RU2640353C1 - Method of protection from the receiving side of two parallel lines with one-sided power supply - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: instantaneous values of the current i₁ and i₂ are measured on the first and second lines in the positive and negative half-waves of the current as the current rises. Then, the instantaneous current value in the first line i₁ with a given value of the current i_st, and for i₁= i_st, continuing to measure i₁, the time ti₁ is counted until the moment when the next positive/negative half-wave current under the current i₁= i_st buildup. Then the countdown is repeated, comparing t₁ with the first t_st1 and the second t_st2 given to the values of time, and if t₁≤t_st1 or t₁≥t_st2, then the switch of the first line is turned off. Simultaneously, the instantaneous current value in the second line i₂ is compared with a given value of the current i_st, and for i₂= i_st, continuing to measure i₂, the time t₂ is began to be counted until the moment when the next positive/negative half-wave current under the current i₂= i_at buildup. Then repeat the countdown, compare t₂ with the first t_et1 and t _et2 second specified values of time, and if t₂≤t_et1 or t₂≥t_et2, turn off power switch of the second line.

EFFECT: increased security reliability from the receiving side of two parallel lines with one-sided power supply.

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Description

The invention relates to the electric power industry, namely to the relay protection technique, and can be used to protect two parallel lines from short circuits.

A known method of protection on the receiving side of two parallel lines with one-way power [Chernobrov N.V., Semenov V.A. Relay protection of energy systems. - M .: Energoatomizdat, 1998. - S. 346-359], in which the difference between the currents of the same phases of the lines is measured and compared with a predetermined value, the voltage across the buses that feed the lines is measured. Then measure the angle between the resulting current and the voltage on the tires and compare it with a predetermined value, and if it exceeds a predetermined value and the current difference is greater than a predetermined value, then turn off the first line. If the angle between the resulting current and voltage on the tires is less than a predetermined value and the current difference is greater than a predetermined value, then the second line is turned off.

Closest to the proposed is a method of protection on the receiving side of two parallel lines with one-way power [Kletsel M.Ya., Nikitin K.I., Stinsky A.S. Improving the transverse differential protection of lines // Industrial Energy - 2008. - No. 5. - S. 20-24], in which the instantaneous values of the current i ₁ and i ₂ on the first and second lines are measured in the positive and negative half-wave current with increasing current. Their effective values are determined, and if they are greater than a predetermined value, the current difference of the same phases of the lines is measured and compared with a second predetermined value, the voltage across the buses from which the lines are fed is measured. Measure the angle between the resulting current and the voltage on the tires. Compare it with a predetermined value, and if it exceeds a predetermined value, and the current difference is greater than the second predetermined value, then turn off the first line. If the angle between the resulting current and the voltage on the tires is less than the specified value and the current difference is greater than the second specified value, then the second line is turned off.

The disadvantage of these methods is that they are based on the measurement of voltage, which entails the unreliability of devices that implement it.

The objective of the invention is to increase the reliability of protection on the receiving side of two parallel lines with one-way power supply.

This is achieved due to the fact that in the method of protection from the receiving side of two parallel lines with one-way power, in the same way as in the prototype, the instantaneous values of current i ₁ and i ₂ on the first and second lines are measured in the positive and negative half-waves of current with increasing current.

According to the invention, the instantaneous value of current i ₁ in the first line is compared with a given value of current i _et , and when the instant value of current i ₁ in the first line reaches a predetermined value of current i _et , while continuing to measure the instantaneous value of current i ₁ in the first line, time t ₁ until the moment when the current rises to the next positive / negative half-wave of current, the instantaneous current value i ₁ in the first line reaches i _et , then the time is repeated, the measured time t _{1 is} compared with the first t _et1 and the second t _et2 given time values. If t ₁ ≤t _et1 or t ₁ ≥t _et2 , then disconnect the first line. At the same time, the instantaneous value of current i ₂ in the second line is compared with the specified value of current i _et , and when the instant value of current i ₂ in the second line reaches the value of the specified value of current i _et , while continuing to measure the instantaneous value of current i ₂ in the second line, the time t ₂ until the moment when, in the next positive / negative half-wave of current, with increasing current, the instantaneous value of current i ₂ in the second line reaches the value of the specified current value i _et . Then, the countdown is repeated, the measured time t _{2 is} compared with the first t _et1 and second t _et2 given time values, and if t ₂ ≤t _et1 or t ₂ ≥t _et2 , then the second line is _turned off.

