit inrush trip, the time starts equal to the AR time of the disconnected circuit breaker, and the appearance of the second current inrush is controlled, and if, when it appears at the moment the countdown time of the automatic reclosure time of the tripped circuit breaker is exceeded, it is greater than the normal operating current, but less than the short-circuit current, then the fact of a successful reclosure circuit breaker is established, and if it is greater than or equal to the short-circuit current. - unsuccessful reclosure of a tripped circuit breaker installed in a partitioned line of a ring network [Patent No. 2305356, cl. H02J 13/00, 2007].

The disadvantage of this method is the impossibility of using it to control the state of the head switch in the line of the ring network, powered by the buses of a two-transformer substation.

The objective of the invention is to expand the functionality of the method by obtaining information about the failure of the automatic reclosure of the head switch, its shutdown, successful reclosure, unsuccessful reclosure, as well as the failure of disconnection after it is switched back on short-circuit current.

According to the proposed method from the moment of the appearance of an inrush short circuit at the beginning of the partitioned line of the ring network, the time equal to the response time of the protection of the line head circuit breaker is counted, and the time of the inrush trip short-circuit is monitored. If the moment of the end of the countdown coincides with the moment of switching off the first inrush short-circuit current, then the fact of switching off the head switch is established. And then from the moment of switching off the first inrush short-circuit start the countdown of the reclosure time of the head switch and the countdown of the total time equal to the reclosure time of the reclosure of the head switch and the response time of its protection with acceleration. At the same time, the appearance of the second inrush current is controlled and if, at the end of the countdown of the AR delay time, there is no second inrush current with a value greater than the normal operating one, but less than the short-circuit current or equal to the short-circuit current, then the fact of the automatic reclosure failure of the head circuit breaker of the ring network line is established. Or, at the end of the countdown of the AR delay time, a second current surge appears with a value greater than the normal operating current, but less than the short-circuit current, then the fact of successful reclosure of the head switch is established, or if a second short-circuit current surge occurs. at the end of the countdown of the reclosure time, then establish the fact of unsuccessful reclosure of the head circuit breaker of the ring network line. And further, if after the appearance of the second short-circuit current inrush, at the end of the countdown of the total time, the second short-circuit inrush does not trip, then the fact of failure to turn off the head switch when it is turned on again is established.

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 outputs of the elements shown in figure 1, in case of failure of the reclosure of the head switch at short circuit at point 27 (see figure 1);

figure 3 - diagrams of the signals at the outputs of the elements shown in figure 1, with the successful reclosure of the head switch at short circuit at point 27;

figure 4 - diagrams of the signals at the outputs of the elements shown in figure 1, with an unsuccessful reclosure of the head switch at short circuit at point 27;

in Fig.5 is a diagram of the signals at the outputs of the elements shown in Fig.1, in case of failure of disconnection when the head switch is turned on again at short circuit at point 27.

The circuit (see Fig. 1) contains: a controlled head circuit breaker of the ring network line 1; current transformer (CT) 2, short-circuit current sensor (DTKZ) 3, element MEMORY 4, element DELAY 5, element REPEATER 6, element NOT 7, element OR 8, one-shot 9, element I 10, element MEMORY 11, element DELAY 12 , element REPEATER 13, element MEMORY 14, element DELAY 15, element REPEATER 16, element OR NOT 17, element I 18, element I 19, element I 20, element I 21, recording device (RU) 22, power transformer 20, power transformer 21, under the station sectional switch 22, the head switch of the first line of the ring network 23, section BID first line switch ring network 24, partition the ring network switch the second line 25, the switch points automatic transfer switch 26, a short-circuit point 27.

Diagrams of the signals at the outputs of the elements shown in figure 1, in the event of a failure of the reclosure of the head switch at short circuit at point 27, have the form (see figure 2): 28 - at the output of element 2; 29 - at the output of element 3; 30 - at the output of element 4; 31 - at the output of element 5; 32 - at the output of element 6; 33 - at the output of element 7; 34 - at the output of element 8; 35 - at the output of element 9; 36 - at the output of element 10; 37 - at the output of element 11; 38 - at the output of element 12; 39 - at the output of element 13; 40 - at the output of element 14; 41 - at the output of element 15; 42 - at the output of element 16; 43 - at the output of element 17; 44 - at the output of element 18; 45 - at the output of element 19; 46 - at the output of element 20; 47 - at the output of element 21; 48 - the availability of information in element 22; t ₁ - time of occurrence of short circuit at point 27; t ₂ - the time of the trip of the head switch; t ₃ - time point of repeated switching on of the head switch; t ₄ - time point of repeated disconnection of the head switch; t _c.z. - response time of the protection of the line head switch; t _{APB Goal} - time delay of automatic reclosure of the head line switch; t _c.z.s. - response time of the protection of the line head switch with acceleration.

