JP2624914B2 - Partial discharge measuring device and its test method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a partial discharge measuring device for measuring a partial discharge generated in a closed gas insulated switchgear and a test method thereof.

[0002]

2. Description of the Related Art In recent years, gas insulated switchgear (GIS) has become widespread and in operation due to the necessity of increasing substation facilities due to soaring land for substations and increasing power supply in urban areas. This gas insulated switchgear has a disconnector, a circuit breaker, and the like housed and arranged in a closed container as is well known, and the periphery thereof is filled with SF ₆ gas having excellent insulation and arc-extinguishing properties to ensure insulation. Device.

[0003] Such a gas insulated switchgear has advantages such as downsizing and reduction of the exposed charged portion of the ground tank. However, on the other hand, if an abnormality occurs inside the sealed container due to difficulties in maintenance diagnosis due to high performance and an increase in maintenance and repair work time, there is a disadvantage that the reliability is significantly reduced. Therefore, in the equipment of the gas insulated switchgear, the circuit breaker, disconnector, and grounding switch,
A substation equipment control system that generates a trip command, etc.
The system is equipped with a preventive maintenance system capable of confirming the reliability of the normal operation of the substation equipment and monitoring early detection when an abnormality occurs.

Among the items monitored by the preventive maintenance system, the corona amount whose measured value itself does not change rapidly,
There are items that are quasi-stationary, such as gas density, oil level, and oil temperature, and items that require processing within a short period of time, such as the operation time of circuit breakers and disconnectors. As a normal monitoring method, for the latter item, measure while the device is operating,
Data is processed, operated, and the result is output and displayed and stored.For the former quasi-stationary item, measurement is performed at a certain time interval, the data is processed and operated, and the result is output and displayed. I remember.

[0005]

Among the monitoring items of the above preventive maintenance system, partial discharge measurement (corona measurement) is one of the most important items from the viewpoint of predicting abnormality of equipment. For this partial discharge measurement, many measurement methods have been proposed than before.However, when applying these methods to actual gas insulation equipment, especially to existing equipment, and conducting inspections, these test methods should be used. There was a problem.

FIG. 2 is a schematic sectional view showing an example of a test method for such a conventional partial discharge measuring device. As shown in FIG. 2, a general gas insulating device is housed in a grounded metal container 1 grounded by a grounding wire (not shown),
The grounded metal container 1 is electrically divided by an insulating spacer 2 and connected in the longitudinal direction. In the grounded metal container 1, a central conductor 3, which is a high-voltage charging unit electrically connected to a transmission line (not shown), is supported by an insulating spacer 2. This insulating spacer 2 includes
A buried electrode 4 for power detection is provided.
A stray capacitance C2 exists between the ground metal container 1 and
This stray capacitance C2 is shown as a capacitor 5. A partial discharge measuring device detecting section 7 is connected to both terminals of the capacitor 5 via a signal lead-in line 6. In the drawing, C1 indicates a stray capacitance existing between the buried electrode 4 and the center conductor 3.

In the gas insulated apparatus to which the partial discharge measuring device detecting section 7 is connected as described above, the case where a partial discharge occurs between the center conductor 3 and the grounded metal container 1 is simulated. As a test method for performing the test of the part 7, as shown in FIG. 2, a connection part of the grounded metal container 1 is cut off, a simulated partial discharge signal generator 8 is connected to the cut off part, and the center conductor 3 is grounded. A method of injecting a simulated partial discharge signal between the metal containers 1 can be considered.

However, when such a test method is adopted, the connection portion of the grounded metal container 1 is disconnected,
It is necessary to reconnect after the test, and the workability is poor. In addition, after the test is completed, a gas treatment such as refilling with SF ₆ gas is required, and in this gas treatment, foreign substances causing dielectric breakdown are likely to be mixed. Therefore, at present, it is almost impossible to carry out such tests not only for tests in factories but also for existing equipment in substations.