In the proposed method, in contrast to the prototype, voltage is not measured, which provides higher reliability, since it is known that voltage circuits are less reliable than current and operational.

In FIG. 1 shows a device that implements a protection method on the receiving side of two parallel lines with one-way power supply.

In FIG. 2 shows the time between the moments when the current i ₁ in the first line reaches when the value of the specified value of current i _{et1 rises} in the positive half wave in the load mode.

In FIG. 3 shows the time between the moments when the current i ₁ in the first line reaches when the value of the specified value of the current i _et increases with a short circuit on this line in the positive half-wave.

The protection method from the receiving side of two parallel lines with one-way power can be implemented using a device that contains the first 1 (DT1), second 2 (DT2) current sensors installed near the conductors of the same phases of the first and second lines. The first current sensor 1 (DT1) is connected in series to the positive current half-wave extraction unit 3 (ПП1), the instantaneous current value comparison unit 4 (СТ1), the time measuring unit 5 (ИВ1), the measured time comparing unit 6 (СВ1), the OR element 7 (OR1) and executive body 8 (ИО1), the output of which is connected to the trip coil of the first line circuit breaker. A second time comparison unit 9 (CB2) is connected to the output of the time measuring unit 5 (IV1), the output of which is connected to the element OR 7 (OR1). A unit for extracting a negative half-wave current 10 (OT1), a second unit for comparing instantaneous current values 11 (CT2), a second unit for measuring time 12 (IV2), and a third unit for comparing time 13 (CB3) are connected in series to the first current sensor 1 (DT1). The fourth time comparison unit 14 (CB4) is connected to the output of the second time measurement unit 12 (IV2). The outputs of the third 13 (CB3) and fourth 14 (CB4) time comparison blocks are connected to the element OR 7 (OR1). The second current sensor 2 (DT2) is connected in series with a second block for extracting a positive half-wave of current 15 (PP2), a third block for comparing the instantaneous current values 16 (CT3), a third block for measuring time 17 (IV3), and a fifth block for comparing time 18 (CB5), the second element OR 19 (OR2) and the second actuator 20 (IO2), the output of which is connected to the trip coil of the second line switch. The sixth time comparison unit 21 (CB6) is connected to the output of the third time measuring unit 17 (IV3), the output of which is connected to the second element OR 19 (OR2). A second block of negative current half-wave extraction 22 (OT2), a fourth block for comparing instantaneous current values 23 (CT4), a fourth block for measuring time 24 (IV4), and a seventh block for comparing time 25 (CB7) are connected in series to the second current sensor 2 (DT2). The eighth time comparison unit 26 (CB8) is connected to the output of the fourth time measuring unit 24 (IV4). The outputs of the seventh 25 (CB7) and eighth 26 (CB8) time comparison units are connected to the second element OR 19 (OR2).

As the first 1 (DT1) and second 2 (DT2) current sensors, reed switches of the KEM-2 type can be used. The first 3 (PTP) and second 15 (PP2) blocks for extracting the positive half-wave of the current, the first 4 (CT1), the second 11 (CT2), the third 16 (CT3) and the fourth 23 (CT4) blocks for comparing instantaneous current values, the first 5 (IV1 ), second 12 (IV2), third 17 (IV3) and fourth 24 (IV4) time measuring units, first 6 (CB1), second 9 (CB2), third 13 (CB3), fourth 14 (CB4), fifth 18 ( CB5), sixth 21 (CB6), seventh 25 (CB7) and eighth 26 (CB8) time comparison blocks, the first 10 (OT1) and second 22 (OT2) blocks of the negative current half-wave and the first 7 (OR1) and second 19 ( OR2) elements OR, can be implemented per mic Atmel AT89S53 series 51 controller. As executive bodies 8 (ИО1), 20 (ИО2) relays of type РП 16-1 can be used.