Diagrams of the signals at the outputs of the elements shown in figure 1, with a successful reclosure of the head switch at short circuit at point 27, have the form (see figure 3): 49 - at the output of element 2; 50 - at the output of element 3; 51 - at the output of element 4; 52 - at the output of element 5; 53 - at the output of element 6; 54 - at the output of element 7; 55 - at the output of element 8; 56 - at the output of element 9; 57 - at the output of element 10; 58 - at the output of element 11; 59 - at the output of element 12; 60 - at the output of element 13; 61 - at the output of element 14; 62 - at the output of element 15; 63 - at the output of element 16; 64 - at the output of element 17; 65 - at the output of element 18; 66 - at the output of element 19; 67 - at the output of element 20; 68 - at the output of element 21; 69 - the availability of information in element 22; t ₁ - time of occurrence of short circuit at point 27; t ₂ - the time of the trip of the head switch; t ₃ - time point of repeated switching on of the head switch; t ₄ - time point of repeated disconnection of the head switch; t _s.z. - response time of the protection of the line head switch; t _recl. - time delay of automatic reclosure of the head line switch; t _s.z. - response time of the protection of the line head switch with acceleration.

Diagrams of the signals at the outputs of the elements shown in figure 1, with an unsuccessful reclosure of the head switch at short circuit at point 27, have the form (see figure 4): 70 - at the output of element 2; 71 - at the output of element 3; 72 - at the output of element 4; 73 - at the output of element 5; 74 - at the output of element 6; 75 - at the output of element 7; 76 - at the output of element 8; 77 - at the output of element 9; 78 - at the output of element 10; 79 - at the output of element 11; 80 - at the output of element 12; 81 - at the output of element 13; 82 - at the output of element 14; 83 - at the output of element 15; 84 - at the output of element 16; 85 - at the output of element 17; 86 - at the output of element 18; 87 - at the output of element 19; 88 - at the output of element 20; 89 - at the output of element 21; 90 - the availability of information in element 22; t ₁ - time of occurrence of short circuit at point 27; t ₂ - the time of the trip of the head switch; t ₃ - time point of repeated switching on of the head switch; t ₄ - time point of repeated disconnection of the head switch; t _c.z. - response time of the protection of the line head switch; t _recl. - time delay of automatic reclosure of the head line switch; t _c.z.s. - response time of the protection of the line head switch with acceleration.

Diagrams of the signals at the outputs of the elements shown in figure 1, in case of failure of the trip when the head switch is turned on again at short circuit at point 27, have the form (see figure 5): 91 - at the output of element 2; 92 - at the output of element 3; 93 - at the output of element 4; 94 - at the output of element 5; 95 - at the output of element 6; 96 - at the output of element 7; 97 - at the output of element 8; 98 - at the output of element 9; 99 - at the output of element 10; 100 - at the output of element 11; 101 - at the output of element 12; 102 - at the output of element 13; 103 - at the output of element 14; 104 - at the output of element 15; 105 - at the output of element 16; 106 - at the output of element 17; 107 - at the output of element 18; 108 - at the output of element 19; 109 - at the output of element 20; 110 - at the output of element 21; 111 - the availability of information in element 22; t ₁ - time of occurrence of short circuit at point 27; t ₂ - the time of the trip of the head switch; t ₃ - time point of repeated switching on of the head switch; t ₄ - time point of repeated disconnection of the head switch; t _s.z. - response time of the protection of the line head switch; t _recl. - time delay of automatic reclosure of the head line switch; t _c.z.s. - response time of the protection of the line head switch with acceleration.

