RU225431U1 - Device for determining the location of a power line fault - Google Patents

Abstract

The utility model relates to the field of electrical engineering and power engineering and can be used to determine the location of a fault in electrical networks of 6-750 kV. The technical result of the claimed utility model is to increase the accuracy of determining the location of a power line fault. The technical result is achieved by determining a time stamp with a more accurate reference to the front of the electromagnetic wave, performed using additionally introduced functional blocks and their connections in the claimed utility model. Increasing the accuracy of determining the location of a power line fault is ensured by the ability to conduct a more detailed analysis of the original signal and more accurately determine the boundary separating the undisturbed part of the signal from the disturbed one, caused by the arrival of the electromagnetic wave front.

Description

The utility model relates to the field of electrical engineering and power engineering and can be used to determine the location of a fault in electrical networks of 6-750 kV.

State of the art

There is a known method for determining the distance to the location of a fault on a power transmission line (RU 2475768, priority dated 10.24.2011, IPC G01R 31/08), by which currents and voltages are measured at each end of the line, an alarm signal is isolated from the measured currents and voltages, and a coefficient is calculated kurtosis of the selected alarm signal within a sliding time window, compare the calculated kurtosis coefficient with the threshold value, record the moment of exceeding the threshold using a satellite navigation system and calculate the distance to the location of the damage from the difference in the moments of exceeding the threshold recorded at the ends of the line.

The method is implemented by a device that contains block 1, isolating an alarm signal from the measured phase currents and voltages; a phase _A voltage meter V A, a phase _B voltage meter V B, a phase _C voltage meter V C, a phase current meter A _A are connected to the inputs of block 1 A, meter A _B of phase B current, meter A _C of phase C current. Block 2 is connected to the output of block 1, which calculates the kurtosis coefficient of the selected alarm signal within a sliding time window. One input of comparator 3 is connected to the output of block 2, which compares the kurtosis coefficient calculated by block 2 with the threshold value set at the other input of comparator 3 by block 4. The output of comparator 3 is connected to the capture input of timer 5. The output of block 6, which receives, is connected to the counting input of timer 5. timing pulses of a satellite navigation system. The output of the timer 5 is connected to the communication unit 7, which transmits to the dispatch console the time of arrival of the front of the alarm signal at the corresponding end of the power line.

The disadvantages of the device are due to the following factors. The moment the transition process begins is determined by a one-time process of isolating an alarm signal and exceeding the kurtosis coefficient of the threshold value under the conditions of a sliding time window, which initiates the process of triggering the comparator and starting the timer. As a result of applying the kurtosis coefficient, a time delay is introduced at the determined timestamp. In addition, the hardware noise of the functional blocks has a significant impact on the moment the timer starts, which records the moment of arrival of the electromagnetic wave. Due to this, the device has low accuracy

The closest in technical essence to the claimed utility model (prototype) is a device for determining the location of a fault in a power transmission line (RU2724352, priority dated November 30, 2018, IPC G01R 31/08, G01R 31/08), consisting of two semi-sets, each of which is connected to the corresponding end of the power line and contains a block for measuring voltages and currents of the power line, the input of which is connected to the end of the power line, a comparison block, a threshold element, a block for receiving a global time signal from the satellite system, a first communication channel, the output of the block for measuring voltages and currents of the power line connected to the first input of the comparison block, the second input of the comparison block is connected to the output of the threshold element, characterized in that an RF signal recording block, a block for determining the time stamp of the arrival of an electromagnetic wave and a fault location calculator are introduced, the first input of the HF signal recording block is connected to the output voltage and current meter, the second input of the RF signal recording block is connected to the output of the comparison block, the third input of the HF signal recording block is connected to the output of the satellite system global time signal receiving block, the input of the block for determining the time stamp of the arrival of an electromagnetic wave is connected to the output of the recording block RF signal, the block for determining the time stamp of the arrival of an electromagnetic wave is connected to the computer through a communication port and, through the first communication channel, is connected to a similar port of the block for determining the time stamp of the arrival of an electromagnetic wave of the second half-set.

The disadvantages of the prototype are low accuracy, causing a high probability of false determination of the moment of arrival of the electromagnetic wave front due to the significant influence of noise factors on the process of determining the time stamp.

