CN211528594U - Partial discharge simulation test system based on oscillatory wave - Google Patents
Partial discharge simulation test system based on oscillatory wave Download PDFInfo
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- CN211528594U CN211528594U CN201922365352.8U CN201922365352U CN211528594U CN 211528594 U CN211528594 U CN 211528594U CN 201922365352 U CN201922365352 U CN 201922365352U CN 211528594 U CN211528594 U CN 211528594U
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Abstract
A partial discharge simulation test system based on oscillation waves belongs to the technical field of partial discharge tests. Including cable (5), be provided with the test point in cable (5), the inner core and the sheath of test point department are test joint mechanism (3) respectively and are drawn forth, and test joint mechanism (3) are pegged graft with test plug mechanism, and the oscillatory wave signal discharges in test module (15) are put in the office in test plug mechanism, still includes following step: step 1001, calculating an initial voltage; step 1002, inserting the test plug mechanism and the test joint mechanism (3); step 1003, connecting the cable connector (6) with an oscillatory wave host; step 1004, outputting an oscillation wave signal; step 1005, observe the waveform. In the local discharge simulation test system based on the oscillatory wave, the actual oscillatory wave signal is input into the cable, so that the test waveform is convenient to identify, and technicians can conveniently master the oscillatory wave local discharge test technology to make the test technology closer to the actual test.
Description
Technical Field
A partial discharge simulation test system based on oscillation waves belongs to the technical field of partial discharge tests.
Background
The partial discharge phenomenon mainly refers to a phenomenon that only partial areas in an insulator of high-voltage electrical equipment are discharged, and according to power grid statistics, the partial discharge is an important reason causing the final insulation breakdown of the high-voltage electrical equipment and is also an important sign of insulation degradation. With the continuous progress of the technology, in order to guarantee the reliability of power supply, the national grid company also gradually pushes the planned maintenance of the cable to the state maintenance, and the oscillation wave partial discharge test is used as a new technology for cable state evaluation, so that the partial discharge defect of the cable can be timely found, the defect can be timely eliminated, and the normal operation of the cable can be guaranteed, therefore, the national grid company also sets the corresponding regulation and standard of the oscillation wave partial discharge test.
However, the time for introducing the local discharge of the oscillatory wave into the country is short, and the waveform of the local discharge test of the oscillatory wave is difficult to identify compared with a cable fault test, but the local discharge simulation system on the market at present can only simulate the classical maps with different local discharge defects and cannot bear high voltage, and in the actual local discharge test of the oscillatory wave, high voltage needs to be applied to the cable, so that the simulation system in the prior art is not beneficial to the mastering of technical personnel on the local discharge test technology of the oscillatory wave. Therefore, in order to facilitate the technical staff to master the oscillation wave partial discharge test technology, a simulation test system capable of bearing high voltage and making the simulation test system closer to the actual test is designed, which is a problem to be solved in the field.
SUMMERY OF THE UTILITY MODEL
The to-be-solved technical problem of the utility model is: the testing system overcomes the defects of the prior art, provides a local discharge simulation testing system based on the oscillatory wave, which is convenient for identifying the testing waveform by inputting an actual oscillatory wave signal into a cable, and is convenient for technical personnel to master the oscillatory wave partial discharge testing technology, so that the testing system is closer to the actual testing.
The utility model provides a technical scheme that its technical problem adopted is: this partial discharge simulation test system based on oscillatory wave, its characterized in that: the cable testing device comprises a shell, wherein a cable is wound in the shell, cable joints of the cable are led out from two ends of the shell, at least one test point is arranged at any position in the cable, test joint mechanisms which are in one-to-one correspondence with the test points are fixed on the side part of the shell, and an inner core and a protective layer at the test point are respectively led out and then connected into the test joint mechanisms; the test plug mechanism is inserted with the test joint mechanism, a partial discharge test module is arranged in the test plug mechanism, and an inner core and a protective layer at a test point are respectively connected into the partial discharge test module through the test joint mechanism; and outputting an oscillation wave signal for testing to the cable through the cable joint, wherein the oscillation wave signal enters the test plug mechanism through the test joint mechanism and is subjected to partial discharge in the partial discharge test module.