The method is as follows. In normal operation, the monitored head switch 1 is turned on. At the output of TT 2 there is a certain value of the output signal (Fig. 2, diagram 28), due to the operating current, but insufficient for tripping of the DTKZ 3 and one-shot 9. The presence of the output signal from the element HE 7 at the first input of the circuit element AND 10 and the output signal OR -NE 17 at the first input of the circuit element AND 18 are insufficient for their operation (see figure 1). The circuit does not start.

When a short circuit occurs at point 27 (see Fig. 1), the output signal of TT 2 (Fig. 2, diagram 28) will be sufficient for triggering DTKZ 3, therefore, a signal appears at its output (Fig. 2, diagram 29), which will be received at the input of the MEMORY 4 element , element NOT 7, element OR NOT 17, element AND 19 and element AND 21 (see figure 1). From the output of the element NOT 7 the signal will disappear (Fig. 2 diagram 33) received at the first input of the element And 10. From the output of the element NOT-17 the signal (Fig. 2 diagram 43) disappearing at the first input of the element And 18. The presence of one input signal at the input of the elements And 19 and 21 will not lead to their operation. The signal from DTKZ 3 is stored by the element MEMORY 4 (FIG. 2 diagram 30) and is input to the element DELAY 5, from the output of which the signal will appear after a time equal to the response time of the protection of the head switch 1 (FIG. 2 diagram 31). From the output of element 5, the signal will go to the input of the REPEATER 6 element, this element will give a single pulse (Fig. 2 diagram 32), which will be transmitted to the input of the OR element 8 and to the second input of the And element 10. The OR element 8 will work (Fig. 2 diagram 34 ) and "reset" the element MEMORY 4 (Fig. 2 diagram 30). If at the same time, under the influence of overcurrent protection, the monitored head switch 1 (see Fig. 1) disconnects the short-circuit current, then with DTKZ 3 the output signal will disappear (see Fig. 2, diagram 29). In this case, the output signal from the element NOT 7 (see Fig. 2 diagram 33) at the first input of the element of the circuit And 10 and the output signal OR-NOT 17 at the first input of the element of the circuit 18. The presence of the output signal OR-NOT 17 at the first input circuit element And 14 is not enough for its operation. And the simultaneous presence of two input signals at the input of the element And 10 leads to the appearance of its output signal (figure 2 diagram 36), which will be received at the input of the element MEMORY 11, element MEMORY 14 and RU 22 (see figure 1). At the same time, information will appear in RU 22 that the main switch 1 has been disconnected in the ring network line. The signal from the element And 10 is remembered by the elements MEMORY 11 (Fig. 2 diagram 37) and MEMORY 14 (Fig. 2 diagram 40), and then it is input to the element DELAY 12 and the element DELAY 15, respectively. From the output of the element DELAY 12, the signal appears after the exposure time of the automatic reclosure of the head switch 1 (Fig. 2 diagram 38). From the output of the DELAY 15 element, the signal will appear after the countdown of the total time equal to the exposure time of the automatic reclosure of the head switch and the response time of its protection with acceleration (Fig. 2 diagram 40). The signal from element 12 will go to the input of the REPEATER 13 element, this element will give a single pulse (Fig. 2, diagram 39), which will “reset” the MEMORY 11 element and will go to one of the inputs of the elements AND 18, AND 19, AND 20 (see FIG. .one). If after the lapse of the reclosure time, switch 1 (see Fig. 1) does not turn on, then there will be no signal at the output of current transformer 2 (Fig. 2, diagram 30), sufficient for tripping of DTKZ 3 (Fig. 2, diagram 29) or a single-shot element 9 (Fig. 2 diagram 35). In this case, the output signal from the OR-NOT 17 element will be present at the first input of the And 18 circuit element. The presence of two input signals at the input of the And 18 element will lead to the appearance of its output signal (Fig. 2 diagram 44), which will arrive at RU 22 (see Fig. 1) and will ensure that there is information that there was a failure of the reclosure of the head switch installed in the ring network line. The signal from element 15 will go to the input of the REPEATER element 16, this element will give a single impulse (Fig. 2 diagram 42), which will “reset” the element MEMORY 14 and will go to the input of the element AND 21 and the element OR 8. Since in this case, there will be no signal from DTKZ 3 at the first input, then the AND 21 element will not work, and the OR 8 element will work (Fig. 2 diagram 34) and duplicate the "reset" of the MEMORY element 4. The circuit will return to the initial control state.