FIG. 3 is a schematic sectional view showing another example of a conventional method for testing a partial discharge detector. In FIG. 3, a part of the central portion of the grounded metal container 1 is branched, and a grounding device 20 is arranged at this branch portion. The grounding device 20 includes an insulating terminal 21 connected to the grounded metal container 1,
An electrode 22 embedded in the insulating terminal 21 and connected to the grounded metal container 1 and a movable electrode 2 connected to this electrode 22
3 and a fixed electrode 24 connected to the center conductor 3. The movable electrode 23 operates to open and close the electrodes 23 and 24, and grounds the center conductor 3 in a closed state.

In a gas-insulated apparatus provided with the grounding device 20 as described above, a test method for performing the test of the partial discharge measuring device detecting section 7 is as shown in FIG.
The electrical connection between the electrode 22 of the insulating terminal 21 of the grounding device 20 and the grounded metal container 1 is cut off, and the simulated partial discharge signal generator 8 is attached between the electrode 22 and the grounded metal container 1. As a closed state, a test method in which a simulated partial discharge signal is transmitted from the simulated partial discharge signal generator 8 can be considered. In this test method, the simulated partial discharge signal generated by the simulated partial discharge signal generator 8 is applied to the electrode 22,
Since the signal is sent to the center conductor 3 via the movable electrode 23 and the fixed electrode 24, an operation test of the partial discharge measuring device detection unit 7 can be performed.

However, when such a test method is adopted, the electrode 22 of the insulating terminal 21 of the grounding device 20
Electrical connection between the ground metal container 1 and
It is necessary to reconnect after the test, and the workability is poor. In addition, since the test is performed with the grounding device 20 turned on,
The main circuit must be stopped during the test. Therefore, the test cannot be performed in an actual operation state, which is extremely inconvenient.

The present invention has been proposed to solve the above-mentioned problems of the prior art, and an object of the present invention is to eliminate the necessity of disassembling or gas-treating gas-insulated equipment, and to provide a main circuit for testing. By eliminating the need for stoppage, it is possible to maintain the high reliability of the equipment, to easily perform the test of the partial discharge measuring device, and to perform the test even in the actual operation state. An object of the present invention is to provide an excellent partial discharge measuring device and a test method thereof.

[0013]

According to the present invention, there is provided a test method for a partial discharge measuring device, comprising a detecting unit connected to a gas insulated device having a high voltage charging unit housed in a grounded metal container together with an insulating gas. This is a test method for a partial discharge measuring device that measures a partial discharge generated inside a gas-insulated device based on an output signal from the detection unit, and has the following features.
That is, a plurality of buried electrodes or floating electrodes are provided inside an insulating spacer for electrically dividing the grounded metal container or inside the grounded metal container while being insulated from the grounded metal container. The detection unit of the partial discharge measurement device is connected to a first electrode which is one of the floating electrodes. Then, a simulated partial discharge signal generator is connected to a second electrode which is one of another buried electrode or a floating electrode located at a position distant from the first electrode. The simulated partial discharge signal generated by the
Is injected into the gas-insulated equipment through the electrodes.

In this case, specifically, an injection command signal for instructing the simulated partial discharge signal generator to inject the simulated partial discharge signal into the gas-insulated equipment from the partial discharge measuring device or another control device. It is desirable to output a simulated partial discharge signal based on the injection command signal. Furthermore, the same type of electrode can be used as the first electrode and the second electrode, but different types of electrodes can be used as well.

On the other hand, the partial discharge measuring device according to the present invention
A state in which the high-voltage charging unit is housed in a grounded metal container together with an insulating gas, and is insulated from the grounded metal container inside an insulating spacer for electrically dividing the grounded metal container or inside the grounded metal container. A partial discharge measurement device for measuring a partial discharge generated inside a gas insulated device provided with a plurality of embedded electrodes or floating electrodes, and has the following characteristics and conforms to the test method. Device. That is, the partial discharge measuring device of the present invention is connected to the first electrode, which is one of the plurality of buried electrodes or floating electrodes, and detects partial discharge occurring inside the gas-insulated equipment. Having a part. In addition, it is connected to a second electrode which is one of other buried electrodes or floating electrodes located at a position away from the first electrode, generates a simulated partial discharge signal, and generates the simulated partial discharge signal. A simulated partial discharge signal generator for injecting the gas into the gas insulating device through the second electrode; Further, an injection command signal for instructing the simulated partial discharge signal generator to inject the simulated partial discharge signal into the gas-insulated equipment is output, and the simulated partial discharge signal is injected based on the injection command signal. It has an injection command unit.

