JP5511639B2 - Partial discharge analyzer - Google Patents

Description

  The present invention relates to a partial discharge analyzer for analyzing partial discharge of, for example, high voltage equipment.

  A conventional partial discharge measuring apparatus includes a pulse generation frequency (n), a pulse generation phase (φ), a pulse signal intensity (q), a pulse generation duration (t), a pulse generation position (x), and a detection frequency (f). And a logical determination function for each feature data, and as a second determination function, a pattern determination function for fqt pattern change or xqt pattern change, or φ-qn data Is provided with a determination function using a two-mode neural network having the input data as input data to enable automatic determination of partial discharge (see Patent Document 1).

JP 2002-90412 A

  Since the conventional partial discharge measuring apparatus determines partial discharge by a pattern determination function or a determination function using a two-mode neural network, a high voltage for removing only the determination result and removing the cause of partial discharge When the device was disassembled, if this determination was incorrect, there was a problem that the duty to stably supply power could not be fulfilled and the burden on the economy was increased.

  The present invention has been made to solve the above-mentioned problems. Finally, an expert engineer correctly diagnoses and instructs a disassembly work for removing the cause of partial discharge based on the diagnosis result. The purpose is to obtain a partial discharge analyzer that can support.

  In order to solve the above-described problems and achieve the object, a partial discharge analyzer according to the present invention is installed in a high voltage device and detects a partial discharge signal resulting from the partial discharge generated in the high voltage device. A plurality of partial discharge sensors, a detection unit that detects the pulse generation frequency (n) of the partial discharge from the partial discharge signals detected by these partial discharge sensors, and a pulse generation frequency (n that is detected by the detection unit) ) In the storage unit together with the detection time and the installation locations of the plurality of partial discharge sensors, the pulse generation frequency (n), the detection time, and the plurality of partial discharge sensors from the storage unit The installation location of each partial discharge sensor is displayed on the image diagram of the high-voltage device together with a display indicating the installation location of each partial discharge sensor at the specified time. A display control unit that creates a state diagram that displays a display indicating the magnitude of the frequency (n), and a display unit that displays the state diagram created by the display control unit, the display control unit comprising: The state diagram is created by switching the designated time according to the input time switching signal.

  According to the present invention, an expert engineer can provide support for making a final diagnosis, and the cause of partial discharge can be efficiently removed.

FIG. 1 is a diagram illustrating a configuration example of a partial discharge analyzer according to an embodiment. FIG. 2 is an example of a state diagram. FIG. 3 is another example of a state diagram. FIG. 4 is a diagram illustrating a three-dimensional display example of the state diagram of FIG.

  Embodiments of a partial discharge analyzer according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
FIG. 1 is a diagram illustrating a configuration example of a partial discharge analyzer according to the present embodiment. Here, the partial discharge analyzer detects and analyzes a partial discharge generated in, for example, a high voltage device. FIG. 1 shows an example in which this partial discharge analyzer is applied to, for example, a gas insulated switchgear.

  The gas insulated switchgear includes, for example, a cylindrical tank 1 filled with an insulating gas, an insulating spacer 2 disposed between the flanges of the tank 1, and an insulating spacer 2 housed in the tank 1 for insulating support. The high-voltage conductor 3 is provided. In the illustrated example, for example, three tanks 1 are connected.

  Next, the configuration of the partial discharge analyzer will be described. For example, three partial discharge sensors 4 are built in the gas insulated switchgear. Specifically, the partial discharge sensor 4 is disposed on the inner bottom surface of each tank 1, for example. The partial discharge sensor 4 detects a high-frequency electromagnetic wave signal generated by the partial discharge power source.

  Each partial discharge sensor 4 is connected to an amplifying unit 5. The amplifying unit 5 amplifies the high-frequency signal output from the partial discharge sensor 4. Each amplification unit 5 is connected to a detection unit 6. Based on the output of each amplifying unit 5, the detection unit 6, for example, generates a pulse generation frequency (n), a pulse generation phase (φ), a pulse signal intensity (q), a pulse generation duration (t), a pulse generation position ( x), the detection frequency (f), and the like are detected. As a detection method, for example, a known detection method can be used.