With a successful reclosure of the head switch at short circuit at point 27 (see Fig. 1), the output signal of TT 2 (Fig. 3, diagram 49) will be sufficient for triggering DTKZ 3, therefore, a signal appears at its output (Fig. 3, diagram 50), which will be received at the input of MEMORY 4 , element NOT 7, element OR NOT 17, element AND 19 and element AND 21 (see figure 1). From the output of the element NOT 7 the signal will disappear (Fig. 3 diagram 54), previously received at the first input of the element And 10. From the output of the element NOT-17 the signal (Fig. 3 diagram 64) disappearing at the first input of the element And 18 will disappear one input signal at the input of the elements And 19 and And 21 will not lead to their operation. The signal from DTKZ 3 is stored by the element MEMORY 4 (figure 3 diagram 51) and is fed to the input of the element DELAY 5, from the output of which the signal appears after a time equal to the response time of the protection of the head switch 1 (figure 3 diagram 52). From the output of element 5, the signal will go to the input of the REPEATER 6 element, this element will give a single pulse (Fig. 3 diagram 53), which will be transmitted to the input of the OR element 8 and to the second input of the And element 10. The OR element 8 will work (Fig. 3 diagram 55 ) and "reset" the element MEMORY 4 (Fig. 3 diagram 51). If at the same time, under the influence of overcurrent protection, the monitored head switch 1 (see Fig. 1) switches off the short-circuit current, then with DTKZ 3 the output signal will disappear (see Fig. 3, diagram 50). In this case, the output signal from the element NOT 7 (see Fig. 3 diagram 54) appears at the first input of the element of the circuit And 10 and the output signal OR-NOT 17 at the first input of the element of the circuit And 18. The presence of the output signal OR-NOT 17 at the first input circuit element And 14 is not enough for its operation. And the simultaneous presence of two input signals at the input of the element And 10 leads to the appearance of its output signal (Fig. 3 diagram 57), which will be received at the input of the element MEMORY 11, element MEMORY 14 and in RU 22 (see Fig. 1). At the same time, information will appear in RU 22 that the main switch 1 has been disconnected in the ring network line. The signal from the element And 10 is stored by the elements MEMORY 11 (Fig. 3 diagram 58) and MEMORY 14 (Fig. 3 diagram 61), and then it is input to the element DELAY 12 and the element DELAY 15, respectively. From the output of the element DELAY 12, the signal appears after the exposure time of the automatic reclosure of the head switch 1 (Fig.3 diagram 59). From the output of the DELAY 15 element, the signal will appear after the countdown of the total time equal to the exposure time of the automatic reclosure of the head switch and the response time of its protection with acceleration (Fig. 3 diagram 62). The signal from element 12 will go to the input of the REPEATER 13 element, this element will give a single pulse (Fig. 3 diagram 60), which will "reset" the MEMORY element 11 and will go to one of the inputs of the elements And 18, And 19, And 20 (see Fig. .one). After the time delay of the automatic reclosure of the head switch, its switch 1 (see figure 1) will turn on. And if at point 27 there was an unstable short-circuit, then at the output of the TT 2 there will be a signal (Fig. 3 diagram 49), not sufficient for the triggering of the DTKZ 3 (Fig. 3 diagram 50), but sufficient for the operation of the one-shot 9 (Fig. 3). 3 diagram 56), which will be input to the elements of OR-NOT 17 and AND 20. At the output of the element OR-NOT 17, signal 3 will disappear (Fig. 3 diagram 64), which is fed to the first input of the element And 18. The presence of two input signals at the input element And 20 will lead to the appearance of its output signal (figure 3 diagram 67), which will go to RU 22 (see figure 1) and ensure the availability of information there that there was a successful reclosure of the head switch installed in the ring network line. The signal from element 15 will go to the input of the REPEATER element 16, this element will give a single impulse (Fig. 3 diagram 62), which will “reset” the element MEMORY 14 and will go to the input of the element AND 21 and the element OR 8. Since in this case, there will be no signal from DTKZ 3 at the first input, then the And 21 element will not work. The OR element 8 will work (Fig. 3, diagram 55) and will duplicate the "reset" of the MEMORY element 4. The circuit will return to the initial state of control.