In the load mode, the signal proportional to the current in the phases of the first line is received from the first current sensor 1 (ДТ1) to the inputs of the first 3 (ПП1) unit for isolating the positive half-wave current and the first 10 (OT1) block for separating the negative half-wave current. From the second sensor, a signal proportional to the current in the phases of the second line is supplied to the inputs of the second 15 (ПП2) block for isolating the positive half-wave of current and the second 22 (OT2) block for separating the negative half-wave of current. The first unit for isolating the positive half-wave of current 3 (PP1) and the first block for isolating the negative half-wave of current 10 (OT1) extract the positive and negative half-waves of current i ₁ and supply them to the inputs of the first 4 (CT1) and second 11 (CT2) units of instantaneous value comparison, respectively current, where the instantaneous values of current i ₁ when increasing respectively in the positive and negative half-waves are compared with a given value of current i _et . The second unit for isolating the positive half-wave of current 15 (PP2) and the second block for isolating the negative half-wave of current 22 (OT2) select the positive and negative half-waves of current i ₂ and feed them to the inputs of the third 16 (CT3) and fourth 23 (CT4) of the instant value comparison blocks, respectively current, where the instantaneous values of current i ₂ when increasing respectively in the positive and negative half-waves are compared with a given current value i _et . When the currents i ₁ , i ₂ first reach the value of the set current value, the first 4 (CT1), third 16 (CT3) and second 11 (CT2), fourth 23 (CT4) instantaneous current value comparison blocks give a signal to the inputs of the first 5 (IV1 ), the third 17 (IV3) and the second 12 (IV2), the fourth 24 (IV4) time measuring units, starting the countdown. When the currents i ₁ , i ₂ reach the second time, the values of the set value of the current i _et stop the first countdown, and the first 5 (IV1) and third 17 (IV3) time measuring units give signals, respectively, to the inputs of the first 6 (CB1), second 9 (CB2 ) and the fifth 18 (CB5), the sixth 21 (CB6) time comparison blocks, and the second 12 (IV2) and fourth 24 (IV4) time measuring blocks - to the inputs of the third 13 (CB3), fourth 14 (CB4) and seventh 25 ( CB7), the eighth of 26 (CB8) time comparison blocks, and start the next countdown. The first 6 (CB1) and second 9 (CB2) time comparison units compare the time t ₁ measured in the first time measurement unit 5 (IV1) with the first t _et1 and second t _et2 given time values. The third 13 (CB3) and fourth 14 (CB4) time comparison units compare the time t ₂ measured in the second time measurement unit 12 (IV2) with the first t _et1 and second t _et2 given time values. The fifth 18 (CB5) and sixth 21 (CB6) time comparing units compare the time t ₃ measured in the third time measuring unit 17 (IV3) with the first t _et1 and the second t _et2 given time values. The seventh 25 (CB7) and eighth 26 (CB8) time comparison units compare the time t ₄ measured in the fourth time measurement unit 24 (IV4) with the first t _et1 and the second t _et2 given time values. In this case, the first 6 (CB1) and third 13 (CB3) time comparison blocks do not give out signals, since t _et1 ≤t ₁ and t _et1 ≤t ₂ , the second 9 (CB2) and fourth 14 (CB4) time comparison blocks do not work , since t _et2 ≥t ₁ and t _et2 ≥t ₂ , the fifth 18 (CB5) and the seventh 25 (CB7) time comparison units also do not give signals, since t _et1 ≤t ₃ and t _et1 ≤t ₄ , sixth 21 (CB6) and eighth 26 (CB8) time comparison units also do not work, since t ₁ ≤t _et3 and t ₂ ≤t _et4 . Therefore, there are no signals at the outputs of the first 7 (OR1) and second 19 (OR2) OR elements and the first 8 (IO1) and second 20 (IO2) actuators, the protection does not work.