[0016]

When the test method for a partial discharge measuring device according to the present invention having the above-described configuration is employed, the simulated partial discharge signal generator is insulated from a grounded metal container such as a buried electrode of an insulating spacer. The test can be easily performed by simply connecting to the buried electrode or the floating electrode in the state of being in a state, and injecting a simulated partial discharge signal through this electrode. Therefore,
Since the simulated partial discharge signal generator is connected, there is no need to disassemble or gas-treat the gas-insulated equipment, so that the test can be easily performed and the reliability of the equipment does not decrease. Also, since there is no need to stop the main circuit during the test, the test can be performed even in the actual operation state,
It is convenient.

In particular, an injection command signal is output from the partial discharge measuring device or another control device to the simulated partial discharge signal generator, and injection of the simulated partial discharge signal is performed based on the injection command signal. When configured, measurement tests can be performed automatically in the actual operation state,
Excellent practicality.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A typical embodiment of a test method for a partial discharge measuring device according to the present invention will be described below in detail with reference to FIG. In this case, FIG. 1 is a schematic cross-sectional view showing an embodiment in which the present invention is applied to a general gas insulating device similar to the prior art shown in FIG. It is attached.

As shown in FIG. 1, a grounded metal container 1 is electrically divided by an insulating spacer 2 and connected in a longitudinal direction. In the grounded metal container 1, a central conductor 3, which is a high-voltage charging unit electrically connected to a transmission line (not shown), is supported by an insulating spacer 2. The insulating spacer 2 is provided with a buried electrode 4a for power detection, and a stray capacitance C2 exists between the buried electrode 4a and the grounded metal container 1. The stray capacitance C2 is shown as a capacitor 5. Have been. A partial discharge measuring device detecting section 7 is connected to both terminals of the capacitor 5 via a signal lead-in line 6. In this case, the buried electrode 4a of the insulating spacer 2 corresponds to the first electrode in the present invention. In the drawing, C1 indicates a stray capacitance existing between the buried electrode 4a and the center conductor 3. The configuration up to this point is the same as that of the prior art shown in FIG.

Further, in the present embodiment, the output from the partial discharge measuring device detecting section 7 is transmitted to the partial discharging measuring device receiving section 10 through the optical cable 9. On the other hand, the simulated partial discharge signal generator 8 is connected to another insulating spacer 11 different from the insulating spacer 2 on which the partial discharge measuring device detection unit 7 is installed. That is,
The simulated partial discharge signal generator 8 is connected via a signal injection line 12 to both terminals of the capacitor 5 formed by the buried electrodes 4b of the insulating spacer 11. In this case, the buried electrode 4b of the insulating spacer 11 corresponds to the second electrode in the present invention. The partial discharge measuring device receiving section 10 is set so as to automatically output an injection command signal at regular intervals. Partial discharge measurement device receiver 10
The injection command signal output from the
The O / E converter 13, the optical cable 9, and the optical / electrical converter (O / E converter) 14 are sequentially transmitted and input to the simulated partial discharge signal generator 8.

In the present embodiment, the test of the partial discharge measuring device detecting section 7 is performed in the above-described configuration, and the test method will be described below.

First, since the internal partial discharge of the gas insulated equipment is related to the SF ₆ gas discharge phenomenon whose rise is several ns, the signal generated by the partial discharge is also several thousand.
An extremely high frequency electromagnetic wave up to MHz. In this case, the charging section of the gas-insulated equipment is housed in the grounded metal container 1, so that the electromagnetic wave of a frequency of several MHz or more due to the internal partial discharge generated in the grounded metal container 1 is grounded. The metal container 1 will function as a waveguide. That is, the signal generated by the partial discharge propagates in the grounded metal container 1. Therefore, if such a signal of the electromagnetic wave is detected, it is possible to determine the presence or absence of the partial discharge. Recently, a partial discharge measuring device that detects a high-frequency band based on such a principle has been proposed. In this embodiment, a partial discharge signal detecting device 7 of this type is used to detect a partial discharge signal. Is to be detected.

