JPH09159717A - Method and device for detecting discharging position - Google Patents

Abstract

PROBLEM TO BE SOLVED: To exactly detecting discharge generating positions over a wide extent with a simple means. SOLUTION: When discharge occurs from a compressed gas insulation bus 1 at a position 4 at a distance X from the left end of the bus 1 and at a distance Y from the right end of the bus 1 due to a ground fault for some reason, a step-like voltage is generated and propagated to both ends of the bus 1, because the voltage applied across the bus 1 becomes zero. When voltage signals arrives at voltage sensors A and B, the signals are inputted to the 1CH and 2CH of a measuring instrument 5 through signal lines 6. The instrument 5 detects that the discharge occurs due to the ground fault from the bus 1 at the distance X from the left end of the bus 1 based on the difference between the arrival time of the voltage signals at the sensors A and B, the length L of the bus 1, and the propagating speed of electric signals through the bus 1.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to, for example, a substation,
The present invention relates to a discharge position detection method and a detection device for detecting a generation position when a discharge occurs in a gas-insulated device such as a switchyard and a power plant.

[0002]

2. Description of the Related Art A gas-insulated switchgear (GIS) installed in a substation, switchgear, power plant, etc. is a transformer, a circuit breaker, a disconnector, and a grounding device in a metal grounding container filled with insulating gas. A gas insulated device such as a lightning arrester is configured, and each device is connected through a high voltage conductor. This gas-insulated switchgear has all of the high-voltage parts housed in a metal grounded container, so the installation area can be significantly reduced compared to air-insulated switchgear, and the safety and environmental characteristics are improved. Are better.

However, in such a gas-insulated switchgear, even if a discharge phenomenon occurs due to a ground fault or the like, the appearance of the grounded container does not reveal the accident point, and it takes a long time to detect the failure position. Become. When detecting this discharge position, depending on the extent of the accident, the operation will be stopped.Therefore, by detecting the accident occurrence position in a short time and taking appropriate measures, the operation can be prevented or the stop time can be reduced. Need to be shortened.

In many cases, such detection of the discharge position is performed by sensors provided in advance in the container. For example, an electrostatic partial pressure sensor is configured by connecting a detection electrode to a plurality of places of the high-voltage conductor via a first capacitor element and grounding this detection electrode via a second capacitor element. Then, when a discharge occurs, it is induced in the detection electrode by the correlation between the capacitance between the detection electrode and the high-voltage conductor at the discharge generation position and the capacitance between the detection electrode and the ground potential. The discharge occurrence is measured by drawing out the potential that is generated outside.

Further, since the partial discharge in the gas-insulated equipment has a characteristic waveform, there is a method of detecting the partial discharge by comparing the waveform in the normal state with the actual detected waveform. In the case of this method, in order to be able to identify the noise waveform generated during normal operation and the waveform during partial discharge,
It is necessary to build an expert system that makes decisions based on the data collected in advance.

In addition to the above methods, a detection method using a sound when a partial discharge occurs, a detection method using an increase in gas pressure, a detection method using ultrasonic waves, a detection method using corona generated, and the like have been put into practical use.

[0007]

However, the above-mentioned discharge position detecting method has the following problems.
That is, in the case of the method of providing the sensor in the container, the sensor needs to be attached in the vicinity of the place where the discharge occurs. Will have to be installed. However, in practice, there are many places where it is difficult to attach, and in the case where such a large number of sensors are attached, the manufacturing cost increases and the time required for maintenance also increases.

In the method of detecting the waveform of the partial discharge, since the frequency characteristic of the partial discharge varies depending on the equipment configuration, environment, and the connection position of the detector, it is necessary to collect many individual data in advance. Therefore, it becomes difficult to generalize the system. Further, in such a method, the occurrence of discharge itself is mainly measured, and therefore the detection of the discharge occurrence position is not always an easy process.

Furthermore, there is a problem that it is difficult to distinguish between external noise or the operating noise of a circuit breaker, a transformer, etc. and the noise generated by the discharge by the detection by the noise.

The present invention has been proposed to solve the above-mentioned problems of the prior art.
An object of the present invention is to provide a discharge position detection method capable of accurately detecting a discharge generation position in a wide range by a simple means.

Another object of the present invention is to provide a discharge position detection device capable of accurately detecting a discharge generation position in a wide range with a small number of sensors and a simple mechanism.