  The detection unit 6 is connected to the control processing unit 7. The output of the detection unit 6 is input to the control processing unit 7. The control processing unit 7 is realized by a CPU that operates according to a predetermined program. The control processing unit 7 is connected to the comparison units 9-1 to 9-p (p is an integer of 1 or more) and the storage units 10 to 12, respectively. The comparison units 9-1 to 9-p are connected to the partial discharge pattern storage units 8-1 to 8-p, respectively. The partial discharge pattern storage unit 8 stores partial discharge patterns corresponding to the types of partial discharges measured in advance. Here, the partial discharge pattern is, for example, a φ-qn pattern. For example, the partial discharge pattern φ-q-n generated due to the defect of the insulator is stored in the partial discharge pattern storage unit 8-1, and the partial discharge pattern φ-q-n generated due to the floating electrode is partially discharged. The partial discharge pattern φ-qn, which is different in p types, such as the partial discharge pattern φ-qn generated by the needle electrode due to the pattern storage unit 8-2 being used as the partial discharge pattern storage unit 8-3. Are stored in the partial discharge pattern storage units 8-1 to 8-p, respectively.

  The storage units 10 to 12 are each connected to the display control unit 13. Note that the storage units 10 to 12 may be integrated. For example, a display switching signal A1, a time switching signal A2, or a display sensor switching signal A3 is input to the display control unit 13 via the input unit 15. The display control unit 13 performs display control of the display unit 14.

  Next, the operation of the present embodiment will be described. First, the partial discharge sensor 4 receives a high-frequency signal generated by partial discharge caused by, for example, insulation failure in the gas insulated switchgear. The amplifying unit 5 amplifies a weak high-frequency signal received by each partial discharge sensor 4. From the high-frequency signal output from each amplifying unit 5, the detection unit 6 detects the pulse generation frequency (n), the pulse generation phase (φ), the pulse signal intensity (q), the pulse generation duration (t), and the pulse generation position (x ) And a detection frequency (f).

  The control processing unit 7 detects the pulse generation frequency (n), which is the output of the detection unit 6, the time when the high frequency signal is detected (the time when the pulse is generated, hereinafter referred to as “detection time”), and the partial discharge sensor 4. The installation location is recorded in the storage unit 10. Here, the pulse generation frequency (n) is recorded for each detection time and for each installation location of the partial discharge sensor 4. The detection time is output to the control processing unit 7 by the detection unit 6. The location of the partial discharge sensor 4 is given as information to the control processing unit 7 in advance. In addition, the control processing unit 7 records the pulse signal intensity (q) that is the output of the detection unit 6, the detection time, and the installation location of the partial discharge sensor 4 in the storage unit 11. Here, the pulse signal intensity (q) is recorded for each detection time and for each installation location of the partial discharge sensor 4. Further, the control processing unit 7 creates a partial discharge pattern φ-q-n from, for example, the pulse generation frequency (n), the pulse generation phase (φ), and the pulse signal intensity (q) that are the outputs of the detection unit 6. The partial discharge patterns φ-qn are output to the comparison units 9-1 to 9-p, respectively.

  The comparison unit 9 compares the partial discharge pattern φ−q−n output from the control processing unit 7 with the partial discharge pattern φ−q−n stored in the partial discharge pattern storage unit 8 and performs control processing on the comparison result. Output to unit 7. For example, the comparison unit 9-1 includes the partial discharge pattern φ-q-n output from the control processing unit 7 and the partial discharge pattern φ-qn of the insulator defect stored in the partial discharge pattern storage unit 8-1. And compare. The comparison unit 9-2 compares the partial discharge pattern φ-q-n output from the control processing unit 7 with the partial discharge pattern φ-q-n of the floating electrode stored in the partial discharge pattern storage unit 8-2. To do. The comparison unit 9-3 compares the partial discharge pattern φ-q-n output from the control processing unit 7 with the partial discharge pattern φ-q-n of the needle electrode stored in the partial discharge pattern storage unit 8-3. Etc.

  The control processing unit 7 receives the outputs of the comparison units 9-1 to 9-p, and uses the partial discharge pattern type most similar to the partial discharge pattern output from the control processing unit 7 to the comparison unit 9 as the determination result. The determination result is recorded in the storage unit 12 together with the detection time and the location of the partial discharge sensor 4. Here, the determination result is recorded for each detection time and for each installation location of the partial discharge sensor 4. For example, when the output of the comparison unit 9-1 is similar to the outputs of the comparison units 9-2 to 9-p, the determination result is a defect in the insulator. In addition, the comparison of the partial discharge patterns in the comparison units 9-1 to 9-p can be performed based on, for example, existing pattern recognition, and the determination result can be quantified according to the degree of similarity, for example. Therefore, for example, the control processing unit 7 compares the numerical values of the outputs of the comparison units 9-1 to 9-p, and the partial discharge pattern φ-q− output from the control processing unit 7 with the largest numerical value is compared. It can be determined that it is most similar to n. However, if each output of the comparison units 9-1 to 9-p is smaller than a preset threshold value, the control processing unit 7 determines the determination result as external noise.