That is, in the present embodiment, when testing the partial discharge measuring device detecting unit 7, first, the injection command signal is automatically output from the partial discharging measuring device receiving unit 10 at regular intervals. The injection command signal is converted into an optical signal by an electric / optical conversion unit (E / O conversion unit) 13, and is converted into an optical / electric conversion unit (O / E conversion unit) 14 via an optical cable 9.
The optical / electrical conversion unit (O / E conversion unit) 14
Is again converted into an electric signal, and then input to the simulated partial discharge signal generator 8.

Next, in the simulated partial discharge signal generator 8, a simulated partial discharge signal (FIG.
Is generated, and the simulated partial discharge signal is injected between the buried electrode 4 b in the insulating spacer 11 and the grounded metal container 1 via the signal injection line 12. Since the injected simulated partial discharge signal is equivalent to several ns of the rise of the internal partial discharge of the gas insulated device, after entering the gas insulated device via the stray capacitances C1 and C2,
It propagates to the left and right in the figure at the same speed as the actual partial discharge signal. The simulated partial discharge signal propagated as described above includes a stray capacitance C1 between the buried electrode 4a and the center conductor 3 in the other insulating spacer 2 and a stray capacitance C2 between the buried electrode 4a and the ground metal container 1. , And is detected by the partial discharge measuring device detection unit 7 via the signal drop-in line 6. Since the simulated partial discharge signal injected from the simulated partial discharge signal generator 8 into the gas-insulated equipment has a high frequency as described above, the test result may be greatly affected by the configuration of the signal injection line 12. is there. For this reason, it is desirable that the signal injection line 12 is as short as possible and the distance between the lines such as a coaxial cable does not change.

Further, the simulated partial discharge signal detected by the partial discharge measuring device detecting unit 7 is transmitted to the partial discharging measuring device receiving unit 10 via the optical cable 9. Therefore, by comparing the value of the injected simulated partial discharge signal with the simulated partial discharge signal detected by the partial discharge measurement device detection unit 7 in synchronization with the partial discharge measurement device receiving unit 10,
It is possible to automatically determine whether or not there is an abnormality in the partial discharge measurement device system itself.

As described above, in the present embodiment, a simulated partial discharge signal is generated by the simulated partial discharge signal generator 8 based on the injection command signal from the partial discharge measuring device receiving section 10, and this signal is isolated. Since it is a method of injecting into the buried electrode 4b of the spacer 11, there is no need to disassemble or process gas as in the prior art shown in FIG. Can be performed, and there is no problem of lowering the reliability of the device. Especially,
In some cases, such as when applying a partial discharge measurement device to existing equipment, without stopping the applied equipment,
Confirmation of the detection characteristics and adjustment of the sensitivity of the detector can be easily and automatically performed on site.

The present invention is not limited to the above embodiment. For example, the electrodes connected to the partial discharge measuring device and the simulated partial discharge signal generator are not limited to the buried electrodes of the insulating spacer, but may be grounded metal. As long as it is a buried electrode or a floating electrode provided in an insulated state with respect to the container, its specific configuration can be appropriately selected, and its arrangement location can be freely selected. Further, in the above-described embodiment, as the electrode connected to the partial discharge measuring device and the electrode connected to the simulated partial discharge signal generator, the same type of electrode as the buried electrode of the insulating spacer was used. However, the present invention is not limited to this, and it is equally possible to use different types of electrodes, and similarly excellent effects can be obtained. Furthermore, the present invention can be similarly applied to gas insulated equipment of any arrangement configuration, as long as the gas insulated equipment has a high voltage charging unit housed in a grounded metal container together with an insulating gas. .

In the above embodiment, the injection command signal is output from the partial discharge measuring device receiving section. However, the output of the injection command signal to the simulated partial discharge signal generator is provided separately from the receiving section. It is also possible to perform the control by a control unit or another control device, and in this case, the same operation and effect can be obtained. In addition, the injection command signal is not automatically output, and the output is performed manually, and further, the simulated partial discharge signal generator is directly operated manually without using the injection command signal itself. It is also possible to generate a simulated partial discharge signal.