[0012]

In order to achieve the above object, the invention as set forth in claim 1 is a discharge position detecting method for detecting a generation position of a discharge when a discharge is generated in a conducting conductor. The electric signal propagating through the current-carrying conductor from the discharge position is detected at at least two different positions across the discharge position in the current-carrying conductor,
The discharge position is calculated based on the propagation velocity of the electric signal, the arrival time difference of the electric signal to each detection position, and the interval between the detection positions.

In the above-mentioned invention according to claim 1, at least two electric signal detection positions are required, and accurate values of the electric signal propagation velocity, arrival time difference and detection position interval can be easily obtained. The discharge position can be calculated on the basis of the data obtained.

According to a second aspect of the present invention, in the discharge position detecting method according to the first aspect, the electric signal is voltage or current.

In the invention according to claim 2 as described above, since the electric signal to be detected is a voltage or a current, it is possible to easily obtain an accurate detected value.

According to a third aspect of the present invention, in the discharge position detecting method according to the first or second aspect, the discharge position is calculated after amplifying the detected electric signal.

In the invention according to claim 3 as described above, since the electric signal is amplified, an error is unlikely to occur in the calculated value even with a weak signal.

According to a fourth aspect of the present invention, in a discharge position detecting device for detecting a generation position of a discharge when a high voltage conductor of a gas-insulated equipment is discharged, both ends of the high voltage conductor are
A sensor capable of detecting an electric signal propagating through the current-carrying conductor from a discharge position by occurrence of discharge is provided to the sensor
A measuring device for calculating the discharge position based on a propagation velocity of the electric signal, a difference in arrival time of the electric signal from each detection position, and an interval between the detection positions is connected.

According to the invention described in claim 4, the sensors need only be provided at both ends of the high-voltage conductor, and the calculation by the measuring device is performed by the propagation speed of the electric signal, the arrival time difference of the electric signal from each detection position, and It is performed based on the data that can easily obtain the accurate value of the interval between the respective detection positions.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments corresponding to the inventions described in claims 1 to 4 will be described below with reference to the drawings. In addition,
The discharge position detecting device described below is one embodiment corresponding to the invention described in claim 4, and the discharge position detecting method realized by this device is one embodiment corresponding to the invention described in claims 1 and 2. It is an embodiment. The high-voltage conductor according to claim 4 is a gas-insulated bus bar.

(1) Structure of Discharge Position Detection Device First, the structure of the discharge position detection device will be described. That is,
As shown in FIG. 1, in the grounding container of the gas insulated switchgear,
A gas-insulated busbar 1 having a linear shape and a length of L (m) is formed. A voltage sensor A2 is provided at one end (left end in the drawing) of the gas insulated bus bar 1, and a voltage sensor B3 is provided at the other end (right end in the drawing). The voltage sensor A2 and the voltage sensor B3 are connected to the 1CH and 2CH of the measuring instrument 5 via the signal line 6, respectively. The length L of the gas-insulated busbar 1 and the speed at which a step-like voltage generated by a ground fault propagates through the gas-insulated busbar 1 are input to the measuring device 5 in advance. Then, the measuring instrument 5 has a function of calculating the distance from one end of the gas insulation busbar 1 to the discharge location due to the ground fault from the difference in time during which the step-like voltage propagates to both the voltage sensors A2 and B3. is there.

(2) Procedure of Discharge Position Detection Method Next, the procedure of the discharge position detection method realized by the above discharge position detection device will be described. First, in the gas-insulated busbar 1 that is charged with voltage in the operating state, at a position 4 where the distance from the left end is X (m) and the distance from the right end is Y (m), discharge due to a ground fault is caused for some reason. Suppose that it has occurred. In this case, the relationship of the following Expression 1 is established.

[0023]

[Equation 1] L = X + Y (Equation 1) When the discharge is generated at the ground fault position 4 as described above, the applied voltage becomes zero, so that a step-like voltage is generated, which is from the ground fault position 4 to both ends of the gas insulation busbar 1. And propagate.
When the voltage signals reach the voltage sensor A2 and the voltage sensor B3, respectively, the measuring device 5 is connected via the signal line 6.
1CH and 2CH, and the difference between the arrival time of the voltage signal to the voltage sensor A2 and the arrival time of the voltage signal to the voltage sensor B3 is measured.

Then, in the measuring instrument 5, the difference between the measured arrival times and the gas-insulated busbar 1 previously input
Based on the length L and the propagation velocity of the voltage signal, the distance X is calculated as follows. That is, when the difference between the arrival times of the voltage signals at the sensors A2 and B3 is T (seconds) and the propagation speed of the voltage signals is V (m / s), the relationship of the following Expression 2 is established.

