JPH0720192A - Insulating part tester for prefabricated cable connection - Google Patents

Abstract

PURPOSE:To electrically test insulation characteristics of an insulating part by applying a high test voltage to an insulating cylinder and a stress cone of a prefabricated type cable connection and also by applying an electric field distribution similar to an actually used field. CONSTITUTION:An insulating cylinder 7 is held by fixing flanges 10, 11 and a fixing bolt 12, and a stress cone 1 on a lead cable 14 is pushed into a cable insertion hole 7a of the insulating cylinder 7 by a compressing means 15. A spherical electrode 26 is coupled to a conductor of the lead cable 14, and the spherical electrode 26 and an ground side electrode 27 are placed oppositely by another cable insertion hole 7b to have SF6 sealed. The insulating cylinder 7 and a semiconductive part 2 of the stress cone l are electrically insulated by a separating pipe 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulating part testing apparatus for electrically testing an insulating cylinder and a stress cone which constitute a prefabricated cable connecting portion.

[0002]

2. Description of the Related Art In a prefabricated cable connecting portion, an insulating cylinder and a stress cone, which are insulating parts thereof, are manufactured in advance in a factory. Therefore, the insulating cylinder and the like are checked for insulation performance before shipment. That is, for this type of insulating cylinder and stress cone, a test voltage is applied to each single body in a zero atmosphere of sulfur hexafluoride (SF ₆ ) gas, and partial discharge and withstand voltage characteristics are measured.

FIG. 8 is a vertical sectional view showing a conventional stress cone testing device. As shown in the figure, stress cone 1
Is composed of a semiconductive portion 2 and a tapered insulating portion 3. This test apparatus has a rod-shaped body having a high-voltage side electrode 5 at the center and an insulating layer 4 having an outer diameter substantially the same as that of the cable insulator provided on the outside thereof. In this test apparatus, the high-voltage side electrode 5 and the low-voltage side electrode 6 are placed in the SF ₆ gas zero atmosphere.
A constant test voltage is applied between and to test the electrical characteristics of the stress cone 1.

Also in the insulating cylinder, a test voltage is similarly applied between the high-voltage embedded electrode and the low-voltage side electrode in the SF ₆ gas zero atmosphere to perform the electrical characteristic test.

[0005]

By the way, FIG. 9 corresponds to FIG.
FIG. 5 is an explanatory diagram of an electric field distribution applied to the stress cone 1 mounted on the test apparatus of FIG. As shown in the figure, an electric field is applied to the insulating portion 3 of the stress cone 1 as shown by a number of curves,
This electric field distribution tends to have a high electric field applied to a portion close to the low voltage side, and is different from the electric field distribution of the stress cone 1 when the stress cone 1 is actually attached to the cable. Similarly, since the insulating cylinder is not tested in the actual assembled state, the electric field distribution is different.

Therefore, conventionally, it was not possible to accurately test the electrical characteristics of the stress cone and the insulating cylinder during actual use. Further, in the conventional test apparatus, when a high voltage is applied, a partial discharge is generated from the apparatus itself, so that it is not possible to measure the partial discharge of the insulating component with high accuracy. Further, since the stress cone and the insulating cylinder are individually tested, there is a drawback that the test work requires a lot of labor and time.

The present invention has been made in order to solve such a point, and an electric field close to the electric field distribution in an actual use condition can be simultaneously applied to the insulating cylinder and the stress cone, and a high voltage is applied. It is an object of the present invention to provide an insulating part testing device for a prefabricated cable connection part that can perform an electrical test with good workability.

[0008]

According to a first aspect of the present invention, there is provided an insulating component testing apparatus comprising a frame-shaped fixing means for detachably fixing an insulating cylinder forming a prefabricated cable connecting portion, and a stress cone forming the connecting portion. A lead cable to which a terminal attached with is inserted into one end side of an insulating cylinder and a test voltage is applied, compression means for pressing this stress cone into one end of the insulating cylinder, a semiconducting portion of the stress cone and an insulating cylinder. An edge portion electrically insulating between the conductor and a spherical electrode fixed to the conductor of the lead cable terminal and arranged in the other end of the insulating cylinder, and arranged opposite the spherical electrode in the other end of the insulating cylinder. It is characterized by including a ground side electrode.

A second aspect of the present invention is an insulating component testing apparatus which comprises the frame-shaped fixing means and the lead cable described above, an insulating rod fitted with another stress cone and inserted into the other end of the insulating cylinder, and both stress cones. Is provided with compression means for respectively pressing the insulating cylinder into both ends of the insulating cylinder, and an edge portion electrically insulating between the semiconductive portion of at least one stress cone and the insulating cylinder.