In case of unsuccessful reclosure of the head switch at short circuit at point 27 (see Fig. 1), the output signal of TT 2 (Fig. 4, diagram 70) will be sufficient for triggering DTKZ 3, therefore, a signal appears at its output (Fig. 4, diagram 71), which will be received at the input of MEMORY 4 , element NOT 7, element OR NOT 17, element AND 19 and element AND 21 (see figure 1). From the output of the element NOT 7, the signal (figure 4 of the diagram 75) disappears at the first input of the element And 10. From the output of the element NOT-17 the signal (figure 4 of the diagram 85) disappears at the first input of the element And 18. The presence of one input signal at the input of the elements And 19 and 21 will not lead to their operation. The signal from DTKZ 3 is stored by the element MEMORY 4 (Fig. 4, diagram 72) and is fed to the input of the element DELAY 5, from the output of which the signal will appear after a time equal to the response time of the protection of the head switch 1 (Fig. 4, diagram 73). From the output of element 5, the signal will go to the input of the REPEATER 6 element, this element will give a single pulse (Fig. 4 diagram 74), which will be transmitted to the input of the OR element 8 and to the second input of the And element 10. The OR element 8 will work (Fig. 4 diagram 76 ) and "reset" the element MEMORY 4 (Fig. 4 diagram 72). If at the same moment, under the influence of overcurrent protection, the monitored head switch 1 (see Fig. 1) disconnects the short-circuit current, then with DTKZ 3 the output signal will disappear (see Fig. 4, diagram 71). There will be an output signal from the element NOT 7 (see Fig. 4 diagram 75) at the first input of the AND element 10 and the output signal of the OR-NOT 17 element at the first input of the AND element 18. The presence of the output signal from the OR element NOT 17 at the first input circuit element And 14 is not enough for its operation. And the simultaneous presence of two input signals at the input of the element And 10 leads to the appearance of its output signal (figure 4 diagram 78), which will be received at the input of the element MEMORY 11, element MEMORY 14 and RU 22 (see figure 1). At the same time, information will appear in RU 22 that the main switch 1 has been disconnected in the ring network line. The signal from the element And 10 is remembered by the elements MEMORY 11 (Fig. 4 diagram 79) and MEMORY 14 (Fig. 4 diagram 82), and then it is input to the element DELAY 12 and the element DELAY 15, respectively. From the output of the element DELAY 12, the signal appears after the exposure time of the automatic reclosure of the head switch 1 (Fig. 4 diagram 80). From the output of the DELAY 15 element, the signal will appear after the countdown of the total time equal to the exposure time of the automatic reclosure of the head switch and the response time of its protection with acceleration (Fig. 4 diagram 83). The signal from element 12 will go to the input of the REPEATER 13 element, this element will give a single impulse (Fig. 4, diagram 81), which will "reset" the MEMORY 11 element and will go to one of the inputs of the elements And 18, And 19, And 20 (see Fig. .one). After the time delay of the automatic reclosure of the head switch, its switch 1 (see figure 1) will turn on. And if at point 27 there is a stable short-circuit, then at the output of the TT 2 there will be a signal (Fig. 4 diagram 70), sufficient for the triggering of DTKZ 3 (Fig. 4 diagram 71). In this case, the one-shot 9 will not work (Fig. 4 diagram 77). From the output of DTKZ 3, the signal will go to the input of the element MEMORY 4, element NOT 7, element OR NOT 17, element AND 19 and element And 21 (see figure 1). From the output of the element NOT 7, the signal (figure 4 of the diagram 75) disappearing at the first input of the element And 10. From the output of the element NOT-17 the signal (figure 4 of the diagram 85) disappearing at the first input of the element And 18. The presence of one input signal at the input And 21 will not lead to its operation (figure 4 diagram 89). The presence of two input signals at the input of the element And 19 from the elements DTKZ 3 and REPEATER 13 (see above) will lead to its operation. At the output And 19, a signal will appear (Fig. 4, diagram 87), which will go to the switchgear 22 (see Fig. 1) and ensure that there is information that the automatic reclosure of the head switch installed in the ring network failed. The signal from element 15 will go to the input of the REPEATER element 16, this element will give a single impulse (Fig. 4 diagram 84), which will “reset” the element MEMORY 14 and will go to the input of the element AND 21 and the element OR 8. Since at the second inrush short-circuit the signal from DTKZ 3 will again be remembered by the element MEMORY 4 and then the DELAY 5 element may trigger, the signal from the output of which will go to the input of the REPEATER 6 element, and from it to the input of the And 10 element (see Fig. 1). In this case, the signal will appear after a time equal to the response time of the protection of the monitored head switch 1 (Fig. 4, diagram 73), and if the automatic reclosure is unsuccessful, the monitored head switch 1 (see Fig. 1) will turn off with acceleration, and the signal from the element NOT 7 will appear on input element And 10 in time earlier than when you turn off the first inrush short circuit Therefore, to exclude the repeated operation of the And 10 element, when the second short-circuit current is short-circuited, the signal from the REPEATER 16 element (see Fig. 4, diagram 84) will go to the input of the OR element 8 and will lead to the appearance of a signal at its output (see Fig. 4, diagram 76). In this case, the signal from the output of the OR element 8 will “reset” the MEMORY element 4 (see Fig. 1). Therefore, at the input of the element And 10, after turning off the second inrush current short circuit, there will be only one input signal coming from the element NOT 7, and therefore there will be no signal at its output (Fig. 4 diagram 78). Therefore, in RU 22 there will be information that at first the controlled head switch was turned off, and then its unsuccessful reclosure. The circuit will return to the initial state of control.