  In the above description, the partial discharge pattern storage unit 8 stores the φ-q-n pattern. However, the present invention is not limited to this, and the φ-n pattern, the φ-q pattern, and the xq-t pattern. Or an fqt pattern or the like. In this case, the control processing unit 7 outputs the pulse generation frequency (n), the pulse generation phase (φ), the pulse signal intensity (q), the pulse signal intensity (q), and the pulse generation duration (t ), The above-mentioned pattern corresponding to the partial discharge pattern stored in the partial discharge pattern storage unit 8 is created from the pulse generation position (x) and the detection frequency (f), and these are compared with the comparison units 9-1 to 9-p. Respectively.

  The display control unit 13 reads the pulse generation frequency (n), the detection time, and the installation location of the partial discharge sensor 4 from the storage unit 10, creates a corresponding state diagram based on the read information, and displays this on the display unit 14. A state diagram can be displayed. Further, the display control unit 13 reads the pulse signal intensity (q), the detection time, and the installation location of the partial discharge sensor 4 from the storage unit 11, creates a corresponding state diagram based on the read information, and displays the display unit 14. This state diagram can be displayed.

  FIG. 2 is an example of a state diagram. The gas-insulated switchgear according to the present embodiment is a three-phase AC power supply device, where G1-1 is a first-phase device, G1-2 is a second-phase device, and G1-3 is a third-phase device. And the image figure is shown. G2-1, G2-2, and G2-3 represent the devices of the respective phases of the other gas-insulated switchgear and their image diagrams. Moreover, S1, S2, and S3 have each shown the installation place of the partial discharge sensor. S1 to S3 correspond to the partial discharge sensor 4 of FIG.

  In FIG. 2, the image diagrams (G1-1 to G1-3 and G2-1 to G2-3) of the gas insulated switchgear (portions 1 to 4) shown in FIG. 1 are arranged and displayed. Here, the image diagram is, for example, a schematic longitudinal sectional view of a gas insulated switchgear. Further, the partial discharge sensors S1 to S3 are all installed in the same place, for example, three by three. That is, the installation locations of the partial discharge sensors S1 to S3 correspond to each other between G1-1 to G1-3 and G2-1 to G2-3. Although the illustrated example corresponds to a phase-separated state diagram, a three-phase collective state diagram can be created in the same manner.

  The display control unit 13 displays the magnitude of the pulse generation frequency (n) at a specific time on the display unit 14 as a distribution superimposed on the image diagram of the gas insulated switchgear. Moreover, the magnitude | size in the installation place of partial discharge sensor S1-S3 is displayed for pulse generation frequency (n). The display of the pulse generation frequency (n) is distinguished according to the magnitude, and in the illustrated example, the magnitude is distinguished by, for example, color-coding every 0 pps, 100 pps, 300 pps, 1000 pps, and 3000 pps. Here, pps = pulse per second (occurrence frequency per second). In FIG. 2, the pulse generation frequency (n) = 3000 pps in the place (gas section) where the G1-1 partial discharge sensor S1 is installed. The same applies to the place (gas section) where the partial discharge sensors S3 of G2-1 to G2-3 are installed. In other cases, the pulse generation frequency (n) = 0 pps. In addition, you may display the magnitude | size of pulse generation frequency (n) by the numerical value, for example.

The display control unit 13 displays the list M1 (first list) at one end in the arrangement direction of, for example, G1-1 to G1-3 and G2-1 to G2-3. The display control unit 13 creates the list M1 as follows. The display control unit 13 normally has a display start time designated in advance for each of the partial discharge sensors S1 to S3 for all six of G1-1 to G1-3 and G2-1 to G2-3. between (t _s) and the display end time (t _e), calculates a value obtained by adding the pulse frequency (n) at the installation location of each partial discharge sensor (total size of the pulse frequency (n)) The added value is displayed in time series between the display start time and the display end time. For example, the partial discharge sensors S1 on the imaginary line 11 are installed at locations corresponding to each other between G1-1 to G1-3 and G2-1 to G2-3, but all of these six partial discharge sensors S1. The total of the pulse generation frequency (n) at each installation location is calculated, and this total value is calculated between the display start time and the display end time. This is indicated by m11, and it can be seen that the pulse generation frequency (n) increases, for example, with time. Further, for example, the partial discharge sensors S2 on the imaginary line 12 are installed at locations corresponding to each other between G1-1 to G1-3 and G2-1 to G2-3. For the sensor S2, the total of the pulse generation frequency (n) at each installation location is calculated, and this total value is calculated between the display start time and the display end time. This is indicated by m12, and it can be seen that the pulse generation frequency (n) is 0 regardless of time, for example. Further, for example, the partial discharge sensor S3 on the imaginary line l3 is installed at a location corresponding to each other between G1-1 to G1-3 and G2-1 to G2-3. For the sensor S3, the total of the pulse generation frequency (n) at each installation location is calculated, and this total value is calculated between the display start time and the display end time. This is indicated by m13, and the pulse generation frequency (n) is, for example, 3000 pps regardless of time. The value of the pulse frequency (n) in the image view of the gas insulated switchgear is a value in, for example, the time t _e. As described above, the list M1 displays a list of differences in the magnitude of the pulse generation frequency (n) in time series.

