RU2305356C1 - Method for checking circuit breakers of ring-circuit sectionalized line for successful and unsuccessful automatic reclosure - Google Patents

Abstract

FIELD: automatic control of electric circuits.

SUBSTANCE: proposed method involves recording of inrush short-circuit current and readout of time equal to protective gear operating time of each circuit breaker installed in sectionalized line from moment of its occurrence at origin of ring-circuit sectionalized line; in the process moment of inrush short-circuit current disconnection is checked and if moment of protective-gear operating time readout termination in one of circuit breakers coincides with moment of inrush short-circuit current disconnection time, open circuit breaker is detected and then reading of time equal to automatic reclosure delay of open circuit breaker is started from moment of disconnection of first short-circuit inrush current; occurrence of second inrush current is checked in the process and if it is found higher than normal operating current but lower than short-circuit current at moment of automatic reclosure delay readout termination, fact of successful automatic reclosure of disconnected circuit breaker installed in ring-circuit sectionalized line is stated; if it is higher than or equal to short-circuit current, fact of automatic reclosure failure in open circuit breaker installed in ring-circuit sectionalized line is stated.

EFFECT: enlarged functional capabilities.

1 cl, 5 dwg

Description

The invention relates to the automation of electrical networks and is intended to control the successful and unsuccessful automatic restart (AR) of circuit breakers with a one-time automatic reclosure device installed in a sectioned line of a ring network powered by buses of a two-transformer substation.

A known method of obtaining information about the result of the automatic restart of the sectioning apparatus, which consists in fixing the inrush current of the short circuit (short circuit), measuring the time after it disappears before the appearance of the second inrush current and monitoring the on position of the switch at the beginning of the line after the disappearance of the first inrush current .z. with the subsequent measurement of the magnitude of the second inrush, and if it is greater than the normal operating current, but less than the short-circuit current, a successful automatic restart is detected, and if it is equal to or greater than the short-circuit current unsuccessful [Auth. St. No. 851644, Cl. H02J 13/00, 1981].

The disadvantage of this method is the impossibility of implementing, using its control, successful and unsuccessful automatic reclosure switches in a sectioned line of a ring network powered by buses of a two-transformer substation.

The objective of the invention is to expand the functionality of the method by obtaining information about the successful and unsuccessful reclosure of circuit breakers in a sectioned line of a ring network powered by buses of a two-transformer substation.

According to the proposed method, the occurrence of an inrush short-circuit is detected. at the beginning of the partitioned line caused by short circuit in line. From the moment of the appearance of an inrush short-circuit start a time counting equal to the response time of the protection of each switch installed in the partitioned line of the ring network, and at the same time control the moment of disconnection of the inrush current short circuit If the end time of the protection operation time of one of the circuit breakers coincides with the moment of switching off the inrush current, then the disconnected circuit breaker is determined. And then, from the moment of disconnection of the first short-circuit current surge, a countdown begins, equal to the exposure time of the automatic reclosure circuit breaker, while the appearance of the second current surge is controlled. And if, when the second inrush appears, at the end of the countdown of the reclosure time of this switch, it is more than the normal operating current, but less than the short-circuit current, then the fact of successful reclosure of the disconnected switch is established, and if it is greater than or equal to the current k. h. - unsuccessful automatic reclosure of a tripped circuit breaker installed in a partitioned line of a ring network.

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, with a successful reclosure of a sectioning switch with short circuit at point 36 (see figure 1);

figure 3 - diagrams of the signals at the outputs of the elements shown in figure 1, with an unsuccessful reclosure of a sectioning switch at short circuit at point 36;

figure 4 - 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 37;

figure 5 is a diagram 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 37.