Preferably, the side part of the shell is provided with a joint fixing plate, the test joint mechanism is fixed on the joint fixing plate, and the test plug mechanism is inserted into the test joint mechanism from the outside of the shell.
Preferably, the test joint mechanism comprises two joint sockets fixed on the joint fixing plate from top to bottom, a jack is arranged at the center of one end of each joint socket, the other end of each joint socket penetrates through the joint fixing plate and then is fixed with the connecting cover, an opening of the connecting cover faces away from the joint fixing plate, a test point connecting line is led out from the opening of the connecting cover, one end of each test point connecting line is connected with the corresponding jack in the joint socket, and the other end of each test point connecting line is connected with an inner core or a.
Preferably, the test plug mechanism comprises a plug mechanism base, two slots are formed in one end face of the plug mechanism base, and a contact pin is fixed at each end of each slot; one end of each contact pin is connected with the test connector mechanism in an inserting mode, and the other end of each contact pin is led out from the back face of the plug mechanism base and then connected with the partial discharge test module.
Preferably, the contact pins are led out from the back of the plug mechanism base and then fixed through nuts, and are respectively connected with a plug connecting line for connecting with the partial discharge test module, a clamping opening is formed in the middle of the back of the plug mechanism base, and the partial discharge test module is fixed in the clamping opening.
Preferably, the back of the plug mechanism base is covered with a plug mechanism shell, a cover opening of the plug mechanism shell is in butt joint with the outer ring of the plug mechanism base and then is fixed through a bolt, and the back of the plug mechanism base is covered in the plug mechanism shell.
Preferably, it is characterized in that: the partial discharge testing mechanism comprises a group of butted insulators: the first insulator and the second insulator enter the first insulator and are connected through threads, and a discharge gap with adjustable distance is formed between the abutting surfaces of the first insulator and the second insulator;
and the discharge electrodes are respectively arranged in the first insulator and the second insulator, the end surfaces of the discharge electrodes protrude out of the first insulator and the second insulator, and the discharge electrodes are respectively connected with the inner core and the sheath of the cable through the test joint mechanism.
Preferably, a disk-shaped voltage equalizing member is fixed to each of the discharge electrodes; and an umbrella group structure is formed on the outer rings of the first insulator and the second insulator.
Compared with the prior art, the utility model discloses the beneficial effect who has is:
1. in the local discharge simulation test system based on the oscillatory wave, the actual oscillatory wave signal is input into the cable, so that the test waveform is convenient to identify, and technicians can conveniently master the oscillatory wave local discharge test technology to make the test technology closer to the actual test.
2. The first insulator and the second insulator are connected by screw threads, so that the width of the discharge gap can be adjusted by relative rotation of the first insulator and the second insulator.
3. A disk-shaped voltage equalizing part is fixed in each discharge electrode, and partial discharge can be prevented from being generated at the connection part of the plug connecting wire and the discharge electrode through the voltage equalizing part.
4. An umbrella group structure is formed on the outer rings of the first insulator and the second insulator, so that pollution flashover generated between the discharge electrodes during testing is effectively avoided.
Drawings
Fig. 1 is a schematic structural diagram of a partial discharge simulation test system based on an oscillation wave.
Fig. 2 is a schematic structural diagram of a test joint mechanism of a partial discharge simulation test system based on an oscillation wave.
Fig. 3 is a schematic structural diagram of a test plug mechanism of a partial discharge simulation test system based on an oscillatory wave.
Fig. 4 is a schematic diagram of a partial discharge test module of the partial discharge simulation test system based on the oscillation wave.
Fig. 5 is an equivalent circuit diagram of a partial discharge testing mechanism of a partial discharge simulation testing system based on an oscillation wave.
Fig. 6 is a schematic structural diagram of an embodiment 2 of a partial discharge simulation test system based on an oscillation wave.