  The display control unit 13 displays a list M2 (second list) at one end in a direction orthogonal to the arrangement direction of, for example, G1-1 to G1-3 and G2-1 to G2-3. The display control unit 13 creates the list M2 as follows. The display control unit 13 normally starts display for all three of the partial discharge sensors S1 to S3 for G1-1 to G1-3 and G2-1 to G2-3, respectively. A value obtained by adding the pulse generation frequency (n) at the installation location of each partial discharge sensor between the time and the display end time is calculated (the total size of the pulse generation frequency (n)), and this added value is displayed. Display in time series between the start time and the display end time. For example, for all three partial discharge sensors S1 to S3 on the imaginary line 14, the sum of pulse generation frequencies (n) at each installation location is calculated, and this total value is calculated between the display start time and the display end time. Calculate with This is indicated by m21, and it can be seen that, for example, the pulse generation frequency (n) increases with time. In addition, for example, for all three partial discharge sensors S1 to S3 on the virtual line l5, the sum of the pulse generation frequencies (n) at each installation location is calculated, and the total value is displayed as the display start time and the display end time. Calculate between. This is indicated by m22, and it can be seen that the pulse generation frequency (n) is 0, for example, regardless of the time. The same applies to m23 to m26 corresponding to the virtual lines l6 to l9, respectively. As described above, the list M2 displays a list of differences in the magnitude of the pulse generation frequency (n) in time series.

  Moreover, the display control part 13 can select the partial discharge sensor which adds up pulse generation frequency (n) with the input display sensor switching signal A3. For example, when G1-1 is designated by the display sensor switching signal A3, the display control unit 13 selects G1-1, and the list M1 includes a state diagram for only G1-1 (in the case of the above added value). Series change) is displayed. In general, the display control unit 13 uses the frequency of pulse generation at each installation location for each of the partial discharge sensors S1 to S3 for the gas-insulated switchgear specified in G1-1 to G1-3 and G2-1 to G2-3. The sum of (n) is calculated. For example, when the partial discharge sensor S1 is designated by the display sensor switching signal A3, the display control unit 13 selects the partial discharge sensor S1, and the list M2 includes G1-1 to G1-3 and G2-. A state diagram (time-series change of the added value) for each of the partial discharge sensors S1 of 1 to G2-3 is displayed. In general, the display control unit 13 calculates the sum of pulse generation frequencies (n) at the respective installation locations for the designated partial discharge sensors among the partial discharge sensors S1 to S3 for each gas-insulated switchgear.

  Further, the display control unit 13 can switch the display of the pulse generation frequency (n) to the display of the pulse signal intensity (q) according to the input display switching signal A1. That is, on the image diagram of the gas-insulated switchgear, the distribution of the pulse signal intensity (q) is displayed instead of the distribution of the pulse generation frequency (n), and the added value in the list M1, M2 is the pulse signal intensity (q ) Is added. Note that the display of the pulse signal intensity (q) is distinguished depending on the magnitude. In FIG. 2, however, the magnitude is distinguished by, for example, color-coding every 0 pc, 5 pc, 10 pc, 30 pc, and 100 pc. Yes. Here, pc = pico coulomb (unit of charge amount). The rest of the state diagram of the pulse signal intensity (q) is the same as the state diagram of the pulse generation frequency (n).

Moreover, the display control part 13 can designate the detection time of the distribution displayed on the image figure of a gas insulated switchgear by the input time switching signal A2. Further, the display control unit 13, by the time the switching signal A2 inputted, it is possible to specify individual display end time t _e and the display start time t _s of the list M1, M2.

  The display control unit 13 can read the determination result, the detection time, and the installation location of the partial discharge sensor 4 from the storage unit 12 and display a state diagram on the display unit 14 based on the read information.

  FIG. 3 is another example of a state diagram. In FIG. 3, the display which shows the determination result in specific time is overlaid and displayed on the image figure G1-1-G1-3, G2-1-G2-3 of a gas insulated switchgear. In other words, the display control unit 13 causes the display unit 14 to display the partial discharge pattern determination result as a distribution on the image diagram. For example, 1H is an insulation defect pattern, 2H is a floating electrode pattern, 4H is a needle electrode pattern, and 8H is a determination result representing external noise. H indicates that the numerical value is a hexadecimal number. Accordingly, the determination result is displayed as, for example, a hexadecimal number on the image diagram. However, the display method for distinguishing the determination results is not limited to this. Moreover, the determination result displays the result at the installation location of the partial discharge sensors S1 to S3. In FIG. 3, a portion where no determination result is displayed represents a portion where no partial discharge or external noise occurs. Each image diagram of the gas insulated switchgear, partial discharge sensors S1 to S3, virtual lines 11 to 19 and the like are the same as those in FIG. In FIG. 3, the list M1 and M2 of the determination results are displayed together with the image diagram in the same manner as in FIG.