The circuit (see Fig. 1) contains: a power transformer 1, a power transformer 2, a sectional section switch 3, a head switch of the first line of the ring network 4, a head switch of the second line of the ring network 5, a sectional switch of the first line of the ring network 6, a sectional switch of the second ring network lines 7, automatic transfer switch 8 switch, current transformer (CT) 9, short-circuit current sensor (DTKZ) 10, element BAN 11, element MEMORY 12, element MEMORY 13, element DELAY 14, element ON SECONDARY 15, OR element 16, MEMORY element 17, DELAY element 18, REPEATER element 19, NOT element 20, one-shot 21, AND 22 element, AND 23 element, MEMORY 24 element, DELAY 25 element, REPEATER element 26, MEMORY element 27, DELAY element 28, REPEATER element 29, AND element 30, AND 31 element, AND 32 element, AND 33 element, OR 34 element, recording device (RU) 35, short circuit point 36, point short-circuit 37.

Diagrams of the signals at the outputs of the elements shown in figure 1, with a successful automatic reclosure sectioning switch with short circuit at point 36, have the form (see figure 2): 38 - at the output of element 9; 39 - at the output of element 10; 40 - at the output of element 11; 41 - at the output of element 12; 42 - at the output of element 13; 43 - at the output of element 14; 44 - at the output of element 15; 45 - at the output of element 16: 46 - at the output of element 17; 47 - at the output of element 18; 48 - at the output of element 19; 49 - at the output of element 20; 50 - at the output of element 21; 51 - at the output of element 22; 52 - at the output of element 23; 53 - at the output of element 24; 54 - at the output of element 25; 55 - at the output of element 26; 56 - at the output of element 27; 57 - at the output of element 28; 58 - at the output of element 29; 59 - at the output of element 30; 60 - at the output of element 31; 61 - at the output of element 32; 62 - at the output of element 33; 63 - at the output of element 34; 64 - the availability of information in element 35; t _{s.s. sec} - response time of the protection of the sectionalizing circuit breaker; t _s.z. - response time of the protection of the line head switch; t _АПВсек - time delay of automatic reclosure of a sectioning line circuit breaker; t _recl. - time delay of automatic reclosure of the head line switch; t _s.z.sc. - response time of the sectionalizing line circuit breaker protection with acceleration; t _s.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 an unsuccessful reclosure of a sectioning switch at short circuit at point 36, have the form (see figure 3): 65 - at the output of element 9; 66 - at the output of element 10; 67 - at the output of element 11; 68 - at the output of element 12; 69 - at the output of element 13; 70 - at the output of element 14; 71 - at the output of element 15; 72 - at the output of element 16; 73 - at the output of element 17; 74 - at the output of element 18; 75 - at the output of element 19; 76 - at the output of element 20; 77 - at the output of element 21; 78 - at the output of element 22; 79 - at the output of element 23; 80 - at the output of element 24; 81 - at the output of element 25; 82 - at the output of element 26; 83 - at the output of element 27; 84 - at the output of element 28; 85 - at the output of element 29; 86 - at the output of element 30; 87 - at the output of element 31; 88 - at the output of element 32; 89 - at the output of element 33; 90 - at the output of element 34; 91 - the availability of information in element 35; t _{s.s. sec} - response time of the protection of the sectionalizing circuit breaker; t _s.z. - response time of the protection of the line head switch; t _АПВсек - time delay of automatic reclosure of a sectioning line circuit breaker; t _recl. - time delay of automatic reclosure of the head line switch; t _ssu.sec - response time of the sectionalizing line circuit breaker protection with acceleration; t _s.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 37, they have the form (see figure 4): 92 - at the output of element 9; 93 - at the output of element 10; 94 - at the output of element 11; 95 - at the output of element 12; 96 - at the output of element 13; 97 - at the output of element 14; 98 - at the output of element 15; 99 - at the output of element 16; 100 - at the output of element 17; 101 - at the output of element 18; 102 - at the output of element 19; 103 - at the output of element 20; 104 - at the output of element 21; 105 - at the output of element 22; 106 - at the output of element 23; 107 - at the output of element 24; 108 - at the output of element 25; 109 - at the output of element 26; 110 - at the output of element 27; 111 - at the output of element 28; 112 - at the output of element 29; 113 - at the output of element 30; 114 - at the output of element 31; 115 - at the output of element 32; 116 - at the output of element 33; 117 - at the output of element 34; 118 - the presence of information in element 35; t _{s.s. sec} - response time of the protection of the sectionalizing circuit breaker; t _s.z. - response time of the protection of the line head switch; t _АПВсек - time delay of automatic reclosure of a sectioning line circuit breaker; t _recl. - time delay of automatic reclosure of the head line switch; t _ssu.sec - response time of the sectionalizing line circuit breaker protection with acceleration; t _s.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 an unsuccessful reclosure of the head switch at short circuit at point 37, have the form (see figure 5): 119 - at the output of element 9; 120 - at the output of element 10; 121 - at the output of element 11; 122 - at the output of element 12; 123 - at the output of element 13: 124 - at the output of element 14; 125 - at the output of element 15; 126 - at the output of element 16; 127 - at the output of element 17; 128 - at the output of element 18; 129 - at the output of element 19; 130 - at the output of element 20; 131 - at the output of element 21; 132 - at the output of element 22; 133 - at the output of element 23; 134 - at the output of element 24; 135 - at the output of element 25; 136 - at the output of element 26; 137 - at the output of element 27; 138 - at the output of element 28; 139 - at the output of element 29; 140 - at the output of element 30; 141 - at the output of element 31; 142 - at the output of element 32; 143 - at the output of element 33; 144 - at the output of element 34; 145 - the availability of information in element 35; t _{s.s. sec} - response time of the protection of the sectionalizing circuit breaker; t _s.z. - response time of the protection of the line head switch; t _АПВсек - time delay of automatic reclosure of a sectioning line circuit breaker; t _recl. - time delay of automatic reclosure of the head line switch; t _ssu.sec - response time of the sectionalizing line circuit breaker protection with acceleration; t _s.z.s. - the response time of the protection of the line head switch with acceleration.

