RU2472169C1 - Method to detect distance to area of damage on power transmission line - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: currents and phase voltages are measured on the first and second ends of the line. Phase-to-phase currents and voltages are generated from measured currents and voltages. Emergency components of phase-to-phase currents are identified, as well as emergency components of phase-to-phase voltages. Moments of time t₁ and t₂ are fixed on the first and second ends of the line, for the time period, when a threshold value is exceeded by the sum of emergency components of phase-to-phase voltages and emergency components of appropriate phase-to-phase currents multiplied by a coefficient equal to an equivalent value of phase-to-phase wave resistance. Using the measured difference (t₁ -t₂), the distance to the damage area is calculated.

EFFECT: increased sensitivity and accuracy of damage area detection.

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Description

The invention relates to the field of electrical engineering and electric power industry and can be used to determine the location of damage in a three-phase power transmission line (LEP) of high and ultra-high voltage.

A known method of determining the location of damage on power lines using the wave method of two-sided measurements, which fix the electromagnetic waves that occur in the place of a short circuit (SC) and propagating to the ends of the lines, when the wave fronts reach the ends of the lines, measure and fix the difference of arrival of these fronts by stopping the counters of the timing pulses transmitted over the communication channels and ensuring the synchronization of the counters' progress (reference timing) (Shalyt G.M. REPRESENTATIONS power lines pulse methods. M .: Energy, 1968).

The disadvantage of this method is the neglect when fixing the moment of arrival of the wave fronts to the ends of the line of factors such as multiphase power lines, the shape of the phases on the supports of these power lines, the degree of distortion of the component waves in phases.

A technical solution is known, which consists in determining the distance to the place of damage on the power line, by which the phase currents of the line at each end of the line are measured and synchronized, mathematical combinations of these currents are generated, emergency components of these combinations are distinguished, and the moment of time when the emergency components exceed the threshold value is recorded at this end of the line and with the help of a global positioning system, the time moment when the emergency components exceed the threshold value by the other end of the line, measure the difference of these two points in time, calculate the distance L ₁ to the place of damage to the line by the expression:

L ₁ = (L + (t ₁ -t ₂ ) xV) / 2,

where L is the length of the power line, V is the propagation speed of the emergency components, (t ₁ -t ₂ ) is the difference of these two points in time (Patent USA No. 6, 597, 180 B1, Jul, 22,2003).

One of the drawbacks of this technical solution is the use of the sum of the phase currents of the line as a measured signal, that is, phase-to-ground components, which are significantly distorted during the run along the line from the place of damage, especially with an increase in its length. Another disadvantage is the dependence of the level of phase currents of the line on the value of the equivalent resistance of the power system adjacent to the power line, on which the place of damage is determined. When its value is greater than the wave impedance of the line (for example, if there is no other outgoing lines other than this one at one end of the power line), the current levels are significantly reduced, which worsens the process of fixing the excess of the threshold currents by emergency components.

The technical result aimed at achieving the proposed technical solution is to increase the sensitivity and accuracy of determining the location of damage on the power line by stabilizing signal levels by which the threshold value is exceeded by using the magnitude of the voltage of the incident wave propagating from the place of damage to the end of the line where the location of the damage is determined, and calculated by the expression:

2U _pad = u + z

Here u and i are the voltage and current at the end of the line, where the location of the damage is determined, z is the wave impedance of the line. In this technical solution, the coefficient value corresponding to the wave impedance of the line is taken to be equal to the interphase wave impedance of the line, taking into account the actual values of the transformation coefficients of the voltage and current meters of the line.

The technical result is achieved by the fact that in the method for determining the distance to the place of damage on the power line, by which the phase currents of the line are measured and synchronized at each end of the line, mathematical combinations of these currents are generated, emergency components of these combinations are distinguished, and the time instant of exceeding the emergency components is sequentially recorded threshold value at a given end of the line and using the global positioning system, the instant of time when the alarm components exceed the threshold value at the other end of the line, measure the difference of these two points in time and calculate the distance to the place of damage, additionally measure and synchronize at each end of the line the phase voltage of the line, form their mathematical combinations from these voltages and isolate the emergency components of these combinations, record the excess of threshold values components formed by summing the emergency components of mathematical combinations of phase voltages with the emergency components of mathematical combinations of the corresponding phases currents multiplied by a coefficient equal to the equivalent value of the interphase wave impedance, while the phase currents are taken as mathematical combinations of phase currents, and phase-to-phase voltages are used as mathematical combinations of phase voltages, the time offset of the instantaneous values of currents and voltages at the ends of the line is measured.

The essence of the invention is illustrated in the drawing, which shows a device that implements a method for determining the distance to the place of damage on an overhead power line.