Fig. 7 is a schematic structural diagram of a partial discharge test module in embodiment 3 of an oscillatory wave-based partial discharge simulation test system.
Wherein: 1. the test device comprises a shell 2, a connector fixing plate 3, a test connector mechanism 4, a cable winding part 5, a cable 6, a cable connector 7, a connecting cover 8, a test point connecting wire 9, a connector socket 10, a jack 11, a plug mechanism base 12, a contact pin 13, a plug mechanism shell 14, a plug connecting wire 15, a partial discharge test module 16, a voltage equalizing part 17, a wiring hole 18, a discharge electrode 19, a first insulator 20, a discharge gap 21, a second insulator 22 and a discharge tip.
Detailed Description
Fig. 1 to 5 are preferred embodiments of the present invention, and the present invention will be further explained with reference to fig. 1 to 7.
Example 1:
as shown in fig. 1, a partial discharge simulation test system based on oscillatory waves includes a vertically placed rectangular casing 1, a cable winding portion 4 is disposed at a central position of a bottom of an inner cavity of the casing 1, a cable 5 is wound on the cable winding portion 4, and the cable 5 is a section of cable without partial discharge defects. Two ends of the cable 5 connector are respectively led out from two opposite side surfaces at the bottom of the shell 1 as cable connectors 6.
In the present embodiment, two arbitrary positions of the cable 5 are set as test points, and the inner core and the sheath (ground) of the cable at the test points are respectively led out through the wires and connected to the test joint mechanism 3, and the test joint mechanism 3 is fixed on the side of the housing 1 through the joint fixing plate 2. On the side of the housing 1, two test connector mechanisms 3 are arranged from top to bottom, and are respectively connected with two test points arranged in the cable 5 correspondingly.
When the test plug mechanism is used, a test plug mechanism (see fig. 3) is firstly inserted into the test connector mechanism 3 corresponding to at least one test point, a partial discharge test module 15 is arranged in the test plug mechanism, the partial discharge test module 15 is connected with a cable inner core and a protective layer led out from the test point, finally, an oscillating wave signal is loaded to the cable 5 through the cable connector 6, and a partial discharge simulation test is realized through the partial discharge test module 15 connected with the test point of the cable 5 to obtain a corresponding waveform signal.
As shown in fig. 2, the test connection mechanism 3 includes two connection sockets 9 fixed on the connection fixing plate 2 from top to bottom, a central portion of one end of each connection socket 9 is provided with a plug hole 10, the other end of each connection socket passes through the connection fixing plate 2 and simultaneously passes through a central portion of a connection cover 7 located on the other side of the connection fixing plate 2, and the connection sockets 9 are fixed on the connection fixing plate 2 through the connection covers 7. The plug receptacles 10 on the connector sockets 9 face the side of the housing 1 and are plugged into the test plug arrangement described above. The opening of the connecting cover 7 faces back to the joint fixing plate 2, and test point connecting wires 8 are led out from the opening of the connecting cover, one ends of the two test point connecting wires 8 are connected with corresponding jacks 10 in the joint socket 9, and the other ends of the two test point connecting wires are respectively connected with the cable inner core and the sheath at the test line.
As shown in fig. 3, the test plug mechanism includes a plug mechanism base 11, a set of slots are formed on an end surface of the plug mechanism base 11, a pin 12 is fixed at the end of each slot, the distance between the two slots is the same as the distance between two connector sockets 9 in the test connector mechanism 3, when the test plug mechanism is butted with the test connector mechanism 3, the connector sockets 9 are integrally arranged in the slots of the test plug mechanism, and the pins 12 in the slots enter the corresponding jacks 10, thereby completing the plugging of the test plug mechanism and the test connector mechanism 3.