The display control unit 13 creates the list M1 as follows. The display control unit 13 normally has a display start time designated in advance for each of the partial discharge sensors S1 to S3 for all six of G1-1 to G1-3 and G2-1 to G2-3. between (t _s) and the display end time (t _e), performs an OR operation on the bit operation on numbers (hexadecimal) of the judgment result at the installation location of each partial discharge sensor, and a display start time the result of the calculation Display in time series with the display end time. For example, the partial discharge sensors S1 on the imaginary line 11 are installed at locations corresponding to each other between G1-1 to G1-3 and G2-1 to G2-3, but all of these six partial discharge sensors S1. For the above, the OR operation of the numerical value of the determination result at each installation place is performed by bit operation, and this operation is performed between the display start time and the display end time. This is indicated by m11, and it can be seen that the insulator defect pattern 1H has appeared from a certain time. In the OR operation, if no determination result is displayed at the location of the partial discharge sensor, the calculation is performed assuming that the determination result is “0”. The same applies to m12 to m13 corresponding to the virtual lines l2 to l3, respectively.

The display control unit 13 creates the list M2 as follows. The display control unit 13 normally starts display for all three of the partial discharge sensors S1 to S3 for G1-1 to G1-3 and G2-1 to G2-3, respectively. Between the time (t _s ) and the display end time (t _e ), the OR operation is performed by bit operation on the numerical value (hexadecimal) of the determination result at the installation location of each partial discharge sensor, and this calculation result is displayed at the display start time. And display end time in a time series. For example, for all three partial discharge sensor S1~S3 on the virtual line l4, performs OR operation on numerical values of the determination in each location by bit manipulation, yet the display end display start time of the operation (t _s) It is performed between time (t _e ). This is indicated by m21, and it can be seen that the insulator deficient pattern 1H appeared from a certain time. In the OR operation, if no determination result is displayed at the location of the partial discharge sensor, the calculation is performed assuming that the determination result is “0”. The same applies to m22 to m26 corresponding to the virtual lines l5 to l9, respectively.

Here, the hexadecimal notation of the determination result and the bitwise OR operation will be specifically described. Each pattern is expressed in hexadecimal and binary notation as follows ('b' indicates bit notation).
Insulator defect pattern: 1H = 0001b
Floating electrode pattern: 2H = 0010b
Needle electrode pattern: 4H = 0100b
External noise: 8H = 1000b
For example, when an insulator defect pattern: 1H (= 0001b) and a floating electrode pattern: 2H (= 0010b) are generated in a certain area (for example, an installation area of the partial discharge sensor S1), Performs an OR operation for each bit of the decimal number. That is, when the OR operation is performed on the first bit “1” from the right of the insulator defect pattern: 0001b and the first bit “0” from the right of the floating electrode pattern: 0010b, the result is “1”. Similarly, the operation result of the second bit from the right is “1”, the operation result of the third and fourth bits from the right is “0”, and the operation result of all bits is 0011b (= 3H). In addition, when the needle electrode pattern: 4H (= 0100b) is generated, the operation result of all bits is 0111b (= 7H). Therefore, by expressing the result of the OR operation in hexadecimal, it is possible to easily determine which pattern has occurred in the area.

  Moreover, the display control part 13 can select the partial discharge sensor which displays a determination result with the input display sensor switching signal A3. For example, when G1-1 is designated by the display sensor switching signal A3, the display control unit 13 selects G1-1, and the list M1 includes a state diagram for only G1-1 (when the above calculation result is obtained). Series change) is displayed. For example, when the partial discharge sensor S1 is designated by the display sensor switching signal A3, the display control unit 13 selects the partial discharge sensor S1, and the list M2 includes G1-1 to G1-3 and G2-. A state diagram (time series change of the calculation result) for each of the partial discharge sensors S1 of 1 to G2-3 is displayed. The other general cases are the same as those described in FIG.

  Further, the display control unit 13 switches the display from the pulse generation frequency (n) or pulse signal intensity (q) state diagram of FIG. 2 to the determination result state diagram of FIG. 3 according to the input display switching signal A1. be able to. That is, the display control unit 13 can switch and display the pulse generation frequency (n), the pulse signal intensity (q), or the state diagram of the determination result, and the selection of the state diagram is determined by the display switching signal A1. be able to.