Disclosure of the essence of the utility model

The technical result of the claimed utility model is to increase the accuracy of determining the location of a power line fault.

The specified technical result is achieved by the fact that to determine the location of a fault in a power line, a device is used that contains a measuring unit, the input of which is connected to the primary voltage and current converters at the end of the power line, a first comparison unit and a first threshold element, the first input of the first comparison unit is connected to the output measuring block, and the second input of the first comparison block is connected to the output of the first threshold element, a block for receiving a global exact time signal, a signal recording block with increased time resolution, the first input of which is connected to the output of the measuring block, the second input of which is connected to the output of the first comparison block, and the third input of which is connected to the output of the block for receiving a global exact time signal, a calculator block with an interface for data exchange, additionally a signal conversion block is introduced, the input of which is connected to the output of a signal recording block with increased time resolution, a second comparison block and a second threshold element, the first the input of the second comparison block is connected to the output of the signal conversion block, and the second input of the second comparison block is connected to the output of the second threshold element, the electromagnetic wave front analyzer block, the first input of which is connected to the output of the signal recording block with increased time resolution, and the second input of which is connected to the output of the second comparison block, and the output of the electromagnetic wave front analyzer block is connected to the input of the computer block with an interface for data exchange.

The technical result is achieved by determining a time stamp with a more accurate reference to the front of the electromagnetic wave, performed using additionally introduced functional blocks and their connections in the claimed utility model. Increasing the accuracy of determining the location of a power line fault is ensured by the ability to conduct a more detailed analysis of the original signal and more accurately determine the boundary separating the undisturbed part of the signal from the disturbed one, caused by the arrival of the electromagnetic wave front.

In fig. Figure 1 shows a block diagram illustrating an example of the application of the proposed utility model.

In fig. 1 the following designations are adopted:

1. power line (PTL);

2. location of power line damage;

3. location of primary voltage and current converters at the end of the power line;

4. a device for determining the location of power line damage;

5. measuring unit;

6. first comparison block;

7. first threshold element;

8. recording unit with increased time resolution;

9. unit for receiving a global exact time signal;

10. signal conversion block;

11. electromagnetic wave front analyzer unit;

12. second comparison block;

13. second threshold element;

14. computer block with interface for data exchange.

Implementation of a utility model

In the diagram in Fig. Figure 1 shows the power line 1 indicating the location of the fault 2 and the location of the primary voltage and current converters 3 at the end of the power line. The device for determining the location of the fault 4 contains a measuring unit 5, the input of which is connected to the primary voltage and current measuring converters located at the end of the power line. The output of the measuring block 5 is connected to the first input of the first comparison block 6, the second input of which is connected to the output of the first threshold element 7. The first input of the registration block 8 is connected to the output of the measuring block 5, the second input of the registration block 8 is connected to the output of the comparison block 6, the third the input of the recording unit 8 is connected to the output of the unit receiving the global exact time signal 9 from the satellite system. The output of the registration block 8 is connected to the input of the signal conversion block 10 and to the first input of the electromagnetic wave front analyzer block 11. The output of the signal conversion block 10 is connected to the first input of the second comparison block 12, whose second input is connected to the output of the second threshold element 13. The output of the second comparison block 12 is connected to the second input of the electromagnetic wave front analyzer block 11. The output of the electromagnetic wave front analyzer block 11 is connected to the input of the computer block with an interface for data exchange 14, for example, with a control center or a similar device installed at the opposite end of the power line.

A device for determining the location of a power line fault operates as follows. In normal mode, measuring unit 5 measures current voltages and currents at the end of the power line. When a short circuit occurs on a power line, a transient process is created, accompanied by the appearance of an electromagnetic wave at the point of damage 2, which propagates to the opposite ends of the power line along all phase lines. In device 4, upon the fact that the electrical signals arriving at the input of the measuring unit 5 exceed the threshold value set by the first threshold element 7, the first comparison unit 6 starts the registration unit 8, which registers the initial stage of development of the transient process with increased time resolution. The temporal accuracy of the recording unit 8 is ensured using a unit for receiving a global exact time signal 9 from the satellite system.