On the other hand, in the present invention, a method for specifically comparing the simulated partial discharge signal injected into the gas-insulated equipment and the measured simulated partial detection signal can be appropriately selected. It is also possible to provide a comparison / arithmetic circuit in the section, or to provide a processing section separately from the receiving section, or to perform processing by a device separately provided outside the measuring apparatus. Similarly, the other components of the partial discharge measurement device, and the configuration of peripheral devices such as a control device or higher-level devices can be appropriately selected. That is, according to the present invention, a partial discharge measurement device detection unit is connected to a first embedded electrode or a floating electrode provided in a gas insulating device, and a simulated partial discharge signal generator is connected to a second embedded electrode or a floating electrode. However, as long as the test method has a feature of injecting a simulated partial discharge signal into a gas-insulated device, its specific device configuration and peripheral configuration can be freely selected, and similarly excellent operational effects can be obtained. Things.

[0030]

As described above, in the present invention,
By connecting a simulated partial discharge signal generator to a buried or floating electrode provided in a gas-insulated device and injecting a simulated signal through this electrode, it is possible to disassemble gas-insulated By eliminating the need for processing and the need to stop the main circuit at the time of testing, it is possible to maintain high reliability of the equipment and to easily perform the test of the partial discharge measuring device. It is possible to provide an excellent partial discharge measurement device and a test method thereof that can perform a test even in the operation state of the above.

[Brief description of the drawings]

FIG. 1 is a schematic sectional view showing a typical embodiment of a test method for a partial discharge measuring device according to the present invention.

FIG. 2 is a schematic cross-sectional view showing an example of a test method for a conventional partial discharge measuring device.

FIG. 3 is a schematic sectional view showing another example of a test method for a conventional partial discharge measuring device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Ground metal container 2 ... Insulating spacer 3 ... Center conductor (high voltage charging part) 4, 4a, 4b ... Buried electrode 5 ... Capacitor 6 ... Signal lead-in line 7 ... Partial discharge measuring device detector 8 ... Simulated partial discharge signal generation Device 9 ... Optical cable 10 ... Partial discharge measurement device receiver 11 ... Insulating spacer 12 ... Signal injection line 13 ... Electrical / optical converter (E / O converter) 14 ... Optical / electric converter (O / E converter)

Claims (3)

(57) [Claims] A detecting unit connected to a gas insulated device in which a high-voltage charging unit is housed in a grounded metal container together with an insulating gas, and based on an output signal from the detecting unit; In a test method of a partial discharge measuring device for measuring a generated partial discharge, a plurality of pieces of the grounded metal container are electrically insulated from each other in an insulating spacer or a grounded metal container. Embedded electrode or floating electrode is provided, a detecting unit of the partial discharge measuring device is connected to a first electrode which is one of the plurality of embedded electrodes or floating electrodes, and the first electrode A simulated partial discharge signal generator is connected to a second electrode which is one of other buried electrodes or floating electrodes at a distant position, and a simulated partial discharge generated by the simulated partial discharge signal generator. Signal to the second A test method for a partial discharge measuring device, characterized by injecting into a gas insulating device through a pole. 2. An injection command signal for instructing the simulated partial discharge signal generator to inject the simulated partial discharge signal into the gas-insulated equipment is output from the partial discharge measurement device or another control device. 2. The test method for a partial discharge measuring device according to claim 1, wherein the injection of the simulated partial discharge signal is performed based on the injection command signal. 3. A high-voltage charging section is housed in a grounded metal container together with an insulating gas, and a grounding metal is provided inside an insulating spacer or inside the grounding metal container for electrically dividing the grounding metal container. In a partial discharge measurement device for measuring a partial discharge generated inside a gas insulated device provided with a plurality of embedded electrodes or floating electrodes while being insulated from the container, A detecting unit that is connected to the first electrode that is one and detects a partial discharge that occurs inside the gas-insulated device; and a buried electrode or a floating electrode that is apart from the first electrode. A simulated partial discharge signal generator connected to one second electrode, generating a simulated partial discharge signal, and injecting the simulated partial discharge signal into the gas insulated apparatus through the second electrode; Discharge signal generator An injection command unit for outputting an injection command signal for instructing the injection of the simulated partial discharge signal into the gas-insulated equipment, and performing an injection of the simulated partial discharge signal based on the injection command signal. Characteristic partial discharge measuring device.