Moreover, the display control part 13 can designate the detection time of the determination result displayed on the image figure of a gas insulated switchgear by the input time switching signal A2. Further, the display control unit 13, by the time the switching signal A2 inputted, it is possible to specify individual display end time t _e and the display start time t _s of the list M1, M2.

  FIG. 4 is a diagram illustrating a three-dimensional display example of the state diagram of FIG. That is, the magnitude of the pulse generation frequency (n) displayed on the image diagram of the gas insulated switchgear of FIG. 2 is expressed with respect to the axes representing S1 to S3, the axes representing G1-1 to 2-3, and the time axis. It is displayed in three dimensions. In FIG. 2 or FIG. 3, the partial discharge sensor to be selected is designated by the display sensor switching signal A3 when creating the state diagram, but in this embodiment, the viewing angle can be freely set by making the state diagram a three-dimensional diagram. Since it can be switched, more efficient analysis is possible. It is assumed that the display control unit 13 can create a 3D diagram and switch the display angle of the created 3D diagram. Further, the display unit 14 may be a three-dimensional display, for example. If the display unit 14 is a three-dimensional display, humans can perform a three-dimensional analysis by showing separate images to the left and right eyes, which is more efficient.

  As described above, the partial discharge analyzer according to the present embodiment can analyze the partial discharge generated in the gas-insulated switchgear and can switch and display the partial discharge sensor, time, and analysis contents. Therefore, according to the present embodiment, it is possible to provide assistance for an expert engineer to make a final diagnosis, and there is an effect that the cause of partial discharge can be efficiently removed. Expert engineers can diagnose the presence or absence of partial discharge more efficiently and accurately by referring to various state diagrams, and the disassembly work of high-voltage equipment to eliminate the cause of partial discharge. It is possible to efficiently determine whether or not to give an instruction.

  In the above description, the case of the gas-insulated switchgear is described as an example of the application of the present invention, but the present invention can also be used for other high-voltage devices.

  The present invention is useful as a partial discharge analyzer for analyzing partial discharge of high voltage equipment such as a gas insulated switchgear.

DESCRIPTION OF SYMBOLS 1 Tank 2 Insulation spacer 3 High voltage conductor 4 Partial discharge sensor 5 Amplification part 6 Detection part 7 Control processing part 8 Partial discharge pattern memory | storage part 9 Comparison part 10-12 Storage part 13 Display control part 14 Display part 15 Input part A1 Display switching Signal A2 Time switching signal A3 Display sensor switching signal M1, M2 List S1-S3 Partial discharge sensor l1-l9 Virtual line

Claims (12)