The method is implemented by a device comprising a measuring V _A voltage phase A, the output of which is connected to the first input unit 1 forming phase to phase phase voltages A and B, the meter V _B voltage phase B, the output of which is connected to the first input unit 2 forming phase-phase phase voltage B and C, a phase _C voltage meter V _C , the output of which is connected to the first input of the phase-to-phase voltage generating unit 3 of phases C and A, to the second input of which the output of the phase A voltage meter V _A is connected, to the second input of the forming unit 1 the phase-to-phase voltage of phases A and B is connected to the output of the voltage meter V _B of phase B, to the second input of the phase-to-phase voltage generating unit 2 is connected the output of phase-voltage meter V _{C to} the phase C, the output of phase-to-phase voltage generating unit A and B through the selection unit 4 emergency components is connected to the first input of the summing unit 5, the output of the phase-to-phase voltage generating unit 2 of phases B and C through the emergency allocation unit 6 is connected to the first input of the summing-up unit 7, the output of the phase-forming unit 3 to conjugation phases C and A through unit 8 allocating emergency components coupled to a first summing input unit 9, the meter _AA phase current A, the output of which is connected to the first input unit 10 forming phase to phase current of phases A and B, the meter A _B current phase B, the output which is connected to the first input of phase-to-phase current generating unit 11 of phases B and C, a phase _C current meter A, the output of which is connected to the first input of phase-to-phase current generating unit 12 of phases C and A, to the second input of which the output of phase A current meter A _B to the second input of 10 f ormirovaniya phase to phase current of phases A and B connected to the output meter A _B power phase B to the second input unit 11 forming phase to phase current of phases B and C connected to the output meter A _C phase C current output of block 10 forming phase to phase current of phases A and B through a series-connected the emergency component isolation unit 13 and the multiplication unit 14 is connected to the second input of the summing unit 5, the output of the phase-to-phase current generating unit 11 of phases B and C through the series-connected emergency component isolation unit 15 and the multiplication unit 16 is connected to the second the input of the summing unit 7, the output of the phase-to-phase current generation unit 12 of phases C and A through the series-connected emergency component extraction unit 17 and the multiplication unit 18 are connected to the second input of the summing unit 9, the output of the summing unit 5 through the threshold organ 19 is connected to the first input of the OR element 20 , the output of the summing unit 7 through the threshold organ 21 is connected to the second input of the OR element 20, the output of the summing unit 9 through the threshold organ 22 is connected to the third input of the OR element 20, the output of which is connected to the first input center an actual processor 23, to the second input of which a receiver 24 of the global positioning system is connected, and to the third input is the output of relay protection 25 of the line.

The location of damage on the power line is as follows. In the normal mode of operation of the power line at the outputs of blocks 4, 6 and 8 of the allocation of emergency components of interphase voltages and at the outputs of blocks 13, 15 and 17 of the allocation of emergency components of interphase currents, signals are not generated. When switching in the network, including on this power line, the emergency components isolation blocks 4, 6, 8, 13, 15 and 17 generate separate signals, but the location of the damage is not determined due to the lack of conditions for the relay protection to operate 25. When a short circuit occurs at the outputs of blocks 4, 6 or 8 of the separation of the emergency components of the interphase voltages, signals of the emergency components of the interphase voltages of the transient process are generated, and at the outputs of the blocks 13, 15 or 17 of the allocation of the emergency components Signals of the emergency components of the interphase currents of the transient process are formed. Each emergency component of the respective interphase currents is multiplied by a coefficient equal to the equivalent value of the interphase wave impedance, using multiplication units 14, 16 and 18, respectively. The results of the multiplication from the output of the blocks 14, 16 and 18 of the multiplication are fed to the first inputs of the summing blocks 5, 7 and 9, respectively, the second inputs of which are fed from the outputs of the emergency blocks 4, 6 and 8, respectively. At the outputs of the summing blocks 5, 7 and 9, signals are generated corresponding to the interfacial values of the voltages incident from the fault location to the end of the wave line. If the output signals of the summing blocks 5, 7 or 9 exceed the levels of response of the threshold organs 19, 21 or 22, respectively, then the outputs of these organs send signals to the inputs of the OR element 20. From the output of the OR element 20 and from the output of the receiver 24 of the global positioning system, signals are sent to the central processor 23 corresponding to the time instants of exceeding the response levels of the threshold organs 19, 21 or 22 at the ends of the line. The Central processor 23 calculates the distance to the place of damage by the expression

L ₁ = (L + (t ₁ -t ₂ ) xV) / 2,

due to the measurement and fixation of the difference Δt of the formation of incident waves at the ends of the line. The central processor 23 also measures the duration of the time shift of the instantaneous values of currents and voltages of the same phases at the ends of the line when the short circuit is turned off, which allows you to determine the actual length L of the line during a short circuit on it.

Performing in this way a method designed to determine the location of a damage to a line will increase the sensitivity and accuracy of determining the location of damage through the use of incident waves that are generated directly at the place of occurrence of the transient process immediately after the occurrence of damage on the line. It should be noted that in addition to the short circuit location, the proposed technical solution is also able to determine the phase failure of the line. Moreover, if taking into account the use of the fact of the actuation of the relay protection of the line allows to identify the short circuit location on the protected line, then the breakage point can be determined, for example, by using the fact of operation of the device for monitoring the asymmetry of phase currents or voltages on this line.

Claims (1)

The method of determining the distance to the place of damage on the power line, which consists in measuring currents and voltages of phases at the first and second ends of the line, forming interfacial currents and interphase voltages from the measured currents and voltages, isolating emergency components of interphase currents and emergency components of interphase voltages, fix at the first and second ends of the line time moments t ₁ and t _{2 the} time of exceeding the threshold value by the sum of the emergency components of the interphase voltages and the emergency components respectively of the corresponding interphase currents multiplied by a coefficient equal to the equivalent value of the interphase wave impedance, and the distance to the place of damage is calculated from the measured difference (t ₁ -t ₂ ).