The method is as follows. In normal mode, switches 4 and 6 are on. At the output of TT 9 there is a certain value of the output signal (see Fig. 2, 3, 4, 5 diagram 38, 65, 92, 119 time interval t ₀ -t ₁ ), due to the operating current, but insufficient for the operation of DTKZ 10 and a single-shot 21, therefore, the presence of the output signal from the element NOT 20 at one of the inputs of the elements of the circuit And 22 and 23 is not enough for their operation. The circuit does not start and is in a state of control.

When short at point 36 (see Fig. 1), the output signal of TT 9 (Fig. 2, diagram 38) will be sufficient for triggering of DTKZ 10, therefore, a signal appears at its output (Fig. 2, diagram 39), which will be input to the elements BAN 11 , NOT 20, AND 30 and AND 32 (see figure 1). At the same time, a signal appears at the output of the BANS 11 element (figure 2, diagram 40), the signal disappears from the output of the element NOT 20 (figure 2, diagram 49), and the presence of only one input signal at the input of the elements And 30 and 32 will not lead to them triggered. The signal from the element BAN 11 will be remembered by the elements MEMORY 13 and MEMORY 17 (Fig. 2, diagrams 42.46) and will be input to the elements DELAY 14 and DELAY 18. From the output of the element DELAY 14, the signal will appear after a time equal to the response time from the protection of the partition switch 6 (see figure 2, the time interval is t ₁ -t ₂ ), and from the output of the DELAY 18 element, the signal appears after a time equal to the response time of the protection of the head switch 4 (see figure 2, the time interval is t ₁ -t ₃ ). After counting the response time of the protection of the sectioning switch, the signal from the output of element 14 (Fig. 2 diagram 43) will be input to the REPEATER element 15, this element will give a single pulse (Fig. 2 diagram 44), which will be input to the element MEMORY 12, to the input of the element And 22 will also “reset” the element MEMORY 13. This signal will be remembered by the element MEMORY 12, the output of which the signal (Fig. 2 diagram 41) will go to the inhibitory input of the element 11. At the output of the element BAN 11, the signal will disappear (Fig. 2 diagram 40). If at the same time under the influence of overcurrent protection, the controlled sectionalizing switch 6 (see Fig. 1) disconnects the short-circuit current, then the output signal will disappear from DTKZ 10 (see Fig. 2, diagram 38). In this case, a signal will appear at the output from the element NOT 20 (Fig. 2, diagram 49), which will be fed to the input of the elements And 22 and And 23. The simultaneous presence of two input signals at the input of the element And 22 will lead to the appearance of its output signal (Fig. 2 diagram 51), which will go to the input of OR 16 and MEMORY 24. At the output of element 16, a signal will appear (Fig. 2 diagram 45), which will "reset" the MEMORY element 17 (Fig. 2 diagram 46). In this case, from the output of the DELAY 18 element, the signal will not appear (Fig. 2 diagram 47) and the REPEATER 19 element will not work (Fig. 2 diagram 48). Therefore, the presence of one input signal on the element And 23 does not lead to its operation (figure 2 diagram 52) and the circuit automatically determines the disconnection of the sectionalizing line switch. The signal from