A plurality of partial discharge sensors that are installed in a high voltage device and detect a partial discharge signal caused by the partial discharge generated in the high voltage device;
From the partial discharge signals detected by these partial discharge sensors, a detection unit for detecting the pulse generation frequency (n) of the partial discharge,
A control processing unit that records the pulse generation frequency (n) detected by the detection unit in the storage unit together with the detection time and the installation locations of the plurality of partial discharge sensors;
The pulse generation frequency (n), the detection time, and the installation locations of the plurality of partial discharge sensors are read from the storage unit, and designated together with a display showing the installation locations of the partial discharge sensors on the image diagram of the high-voltage device A display control unit that creates a state diagram for displaying a display indicating the magnitude of the pulse generation frequency (n) at each installation location at a given time,
A display unit for displaying a state diagram created by the display control unit;
With
The partial discharge analyzer according to claim 1, wherein the display control unit creates the state diagram by switching the designated time according to an input time switching signal. A plurality of the high voltage devices are installed,
Installation locations of the plurality of partial discharge sensors correspond to each other between the plurality of high voltage devices,
In the state diagram, the image diagrams of the plurality of high-voltage devices are arranged and displayed,
The display control unit is a value obtained by adding a pulse generation frequency (n) at the installation location to the partial discharge sensors corresponding to the installation location for the designated high-voltage device among the plurality of high-voltage devices. Is generated in a time series between the display start time and the display end time, and a first list is created for each partial discharge sensor corresponding to each of the installation locations, For a specified partial discharge sensor among the plurality of partial discharge sensors, a value obtained by adding the pulse generation frequency (n) at the installation location of the partial discharge sensor is calculated between the display start time and the display end time. The state diagram for creating a second list in which the items displayed in series are listed for each high-voltage device, and displaying the first and second lists in correspondence with the image diagram Partial discharge analysis apparatus according to claim 1, wherein the creating. The detection unit detects the pulse signal intensity (q) of the partial discharge,
The control processing unit records the pulse signal intensity (q) detected by the detection unit in the storage unit together with the detection time and the installation location of the plurality of partial discharge sensors,
The display control unit generates the pulse signal intensity (q) and the detection from the storage unit instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal. The time and the installation location of the plurality of partial discharge sensors are read out, and the pulse signal intensity at each installation location at a designated time together with a display indicating the installation location of each partial discharge sensor on the image diagram of the high-voltage device 2. The partial discharge analyzer according to claim 1, wherein a state diagram in which a display indicating a magnitude of (q) is superimposed is created, and the created state diagram is displayed on the display unit. A plurality of the high voltage devices are installed,
Installation locations of the plurality of partial discharge sensors correspond to each other between the plurality of high voltage devices,
In the state diagram, the image diagrams of the plurality of high-voltage devices are arranged and displayed,
The display control unit is a value obtained by adding the pulse signal intensity (q) at the installation location to the partial discharge sensors corresponding to the installation location for the designated high-voltage device among the plurality of high-voltage devices. Is generated in a time series between the display start time and the display end time, and a first list is created for each partial discharge sensor corresponding to each of the installation locations, The value obtained by adding the pulse signal intensity (q) at the installation location of the partial discharge sensor for the designated partial discharge sensor among the plurality of partial discharge sensors is calculated between the display start time and the display end time. The state diagram for creating a second list in which the items displayed in series are listed for each high-voltage device, and displaying the first and second lists in correspondence with the image diagram Partial discharge analysis apparatus according to claim 3, wherein the creating.   The display control unit generates the first list by switching the designated high-voltage device according to the input display sensor switching signal, or switches the designated partial discharge sensor to the second The partial discharge analyzer according to claim 2 or 4, wherein a list of the above is created.   5. The display control unit according to claim 2, wherein the display control unit creates the first list and the second list by switching at least one of the display start time and the display end time according to the time switching signal. The partial discharge analyzer of description. A comparison unit connected to the control processing unit;
A partial discharge pattern storage connected in advance to the comparison unit and storing in advance partial discharge patterns for a plurality of types of pulse generation phases (φ) -pulse signal intensity (q) -pulse generation frequency (n) according to the type of partial discharge And
With
The detection unit detects a pulse generation frequency (n), a pulse generation phase (φ), and a pulse signal intensity (q) of the partial discharge,
The control processing unit creates a φ-q-n pattern from the pulse generation frequency (n), the pulse generation phase (φ), and the pulse signal intensity (q) detected by the detection unit, and then generates this φ-q -N pattern is output to the comparator,
The comparison unit compares the φ-qn pattern output from the control processing unit with the plurality of types of partial discharge patterns stored in the partial discharge pattern storage unit, and compares the comparison result with the control. Output to the processing unit,
The control processing unit determines, from the comparison result, a partial discharge pattern type that is most similar to the φ-qn pattern among the plurality of types of partial discharge patterns as a determination result. Record in the storage unit together with the installation location of a plurality of partial discharge sensors,
Instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal, the display control unit generates the determination result, the detection time, and the plurality of times from the storage unit. The installation location of each partial discharge sensor is read out, and the display showing the determination result at each installation location at the specified time is overlaid on the image diagram of the high-voltage device together with the display showing the installation location of each partial discharge sensor. The partial discharge analyzer according to claim 1, wherein a state diagram to be displayed is created, and the created state diagram is displayed on the display unit. A comparison unit connected to the control processing unit;
A partial discharge pattern storage unit that is connected to the comparison unit and stores in advance partial discharge patterns for a plurality of types of pulse generation phases (φ) -pulse generation frequencies (n) corresponding to the types of partial discharges;
With