The front ends of the pins 12 are butted with the jacks 10, the rear ends of the pins penetrate through the slot walls of the slots and are led out from the back of the plug mechanism base 11 and then fixed through nuts, the pins are respectively connected with a plug connecting wire 14, a clamping opening is formed in the middle of the back of the plug mechanism base 11, the partial discharge test module 15 is fixed in the clamping opening, and the plug connecting wires 14 connected to the rear ends of the two pins 12 are connected into the partial discharge test module 15. The back of the plug mechanism base 11 is covered with a plug mechanism housing 13, the cover opening of the plug mechanism housing 13 is butted with the outer ring of the plug mechanism base 11 and then fixed through bolts, and the back of the plug mechanism base 11 is covered in the plug mechanism housing 13.
As shown in fig. 4, the partial discharge test mechanism 15 includes a set of insulators that are butted: the discharge gap structure comprises a first insulator 19 and a second insulator 21, wherein the abutting surfaces of the first insulator 19 and the second insulator 21 are both flat surfaces, a groove is formed in the abutting surface of the first insulator 19 and the second insulator 21, an internal thread is formed in the inner ring of the groove, the second insulator 21 is in threaded connection with the first insulator 19 through an external thread formed in the outer circumferential ring of the second insulator, so that a discharge gap 20 is formed between the abutting surfaces of the first insulator 19 and the second insulator 21, and the width of the discharge gap 20 can be adjusted through the relative rotation of the first insulator 19 and the second insulator 21.
The end surfaces of the first insulator 19 and the second insulator 21, which face away from the discharge gap 20, are respectively provided with a groove, the discharge electrodes 18 are respectively arranged in the grooves, the end surfaces of the discharge electrodes 18 protrude out of the first insulator 19 and the second insulator 21, the protruding end surfaces are provided with wiring holes 17, and the two plug connecting wires 14 led out from the pins 12 are respectively connected into the wiring holes 17 and connected with the two discharge electrodes 18 in the first insulator 19 and the second insulator 21.
Therefore, after the test connector mechanism 3 is plugged with the test plug mechanism, the two discharge electrodes 18 are respectively connected into the test connector mechanism 3 through the plug connecting lines 14 and the contact pins 12, and further connected with the inner core and the sheath of the cable at the test point through the jacks 10 and the test point connecting lines 8. After the oscillatory wave signal is applied to the cable joint 6, the oscillatory wave signal is applied to the discharge electrode 18 in the opposite direction through the communicating route, and the test is performed through the discharge electrode 18.
The equivalent circuit diagram of the partial discharge test mechanism 15 is shown in fig. 5, and includes a capacitor C connected in series1~C2Capacitor C1~C2Connected in series between terminals A, B, terminals A, B representing two discharge electrodes 18, respectively, capacitor C1The equivalent capacitance of the insulator is shown, and the specific meaning is as follows: let d denote the thickness between the bottom of the recess in the end face of the first insulator 19 and the discharge gap 201The thickness between the bottom of the recess in the end face of the second insulator 21 and the discharge gap 20 is denoted by d2Capacitor C1Is represented by (d)1+d2) Equivalent capacitance of insulator (realized by polytetrafluoroethylene) under thickness, capacitance C2Indicates the thickness (denoted as d) of the discharge gap 200) The equivalent capacitance of the lower air.
A disk-shaped voltage equalizer 16 is fixed to each of the discharge electrodes 18 at the side of the terminal hole 17, and a partial discharge is prevented from occurring at the connection of the plug connecting wire 14 and the discharge electrode 18 by the voltage equalizer 16. Meanwhile, an umbrella group structure is formed on the outer rings of the first insulator 19 and the second insulator 21, so that pollution flashover generated between the discharge electrodes 18 during testing is effectively avoided.
The specific working process and working principle are as follows:
calculating the initial voltage of the partial discharge test, when calculating the design parameters of the partial discharge test module 15, first, calculating the initial voltage of the partial discharge testAccording to formula C2=(*0*S)/d0Calculating the equivalent capacitance C of the discharge gap 202Wherein:0which represents the dielectric constant of a vacuum,0=8.86*10-12f/m, which represents the relative permittivity of air, =1.00053, S is the area of the discharge gap 20 (the area of the interface between the first insulator 19 and the second insulator 21), d0Indicating the thickness of the discharge gap 20.