element 22 is stored by the element MEMORY 24 (Fig. 2, diagram 53) and fed to the input of the element DELAY 25, from the output of which the signal will appear after a time equal to the exposure time of the automatic reclosure sectioning switch (Fig. 2 diagram 54 time interval t ₂ -t ₄ ) The signal from element 25 will go to the input of the REPEATER element 26, this element will give a one-time pulse (Fig. 2 diagram 55), which will “reset” the element MEMORY 24 and will go to the input of the elements I 30 and I 31. After the time-out of the automatic reclosure sectioning switch switch 6 (see figure 1) will turn on. And if at point 36 there was an unstable short-circuit, then at the output of TT 9 there will be a signal (Fig. 2 diagram 38, time moment t ₄ ) not sufficient for triggering DTKZ 10 (Fig. 2 diagram 39), but sufficient for triggering a single-shot 21 (figure 2 diagram 50), which will be input to the elements And 31 and And 33. The simultaneous presence of two input signals at the input of the element And 31 will lead to the appearance of its output signal (figure 2 diagram 60), which will be received at the input of the element OR 34 and in RU 35. At the output of the OR 34 element, a signal will appear (Fig. 2 diagram 63). This signal will “reset” the MEMORY 12 element (Fig. 2, diagram 41) and the signal will disappear at the inhibitory input of the element 11 (see Fig. 1). The circuit will return to its original state of control. Information will appear in RU 35 (Fig. 2, diagram 64) that a successful automatic reclosure of the sectioning switch 6 installed in the sectioned line of the ring network has occurred.

If short-circuit at point 36 will be stable, the sequence of operation of the circuit will be similar to the above-described operation of the circuit according to figure 2 until time t ₄ (see figure 3). Because after the time delay of the automatic reclosure of the sectioning switch, its switch 6 is turned on, and at the point 36 it is stable short-circuit, then at the output of the CT 9 there will be a signal (Fig.3 diagram 65), sufficient for the DTKZ 10 to operate (Fig.3 diagram 66 moment of time t ₄ ). At the output of the DTKZ 10, a signal appears that will go to the input of the elements BAN 11, NOT 20, AND 30 and AND 32 (see figure 1). At the same time, the output element BAN 11 signal will not appear (figure 3 diagram 67), because there is a signal at its inhibitory input from the element MEMORY 12 (Fig. 3 diagram 68). From the output of the element NOT 20, the signal will disappear (Fig. 3, diagram 76), and the presence of only one input signal at the input of the And 32 element will not lead to its operation. The simultaneous presence of two signals from the elements 26 and 10 (see above) on the element And 30 will lead to the appearance of a signal at its output (figure 3 diagram 30). This signal will be received at the input of the OR 34 element and in RU 35. At the output of the OR 34 element, a signal will appear (Fig. 3, diagram 90). This signal will “reset” the MEMORY 12 element (Fig. 3, diagram 68) and the signal will disappear at the inhibitory input of the element 11 (see Fig. 1). The circuit will return to its original state of control. In RU 35, information will appear (Fig. 3, diagram 91) that an automatic reclosure of the sectioning switch 6 installed in the sectioned line of the ring network has failed.