In case of failure of shutdown after repeated switching on of the head switch at short circuit at point 27 (see FIG. 1), the output signal of TT 2 (FIG. 5, diagram 91) will be sufficient to trigger DTKZ 3, therefore, a signal appears at its output (FIG. 5, diagram 92), which will be received at the input of the MEMORY 4 element , element NOT 7, element OR NOT 17, element AND 19 and element AND 21 (see figure 1). From the output of the element NOT 7, the signal (Fig. 5 diagram 96) disappearing at the first input of the element And 10. From the output of the element NOT-17 the signal (Fig. 5 diagram 106) disappearing at the first input of the element And 18. The presence of one input signal at the input of the elements And 19 and 21 will not lead to their operation. The signal received at the element MEMORY 4 (figure 5, diagram 93) is stored by it and fed to the input of the element DELAY 5, from the output of which the signal appears after a time equal to the response time of the protection of the head switch 1 (figure 5, diagram 94). From the output of element 5, the signal will go to the input of the REPEATER 6 element, this element will give a single pulse (Fig. 5 diagram 95), which will be transmitted to the input of the OR element 8 and to the second input of the And element 10. The OR element 8 will work (Fig. 5 diagram 97 ) and "reset" the element MEMORY 4 (Fig. 5 diagram 93). If at the same time, under the influence of overcurrent protection, the monitored head switch 1 (see Fig. 1) disconnects the short-circuit current, then with DTKZ 3 the output signal will disappear (see Fig. 5, diagram 92). There will be an output signal from the element NOT 7 (see Fig. 5 diagram 96) at the first input of the AND element 10 and the output signal of the OR-NOT 17 element at the first input of the AND element 18. The presence of the output signal from the OR element NOT 17 at the first input circuit element And 14 is not enough for its operation. And the simultaneous presence of two input signals at the input of the element And 10 leads to the appearance of its output signal (Fig. 5 diagram 99), which will be received at the input of the element MEMORY 11, element MEMORY 14 and in RU 22 (see Fig. 1). At the same time, information will appear in RU 22 that the main switch 1 has been disconnected in the ring network line. The signal from the element And 10 is stored by the elements MEMORY 11 (Fig. 5 diagram 100) and MEMORY 14 (Fig. 5 diagram 103), and then it is input to the element DELAY 12 and the element DELAY 15, respectively. From the output of the element DELAY 12, the signal appears after the exposure time of the automatic reclosure of the head switch 1 (Fig. 5 diagram 101). From the output of the DELAY 15 element, the signal will appear after the countdown of the total time equal to the exposure time of the automatic reclosure of the head switch and the response time of its protection with acceleration (Fig. 5 diagram 104). The signal from element 12 will go to the input of the REPEATER 13 element, this element will give a single impulse (Fig. 5 diagram 102), which will "reset" the MEMORY element 11 and go to one of the inputs of the elements And 18, And 19, And 20 (see Fig. .one). After the time delay of the automatic reclosure of the head switch, its switch 1 (see figure 1) will turn on. And if at point 27 there is a stable short-circuit, then at the output of the TT 2 there will be a signal (Fig. 5 diagram 91), sufficient for the triggering of DTKZ 3 (Fig. 5 diagram 92). In this case, the one-shot 9 will not work (figure 5, diagram 98). From the output of DTKZ 3, the signal will go to the input of the element MEMORY 4, element NOT 7, element OR NOT 17, element AND 19 and element And 21 (see figure 1). From the output of the element NOT 7, the signal (Fig. 5 diagram 96) disappearing at the first input of the element And 10. From the output of the element NOT-17 the signal (Fig. 5 diagram 106) disappearing at the first input of the element And 18. The presence of one input signal at the input AND 18 from the element REPEATER 13 will not lead to its operation (figure 5 diagram 107). The presence of two input signals at the input of element And 19 from the elements DTKZ 3 and REPEATER 13 (see above) will lead to its operation. At the output And 19, a signal will appear (Fig. 5, diagram 108), which will go to the switchgear 22 (see Fig. 1) and ensure that there is information that the automatic reclosure of the head switch installed in the ring network failed. After the total time equal to the exposure time of the reclosure of the head switch and the response time of its protection with acceleration. the signal from the DELAY element 15 (Fig. 5 diagram 104) will be input to the REPEATER element 16, this element will give a single pulse (Fig. 5 diagram 105), which will “reset” the MEMORY element 14 and will go to the input of the AND element 21 and the OR element 8 Because at the second inrush short-circuit the signal from DTKZ 3 will be remembered again by the element MEMORY 4, then the element DELAY 5 may work, etc. (see above). Therefore, to exclude the repeated operation of the AND 10 element, in case of failure to turn off the head switch 1 when it is turned on again at a stable short circuit, the signal from the REPEATER element 16 (see Fig. 5, diagram 105) will go to the input of the OR element 8 and will cause signal at its output (see figure 5, diagram 97). In this case, the signal from the output of the OR element 8 will “reset” the MEMORY element 4 (see Fig. 1). Therefore, at the input of the element And 10 there will be only one input signal coming from the element NOT 7, and therefore there will be no signal at its output (Fig. 5 diagram 96). If at this time the head switch 1 for some reason does not turn off the second inrush short-circuit current, then the presence of two signals at the inputs of the element And 21 from the elements DTKZ 3 and REPEATER 16 will lead to its operation (figure 5 diagram 110). And at its output there will be a signal that will go to RU 22. At the same time, information will appear in RU 22 that the automatic reclosure of the main switch on the short circuit has failed. and its subsequent failure to turn off when it is turned back on, and the circuit will return to the initial state of control.