[0025]

## EQU2 ## T = (Y / V)-(X / V) Equation 2 Then, from the above Equation 1 and Equation 2, the relationship shown in the following Equation 3 is established.

[0026]

## EQU3 ## X = (L-VT) / 2 Equation 3 Therefore, it is calculated that a ground fault has occurred at the position (L-VT) / 2 from the left end of the gas insulated bus 1.

The propagation speed of an electric signal is usually 3 × 1.
Since it is 0 ⁸ (m / s), the measurement sampling time Ts (seconds) required for the measuring instrument 5 is given by the following equation 4 when the resolution of discharge generation position detection is, for example, 0.3 m. become.

[0028]

Equation 4] ^{Ts = 3 × 10 8 /0.3=10 9} (Hz) ... Equation 4 Thus, since the handling the signal of about 10 ⁹ Hz = 1 GHz, as the measurement system corresponding to the voltage It is necessary to configure the sensors A and B, the measuring device 5 and the like.

(3) Effect of the Embodiment The effect of the present embodiment as described above will be described below. That is, the sensors provided on the gas-insulated busbar 1 need only be two voltage sensors A and B. Therefore, it is possible to accurately detect the discharge occurrence position in a wide range with a simple configuration that does not require manufacturing cost and does not require time for maintenance.

Then, the calculation of the distance X by the measuring device 5 is performed as follows.
Since the calculation is performed by a simple calculation based on the data of which the length L, the propagation velocity V, and the arrival time difference T can be obtained relatively easily and accurately, the discharge occurrence position can be detected quickly and appropriately, and the system It is easy to reduce costs and generalize.

(4) Other Embodiments The present invention is not limited to the above-described embodiments, and the following other embodiments are possible. For example, in the above embodiment, the voltage is used as the detection signal, but it is also possible to detect the current flowing through the circuit due to the ground fault and detect the discharge occurrence position. Further, it is also possible to detect the discharge occurrence position by detecting the current and the electric charge that pass through the electrostatic capacitance between the spacer or the like and the high voltage conductor.

Then, as one embodiment corresponding to the invention described in claim 3, when the discharge occurrence position is detected by a weak signal such as partial discharge, the output signal from each sensor is detected by the wide band amplifier. It is also possible to implement a method of detecting the partial discharge occurrence position as in the above-described embodiment after amplifying to a level detectable by the measuring device 5.

Further, although the above embodiment has been described as an example of a gas-insulated bus bar, similarly, a transformer, a switchgear, a transformer in a power plant, a circuit breaker, a disconnector,
It is also possible to apply to a single device such as a grounding device and a lightning arrester, or a device combining these.

[0034]

As described above, according to the present invention,
It is possible to provide a discharge position detection method capable of accurately detecting the discharge generation position in a wide range by a simple means.

Further, according to the present invention, it is possible to provide a discharge position detecting device capable of accurately detecting the discharge occurrence position in a wide range by using a small number of sensors and a measuring device having a simple structure.

[Brief description of the drawings]

FIG. 1 is a simplified explanatory view showing one embodiment of a discharge position detecting device according to the present invention.

[Explanation of symbols]

 1 ... Gas-insulated bus bar 2 ... Voltage sensor A 3 ... Voltage sensor B 4 ... Ground fault position 5 ... Measuring instrument 6 ... Signal line

Claims (4)

[Claims] 1. A discharge position detecting method for detecting a position where a discharge occurs in a current-carrying conductor, wherein an electric signal propagating through the current-carrying conductor from the discharge position is generated by the discharge, and the discharge position in the current-carrying conductor is detected. Detecting at at least two different positions sandwiching the, the propagation speed of the electric signal, based on the arrival time difference of the electric signal to each detection position and the interval of each detection position, to calculate the discharge position, Discharge position detection method. 2. The discharge position detecting method according to claim 1, wherein the electric signal is voltage or current. 3. The discharge position detection method according to claim 1, wherein the discharge position is calculated after amplifying the detected electric signal. 4. A discharge position detecting device for detecting the position of occurrence of a discharge in a high voltage conductor of a gas-insulated equipment, wherein the current carrying conductor is propagated from the discharge position to both ends of the high voltage conductor by the discharge generation. A measuring device that is provided with a sensor capable of detecting an electric signal, calculates the discharge position on the basis of the propagation speed of the electric signal, the arrival time difference of the electric signal from each detection position, and the interval between the detection positions in the sensor. A discharge position detecting device characterized by being connected to.