In this device, determining the electromagnetic wave front is the process of determining the point on the time axis separating the disturbed part of the environment, which is displayed by a signal of a characteristic emergency state, from the undisturbed part of the environment, which is displayed by a signal of a characteristic pre-emergency state. This process is determined by the following iterative procedures.

During the first iteration, one or more information signals are recorded with increased resolution in the time domain, which display the pre-emergency state and the initial part of the emergency state. This procedure is implemented using a comparison block 6, which compares the signal arriving at its first input from the measuring block 5 with the level of the first threshold element 7 and starts the recording block 8, synchronized from the global exact time signal receiving block 9. The result of the first iteration is a fragment of the oscillogram a signal lasting within 10-20 ms, which displays a pre-emergency state, where there is no disturbance, and an emergency state, where there is a disturbance. Depending on the choice of the level of the threshold element 7, the perturbed part can occupy a larger or smaller area of the signal oscillogram fragment.

During the second iteration, the first approximation of the boundary between the pre-emergency and emergency states, which is located in the emergency part of the oscillogram, is recorded. This procedure is implemented using a signal conversion block 10, which extracts the emergency component from a fragment of the signal oscillogram received from the recording block 8, which records the result of the first iteration. As a result of isolating the emergency component, the pre-emergency state will have a small value close to zero; in the emergency state, the resulting value will differ from zero. When the signal received from the signal conversion unit 10 to the first input of the second comparison unit 12 exceeds the level of the second threshold element 13, a moment in time is recorded, which is the result of the second iteration of approaching the desired boundary point separating the perturbed state from the non-perturbed state.

During the third iteration, a point on the time axis is determined that separates the perturbed part of the signal from the unperturbed part. This procedure is carried out by the electromagnetic wave front analyzer unit 11, the first and second inputs of which receive, respectively, a fragment of the oscillogram of the original signal obtained as a result of the first iteration, and a time stamp obtained as a result of the second iteration. The boundary between the perturbed part and the non-perturbed part is determined by analyzing the increment of samples of the original signal from the first approximation of the perturbation boundary, obtained as a result of iteration 2, to samples that were earlier in time. In the pre-emergency state, the increment between samples of the original signal is close to zero and, depending on the technical capabilities of the measuring equipment, does not exceed the least significant digit of the ADC. The desired boundary of the beginning of the disturbance is determined at the moment when the value between the current analyzed sample and the earlier one does not change in value. The result of the third iteration is the actual boundary between the pre-emergency and emergency states, which is the time of arrival of the electromagnetic wave front to the device.

The resulting time of arrival of the electromagnetic wave is transmitted to the computer unit 14, which transmits it to remote devices, for example, to a control center, and receives measurement data of the electromagnetic wave front from other OMP devices installed on the line, which determine the wave front in a similar way. Thus, it is possible to accurately determine the location of fault 2 on power line 1.

The use of additional functional blocks and new connections makes it possible to more accurately determine the boundary between the disturbed part of the signal and the undisturbed part and thereby provide a more accurate determination of the location of the damage.

Claims (1)

A device for determining the location of a fault in a power line, containing a measuring unit, the input of which is intended for connection to primary voltage and current transducers at the end of the power line, a first comparison unit and a first threshold element, the first input of the first comparison unit is connected to the output of the measuring unit, and the second input the first comparison block is connected to the output of the first threshold element, a block for receiving a global exact time signal, a signal recording block with increased time resolution, the first input of which is connected to the output of the measuring block, the second input of which is connected to the output of the first comparison block, and the third input of which is connected to output of the block for receiving a global exact time signal, a calculator block with an interface for data exchange, characterized in that a signal conversion block is additionally introduced, the input of which is connected to the output of the signal recording block with increased time resolution, a second comparison block and a second threshold element, the first input of the second the comparison block is connected to the output of the signal conversion block, the second input of the second comparison block is connected to the output of the second threshold element, the electromagnetic wave front analyzer block, the first input of which is connected to the output of the signal recording block with increased time resolution, and the second input of which is connected to the output of the second block comparison, and the output of the electromagnetic wave front analyzer block is connected to the input of the computer block with an interface for data exchange.

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