Consider a short circuit (short circuit), for example, on the first line during the transition of currents i ₁ , i ₂ from positive to negative half-wave. Until the appearance of short-circuit with the current sensor outputs 1 (DT1 multiple unit) 2 (dT2) signals when the setpoint value current i _fl currents i _1, i ₂ with an increase in the negative or positive half-wave through the first three (FG1) block allocation positive half-wave current , the first unit for comparing the instantaneous values of current 4 (CT1) and the first unit for comparing the negative half-wave of current 10 (OT1), the second unit for comparing the instantaneous values of current 11 (ST2), the second unit for selecting the positive half-wave of current 15 (PP2), the third unit for comparing the instantaneous values current 16 (ST3) and in the second unit for extracting the negative half-wave of current 22 (OT2), the fourth unit for comparing the instantaneous values of current 23 (CT4) are respectively supplied to the inputs of the first 5 (IV1) and second 12 (IV2), third 17 (IV3) and fourth 24 (IV4) measurement units time, which begin to count, respectively, the time t ₁ and t ₂ , t ₃ and t ₄ . In the event of a short circuit from the outputs of current sensors 1 (DT1), 2 (DT2), the signals through the first block for isolating the positive half-wave of current 3 (PP1) and the first block for isolating the negative half-wave of current 10 (OT1), the second block for highlighting the positive half-wave of current 15 (PP1) and the second block for separating the negative half-wave of current 22 (OT2) is supplied to the inputs of the first 4 (CT1) and second 11 (CT2), third 16 (CT3) and fourth 23 (CT4) blocks comparing the instantaneous current values, which when currents reach i ₁ , i ₂ values specified current value i _fl output a signal stopping the counting bp change respectively in the first 5 (IV1) and second 12 (IV2), third 17 (IV3) and fourth 24 (IV4) time measuring units, from the outputs of which the signals are respectively supplied to the inputs of the first 6 (CB1) and second 9 (CB2), third 13 (CB3) and fourth 14 (CB4), fifth 18 (CB5) and sixth 21 (CB6), seventh 25 (CB7) and eighth 26 (CB8) time comparison blocks. Moreover, since the current in the first line changed the phase to the opposite, the time measured by the first time measuring unit 5 (IV1) is less than t _et1 , and measured by the second time measuring unit 12 (IV2), it is greater than t _et2 . Therefore, the first 6 (CB1) and fourth 14 (CB4) time comparison blocks give signals through the first element OR 7 (OR1) to the input of the first actuator 8 (IO1), which sends a signal to turn off the first line circuit breaker. The third 13 (CB3) and second 9 (CB2) blocks for comparing time signals do not give out, because, despite the change in the phase of the current, t _et1 ≤t ₂ and t ₁ ≤t _et2 . Fifth 18 (CB5), sixth 21 (CB6), seventh 25 (CB7), eighth 26 (CB8) time comparison units do not work, since the phase of the current in the second line has not changed.

In the load mode, the time t ₁ between the moments when the currents in the lines reach the value of the specified current value i _et is 0.02 s (Fig. 2). With external short circuits, it is in the range of 0.015-0.025 s. Therefore, as the first and second preset time values, we take t _et1 = 0.015 s and t _et2 = 0.025 s. In the event of short circuits on the protected lines, for example, on the first when the current i ₁ passes from the negative half-wave to positive, the time U measured by the first time measuring unit 5 (IV1) (Fig. 3) becomes greater than t _et2 . Therefore, the second time comparison unit 9 (CB2) is triggered and gives a signal to the first element OR 7 (OR1), which starts the first actuator 8 (IO1), which sends a signal to turn off the first line circuit breaker.

Using the proposed method allows the use of parallel line protection devices on the receiving side without voltage circuits, which increases the reliability of the protection.

Claims (1)

The method of protection from the receiving side of two parallel lines with one-way power, which consists in measuring the instantaneous values of currents i ₁ and i ₂ in the first and second lines in the positive and negative half-wave current with increasing current, characterized in that they compare the instantaneous value of current i ₁ in the first line with predetermined current value i _fl, and when the instantaneous value of the current i ₁ at the first predetermined value of the current line i _fl, continuing to measure the instantaneous value of the current i ₁ in the first line, starting to count the time t ₁ to the point where next positive / negative half-wave AC current with an increase in the instantaneous value of the current i ₁ in the first line reaches i _fl, then repeating countdown, comparing the measured time t ₁ to t first t second _et1 and _et2 predetermined time values and if t ₁ ≤t _et1 or t ₁ ≥t _et2 , then turn off the first line, at the same time compare the instantaneous value of current i ₂ in the second line with the specified value of current i _et , and when the instantaneous value of current i ₂ in the second line reaches the value of the specified value of current i _et , continuing to measure instant value Current s i ₂ at the second line, start to count the time t ₂ to the time when the next current positive / negative half-wave current with an increase in current instantaneous value i ₂ of the second line reaches the predetermined value i _fl current then repeated countdown compared the measured time t ₂ with the first t _et1 and second t _et2 given time values, and if t ₂ ≤t _et1 or t ₂ ≥t _et2 , then turn off the second line.

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