The detection unit detects the pulse generation frequency (n) and the pulse generation phase (φ) of the partial discharge,
The control processing unit generates a φ-n pattern from the pulse generation frequency (n) and the pulse generation phase (φ) detected by the detection unit, and then outputs the φ-n pattern to the comparison unit.
The comparison unit compares the φ-n pattern output from the control processing unit with the plurality of types of partial discharge patterns stored in the partial discharge pattern storage unit, and compares the comparison result with the control processing unit. Output to
The control processing unit determines, from the comparison result, a partial discharge pattern type most similar to the φ-n pattern among the plurality of types of partial discharge patterns as a determination result, and uses the determination result as a detection time and the plurality of partial discharge patterns. Recorded in the storage unit together with the location of the partial discharge sensor,
Instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal, the display control unit generates the determination result, the detection time, and the plurality of times from the storage unit. The installation location of each partial discharge sensor is read out, and the display showing the determination result at each installation location at the specified time is overlaid on the image diagram of the high-voltage device together with the display showing the installation location of each partial discharge sensor. The partial discharge analyzer according to claim 1, wherein a state diagram to be displayed is created, and the created state diagram is displayed on the display unit. A comparison unit connected to the control processing unit;
A partial discharge pattern storage unit that is connected to the comparison unit and stores in advance partial discharge patterns for a plurality of types of pulse generation phases (φ) -pulse signal intensity (q) according to the type of partial discharge;
With
The detection unit detects a pulse generation phase (φ) of the partial discharge and a pulse signal intensity (q),
The control processing unit generates a φ-q pattern from the pulse generation phase (φ) detected by the detection unit and the pulse signal intensity (q), and then outputs the φ-q pattern to the comparison unit.
The comparison unit compares the φ-q pattern output from the control processing unit with the plurality of types of partial discharge patterns stored in the partial discharge pattern storage unit, and compares the comparison result with the control processing unit. Output to
The control processing unit determines, from the comparison result, a partial discharge pattern type most similar to the φ-q pattern among the plurality of types of partial discharge patterns as a determination result, and uses the determination result as the detection time and the plurality of partial discharge patterns. Recorded in the storage unit together with the location of the partial discharge sensor,
Instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal, the display control unit generates the determination result, the detection time, and the plurality of times from the storage unit. The installation location of each partial discharge sensor is read out, and the display showing the determination result at each installation location at the specified time is overlaid on the image diagram of the high-voltage device together with the display showing the installation location of each partial discharge sensor. The partial discharge analyzer according to claim 1, wherein a state diagram to be displayed is created, and the created state diagram is displayed on the display unit. A comparison unit connected to the control processing unit;
A partial discharge pattern storage connected in advance to the comparison unit and storing in advance partial discharge patterns for a plurality of types of detection frequencies (f) -pulse signal intensity (q) -pulse generation duration (t) corresponding to the type of partial discharge And
With
The detection unit detects a detection frequency (f), a pulse signal intensity (q), and a pulse generation duration (t) of the partial discharge,
The control processing unit creates an fqt pattern from the detection frequency (f), pulse signal strength (q), and pulse generation duration (t) detected by the detection unit, -T pattern is output to the comparison unit;
The comparison unit compares the fqt pattern output from the control processing unit with the plurality of types of partial discharge patterns stored in the partial discharge pattern storage unit, and compares the comparison result with the control. Output to the processing unit,
The control processing unit determines, from the comparison result, a partial discharge pattern type most similar to the fqt pattern among the plurality of types of partial discharge patterns as a determination result, and uses the determination result as the detection time and the Record in the storage unit together with the installation location of a plurality of partial discharge sensors,
Instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal, the display control unit generates the determination result, the detection time, and the plurality of times from the storage unit. The installation location of each partial discharge sensor is read out, and the display showing the determination result at each installation location at the specified time is overlaid on the image diagram of the high-voltage device together with the display showing the installation location of each partial discharge sensor. The partial discharge analyzer according to claim 1, wherein a state diagram to be displayed is created, and the created state diagram is displayed on the display unit. A comparison unit connected to the control processing unit;
A partial discharge pattern that is connected to the comparison unit and stores in advance partial discharge patterns for a plurality of types of pulse generation positions (x) -pulse signal intensity (q) -pulse generation duration (t) according to the type of partial discharge A storage unit;
With
The detection unit detects a pulse generation position (x), a pulse signal intensity (q), and a pulse generation duration (t) of the partial discharge,
The control processing unit creates an xqt pattern from the pulse generation position (x), the pulse signal intensity (q), and the pulse generation duration (t) detected by the detection unit, outputting the q-t pattern to the comparison unit;
The comparison unit compares the xqt pattern output from the control processing unit with the plurality of types of partial discharge patterns stored in the partial discharge pattern storage unit, and compares the comparison result with the control. Output to the processing unit,
The control processing unit determines, from the comparison result, a partial discharge pattern type most similar to the xqt pattern among the plurality of types of partial discharge patterns as a determination result, and uses the determination result as the detection time and the Record in the storage unit together with the installation location of a plurality of partial discharge sensors,
Instead of creating the state diagram indicating the magnitude of the pulse generation frequency (n) based on the input display switching signal, the display control unit generates the determination result, the detection time, and the plurality of times from the storage unit. The installation location of each partial discharge sensor is read out, and the display showing the determination result at each installation location at the specified time is overlaid on the image diagram of the high-voltage device together with the display showing the installation location of each partial discharge sensor. The partial discharge analyzer according to claim 1, wherein a state diagram to be displayed is created, and the created state diagram is displayed on the display unit. The display unit is a three-dimensional display;
The partial display analyzer according to claim 1, wherein the display control unit displays the state diagram created as a three-dimensional diagram on the display unit.