Thus, the method allows you to receive timely information about the state of the head switch in the line of the ring network, powered by the buses of a two-transformer substation. This will lead to an increase in the reliability of power supply to consumers through the adoption of necessary decisions based on the information received by operational personnel.

Claims (1)

A method for monitoring changes in the state of the head switch in a ring network line powered by two-transformer substation buses, which consists in fixing the inrush currents and measuring the time between them, characterized in that from the moment the inrush current of the short circuit occurs (short circuit) at the beginning of the sectioned line of the ring network, the time equal to the response time of the protection of the line head circuit breaker is counted, while the instantaneous inrush trip is short-circuited, and if the end of the countdown coincides with the moment of disconnection If the first inrush current is short-circuited, then the fact of disconnecting the head switch is established, and then from the moment the first inrush current is short-circuited start the countdown time of automatic restart (AR) of the head switch and the countdown of the total time equal to the shutter speed of the reclosure of the head switch and the response time of its protection with acceleration, they control the appearance of the second inrush current and if there is no second surge at the end of the countdown of the reclosure time current value is greater than the normal operating, but less than the short-circuit current or equal to the short-circuit current, then the fact of the automatic reclosure failure of the head circuit breaker of the ring network line is established, or at the end of the countdown of the automatic reclosure time, a second current surge occurs with a value greater than the normal operating current, but less than the short-circuit current, then the fact of successful reclosure of the main circuit breaker of the ring network, and if there is a second inrush short-circuit current at the end of the countdown of the AR delay time, then the fact of the unsuccessful AR of the head circuit breaker of the ring network line is established, and then, if after the appearance of the second inrush short circuit when the countdown of the total time ends, the second short-circuit current fault does not trip, then the fact of failure to turn off the head switch when it is turned on again is established.

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