Then according to formula C1=(’*0*S’)/(d1+d2) Calculating the equivalent capacitance C of the insulator1Wherein:0which represents the dielectric constant of a vacuum,0=8.86*10-12f/m ' denotes the relative dielectric constant of the insulator material, and since the insulator is made of teflon in this application, ' =2.55, S ' the area of the abutting surface of the first insulator 19 and the second insulator 21, d1Denotes the thickness between the bottom of the recess in the end face of the first insulator 19 and the discharge gap 20, d2The thickness between the bottom of the recess of the end face of the second insulator 21 and the discharge gap 20 is shown.
Finally according to the formula U = (C)1+C2)*U1/C1Calculating to obtain the initial voltage of the partial discharge test, wherein: c1Denotes the equivalent capacitance of the insulator, C2Represents the equivalent capacitance, U, of the discharge gap 201Representing the breakdown voltage of the discharge gap 20, the breakdown voltage is determined in the following way: the breakdown voltage per 1mm of air is 3kV, and the actual value of the breakdown voltage can pass through the thickness d of the discharge gap 200And specifically calculating to obtain.
After the design parameters of the partial discharge test module 15 are completed, the test plug mechanism is inserted into the test connector mechanism 3. When the oscillatory wave partial discharge test is carried out, high-voltage signals are applied according to the sequence from low to high of the voltage specified in the cable oscillatory wave test regulation, and when the applied voltage is greater than the initial voltage of the partial discharge test, the partial discharge test waveform can be observed.
Example 2:
this example differs from example 1 in that: as shown in fig. 6, in the present embodiment, only one test point is provided in the cable 5, and therefore, one test connection mechanism 3 is correspondingly provided, and also the core and the sheath (ground) of the cable at the test point are respectively led out through the wires and connected to the test connection mechanism 3, and the test connection mechanism 3 is fixed on the side of the housing 1 through the connection fixing plate 2.
Example 3:
this example differs from example 1 in that: as shown in fig. 7, in the partial discharge test module 15 of the present embodiment, a discharge tip 22 is disposed in the first insulator 19, one end of the discharge tip 22 is connected to the corresponding discharge electrode 18, and the tip of the discharge tip passes through the first insulator 19 and then enters the discharge gap 20. The test of the point discharge can be realized by the partial discharge test module 15 of the present embodiment.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention. However, any simple modification, equivalent change and modification made to the above embodiments according to the technical substance of the present invention still belong to the protection scope of the technical solution of the present invention.
Claims (8)
1. A partial discharge simulation test system based on oscillatory waves is characterized in that: the cable testing device comprises a shell (1), wherein a cable (5) is wound in the shell (1), cable joints (6) of the cable (5) are led out from two ends of the shell (1), at least one test point is arranged at any position in the cable (5), test joint mechanisms (3) which are in one-to-one correspondence with the test points are fixed on the side part of the shell (1), and an inner core and a protective layer at the test point are respectively led out and then are connected into the test joint mechanisms (3); the testing device is also provided with a testing plug mechanism which is spliced with the testing joint mechanism (3), a partial discharge testing module (15) is arranged in the testing plug mechanism, and an inner core and a protective layer at a testing point are respectively connected into the partial discharge testing module (15) through the testing joint mechanism (3); an oscillation wave signal for testing is output to the cable (5) through the cable joint (6), enters the test plug mechanism through the test joint mechanism (3), and is subjected to partial discharge in the partial discharge test module (15).
2. The oscillatory wave-based partial discharge simulation test system according to claim 1, characterized in that: the lateral part of the shell (1) is connected with a fixing plate (2), the test connector mechanism (3) is fixed on the fixing plate (2), and the test plug mechanism is inserted into the test connector mechanism (3) from the outside of the shell (1).