When short at point 37 (see Fig. 1), the output signal of TT 9 (Fig. 4, diagram 92) will be sufficient for triggering DTKZ 10, therefore, a signal appears at its output (Fig. 4, diagram 93), which will be input to the elements BAN 11 , NOT 20, AND 30 and AND 32 (see figure 1). At the same time, a signal will appear at the output of the BANS 11 element (figure 4, diagram 94), the signal will disappear from the output of the element NOT 20 (figure 4 is diagram 103), and the presence of only one input signal at the input of the elements And 30 and And 32 will not lead to them triggered. The signal from the element BAN 11 will be remembered by the elements MEMORY 13 and MEMORY 17 (figure 4 of the diagram 96,100) and will be input to the elements of DELAY 14 and DELAY 18. From the output of the element DELAY 14, a signal will appear (figure 4 of diagram 97) after a time equal to the response time protection sectioning switch 6 (see Fig.4 time interval t ₁ -t ₂ ), and from the output of the DELAY 18 signal appears (Fig.4 diagram 101) after a time equal to the response time of the protection of the head switch 4 (see Fig.4 time interval t ₁ -t ₃ ). After counting the response time of the protection of the sectioning switch, the signal from the output of element 14 (Fig. 4, diagram 97) will be input to the REPEATER element 15, this element will give a single pulse (Fig. 4, diagram 98), which will receive the input of the MEMORY 12 element to the input of the And element 22 and will "reset" the element MEMORY 13. This signal is remembered by the element MEMORY 12, from the output of which the signal (Fig. 4, diagram 95) will go to the inhibitory input of the element 11. At the output of the element BAN 11, the signal will disappear (Fig. 4, diagram 94). Because at this moment at the input of element And 22 there is no second input signal from the element NOT 20 (see figure 4 diagram 103), then there will be no signal at its output (figure 4 diagram 105). After counting the response time of the protection of the head switch, the signal from the output of element 18 (Fig. 4, diagram 101) will be fed to the input of the REPEATER 19 element, this element will give a single pulse (Fig. 4, diagram 102), which will be input to the OR element 16 and to the input of the And element 22. The OR element 16 will work and a signal will appear at its output (Fig. 4, diagram 99), which will “reset” the MEMORY element 17. If at this moment, under the influence of overcurrent protection, the monitored head switch 4 (see Fig. 1) disconnects the current to .z., then at the output of DTKZ 10 the signal will disappear (see 4, diagram 93). In this case, a signal appears at the output of the element NOT 20 (Fig. 4 diagram 103, time moment t ₃ ), which will be fed to the input of the elements And 22 and And 23. The simultaneous presence of two input signals at the input of the element And 23 will lead to the appearance of its output signal (Fig. .4 diagram 106). Because at this moment at the input of element And 22 there will be no input signal from the REPEATER element 15 (see figure 4 diagram 98), then the signal will not appear on its output (figure 4 diagram 105) and the circuit will automatically detect the shutdown of the line head switch . The signal from element 23 is stored by the element MEMORY 27 (Fig. 4, diagram 110) and is input to the element DELAY 28, from the output of which the signal will appear after a time equal to the exposure time of the automatic reclosure of the head switch (Fig. 4, diagram 111, time interval t ₃ -t ₆ ) The signal from element 28 will go to the input of the REPEATER element 29, this element will give a single impulse (Fig. 4, diagram 112), which will “reset” the MEMORY element 27 and will go to the input of the I 32 and I 33 elements. After the lapse of the reclosure time of its head switch switch 4 (see figure 1) will turn on. And if at point 37 there was an unstable short-circuit, then at the output of the TT 9 there will be a signal (Fig. 4 diagram 92 moment of time t ₆ ), insufficient for the operation of the DTKZ 10 (Fig. 4 diagram 93), but sufficient for the operation of the single-shot 21 (figure 4 diagram 104), which will be input to the elements And 31 and And 33. The simultaneous presence of two input signals at the input of the element And 33 will lead to the appearance of its output signal (figure 4 diagram 116), which will be received at the input of the element OR 34 and in RU 35. At the output of the OR 34 element, a signal will appear (Fig. 4, diagram 117). This signal will “reset” the MEMORY 12 element (Fig. 4, diagram 95) and the signal will disappear at the inhibitory input of the element 11 (see Fig. 1). The circuit will return to its original state of control. In RU 35, information will be present (Fig. 4, diagram 118) that a successful reclosure of the head switch 4 installed in the partitioned line of the ring network has occurred.