3. The oscillatory wave-based partial discharge simulation test system according to claim 2, characterized in that: the test joint mechanism (3) comprises two joint sockets (9) fixed on the joint fixing plate (2) from top to bottom, a jack (10) is arranged at the center of one end of each joint socket (9), the other end of each joint socket penetrates through the joint fixing plate (2) and then is fixed with the connecting cover (7), an opening of the connecting cover (7) faces away from the joint fixing plate (2), a test point connecting wire (8) is led out from the opening of the connecting cover, one end of the test point connecting wire (8) is connected with the jack (10) in the corresponding joint socket (9), and the other end of the test point connecting wire is connected with an inner core or a protective layer.
4. The oscillatory wave-based partial discharge simulation test system according to claim 1, characterized in that: the test plug mechanism comprises a plug mechanism base (11), wherein two slots are formed in one end face of the plug mechanism base (11), and a contact pin (12) is fixed at the end of each slot; one ends of the two contact pins (12) are inserted into the test joint mechanism (3), and the other ends of the two contact pins are led out from the back surface of the plug mechanism base (11) and then connected with the partial discharge test module (15).
5. The oscillatory wave-based partial discharge simulation test system according to claim 4, wherein: the plug pins (12) are led out from the back of the plug mechanism base (11) and then fixed through nuts, the plug pins are respectively connected with a plug connecting wire (14) used for being connected with the partial discharge testing module (15), a clamping opening is formed in the middle of the back of the plug mechanism base (11) at the same time, and the partial discharge testing module (15) is fixed in the clamping opening.
6. The oscillatory wave-based partial discharge simulation test system according to claim 4, wherein: the back of the plug mechanism base (11) is covered with a plug mechanism shell (13), a cover opening of the plug mechanism shell (13) is in butt joint with the outer ring of the plug mechanism base (11) and then fixed through a bolt, and the back of the plug mechanism base (11) is covered in the plug mechanism shell (13).
7. The oscillatory wave-based partial discharge simulation test system according to claim 1, 4 or 5, wherein: the partial discharge test module (15) comprises a group of butted insulators: a first insulator (19) and a second insulator (21), wherein the second insulator (21) enters the inside of the first insulator (19) and is connected through threads, and a discharge gap (20) with adjustable distance is formed between the butt joint surfaces of the first insulator (19) and the second insulator (21);
the first insulator (19) and the second insulator (21) are respectively provided with a discharge electrode (18), the end face of the discharge electrode (18) protrudes out of the first insulator (19) and the second insulator (21), and the discharge electrode (18) is respectively connected with the inner core and the protective layer of the cable (5) through the test joint mechanism (3).
8. The oscillatory wave-based partial discharge simulation test system according to claim 7, wherein: each discharge electrode (18) is also respectively fixed with a disk-shaped pressure equalizing piece (16); an umbrella group structure is formed on the outer rings of the first insulator (19) and the second insulator (21).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201922365352.8U CN211528594U (en) | 2019-12-25 | 2019-12-25 | Partial discharge simulation test system based on oscillatory wave |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201922365352.8U CN211528594U (en) | 2019-12-25 | 2019-12-25 | Partial discharge simulation test system based on oscillatory wave |
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| Publication Number | Publication Date |
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| CN211528594U true CN211528594U (en) | 2020-09-18 |
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| Application Number | Title | Priority Date | Filing Date |
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| CN201922365352.8U Active CN211528594U (en) | 2019-12-25 | 2019-12-25 | Partial discharge simulation test system based on oscillatory wave |
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Effective date of registration: 20210802 Address after: No.16, Sanying Road, Zhangdian District, Zibo City, Shandong Province Patentee after: SHANDONG KEHUI POWER AUTOMATION Co.,Ltd. Patentee after: QINGDAO KEHUI ELECTRIC Co.,Ltd. Address before: No.16, Sanying Road, Zhangdian District, Zibo City, Shandong Province Patentee before: SHANDONG KEHUI POWER AUTOMATION Co.,Ltd. |
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| TR01 | Transfer of patent right |