If short-circuit at point 37 will be stable, the sequence of operation of the circuit will be similar to the above-described operation of the circuit according to figure 4 until time t ₆ (see figure 5). Because after the time delay of the automatic reclosure of the head switch, its switch 4 will turn on, and at point 37 there will be a stable short circuit, then at the output of the CT 9 there will be a signal (Fig. 5 diagram 119), sufficient for the DTKZ 10 to operate (Fig. 5 diagram 120 moment time 1 ₆ ). At the output of the DTKZ 10, a signal appears that will go to the input of the elements BAN 11, NOT 20, AND 30 and AND 32 (see figure 1). At the same time, the signal does not appear at the output of the BAN 11 element (Fig. 5 diagram 121), because there will be a signal at its inhibitory input from the element MEMORY 12 (Fig. 5, diagram 122). From the output of the element NOT 20, the signal will disappear (figure 5 diagram 130), and the presence of only one input signal at the input of the element And 30 will not lead to its operation. The simultaneous presence of two signals from the elements 29 and 10 (see above) on the element And 32 will lead to the appearance of a signal at its output (figure 5 diagram 142). This signal will be received at the input of the OR 34 element and in RU 35. At the output of the OR 34 element, a signal will appear (Fig. 5, diagram 144). This signal will “reset” the MEMORY 12 element (Fig. 5, diagram 122) and the signal will disappear at the inhibitory input of the element 11 (see Fig. 1). The circuit will return to its original state of control. In RU 35, information will appear (Fig. 5, diagram 145) that an automatic reclosure of the head switch 4 has been unsuccessful, installed in a sectioned line of the ring network.

Thus, the method allows to obtain timely information about the successful and unsuccessful reclosure of circuit breakers in a partitioned line of a ring network powered by 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 the successful and unsuccessful automatic restart (AR) of circuit breakers in a sectioned line of a ring network powered by two-transformer substation buses, which consists in fixing the inrush currents and in measuring the time between them, characterized in that from the moment of the appearance of the inrush current short circuit (to. h.) at the beginning of the partitioned line of the ring network, the time equal to the response time of the protection of each switch installed in the partitioned line is counted, while the moment of tripping is monitored Nia throws a short circuit current, and if the end timing protection operation of a switch coincides with the throw off short-circuit current, the switch is disconnected is determined, and further since the first disable inrush current Isc they begin to count down the time equal to the AR time of the opener of the tripped circuit breaker, while controlling the appearance of the second inrush current, and if, when it appears at the end of the countdown of the AR time of the circuit breaker, it is greater than the normal operating current, but less than the short-circuit current, then the fact is established successful reclosure of a tripped circuit breaker, and if it is greater than or equal to the short-circuit current - unsuccessful automatic reclosure of a tripped circuit breaker installed in a partitioned line of a ring network.

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