[0010]

The insulating cylinder and the stress cone are assembled by the frame-shaped fixing means, and the test voltage is applied by the lead cable to apply an electric field similar to the actual use condition to these insulating parts. Since the semiconducting portion of the stress cone and the insulating cylinder are electrically insulated by the edge cut portion, the stress cone and the insulating cylinder can be electrically tested individually and simultaneously. A high test voltage can be applied to the device when the electric field concentration is alleviated by the spherical electrode, or when an electric field distribution similar to that in the actual use state is obtained by using the insulating rod.

[0011]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a sectional view of an insulating component testing apparatus according to the first invention. In FIG. 1, 7 is an insulating cylinder made of epoxy resin, in which tapered cable insertion holes 7a and 7b are provided in communication. A high voltage embedded electrode 8 is embedded in the center of the insulating cylinder 7. Further, 1 is a stress cone made of PE rubber, and has an insulating portion 3 and a semiconductive portion 2. The insulating cylinder 7 and the stress cone 1 form an insulating component of the prefabricated cable connecting portion.

The insulating part testing apparatus of the present invention has disk-shaped fixing flanges 10 and 11. The fixed flanges 10 and 11 are fitted with the flange portions in a state of being in surface contact with both end surfaces of the insulating cylinder 7, and the opposite ends of the fixing bolts 12 are penetrated through the opposed flange portions of the fixed flanges 10 and 11. . Then, the nut 13 is screwed onto both ends of the fixing bolt 12 and tightened to hold and fix the insulating cylinder 7.

The end of the lead cable 14 is inserted into the cable insertion hole 7a of the insulating cylinder 7. The above-mentioned stress cone 1 is mounted on the end of the lead cable 14, and the semiconductive portion 2 of the stress cone 1 and the exposed semiconductive layer 14a of the lead cable 14 are in surface contact with each other and electrically connected. ing.

A compression means 15 is provided on the fixed flange 10. The compression means 15 includes a plurality of shafts 16 concentrically fixed to the plate surface of the fixed flange 10 and a pressing plate 1 penetrating the shafts 16 so as to be movable.
7 and a washer 18 penetrating the tip of the shaft 16
And a plurality of other shafts 19 whose both ends are inserted into the washer 18 and the pressing plate 17, respectively.
A coil spring 20 is mounted on the device 19. The compression means 15 having the above configuration is the coil spring 20.
Is applied to the edge cutting pipe 21 via the pressing plate 17 to press the stress cone 1 against the inner peripheral wall of the cable insertion hole 7a. The cable insertion hole 7a is provided with a stopper 22 made of an insulating material with which the tip of the stress cone 1 abuts. The edge cutting pipe 21 is made of FRP and electrically insulates the semiconductive portion 2 of the stress cone 1 from the insulating cylinder 7.

A connecting pipe 23 is compressed and fixed to the conductor 14b at the tip of the lead cable 14. The connecting pipe 23 is fixed to the center of the high-voltage embedded electrode 8 with a fixing member 24 via a bolt 25.

A column portion 26a of the spherical electrode 26 is screwed into and fixed to the tip of the connecting pipe 23. The spherical electrode 26 is located in the cable insertion hole 7b of the insulating cylinder 7, and the earth side electrode 27 faces it. The ground-side electrode 27 is formed in a substantially cylindrical shape and is fixed to the center of the blind plate 28. Blind plate 28
Is fixed to the fixed flange 11 via an O-ring 29 with bolts while maintaining airtightness. In addition, fixed flange 1
1 is also fixed to the end surface of the insulating cylinder 7 via the O-ring 29 as described above. SF ₆ gas 30 is sealed in the cable insertion hole 7b through the connector 28a of the blind plate 28.

FIG. 2 is a schematic diagram of a known partial discharge measuring circuit. This measuring circuit includes a detection resistor 31a for detecting partial discharge of the insulating cylinder 7, an insulating cylinder determination unit 32 for determining the detection signal, a detection resistor 31b for detecting partial discharge of the stress cone 1, and its A stress cone determination unit 33 for determining a detection signal, an oscilloscope 34 connected to the output side of both determination units 32, 33, and a precursor cutoff circuit 3
5 and a recorder 36, the precursor shutoff circuit 35 disconnects a power source 37 for applying a test voltage to the lead cable 14 from the lead cable 14 as described later.

By the way, in the insulation part testing apparatus of the present invention shown in FIG. 1, the radius of the spherical electrode 26 and the earth side electrode 2
The outer diameter, shape, position of No. 7, the gas pressure of the SF ₆ gas 30, etc. were used as parameters, and electric field analysis was performed a plurality of times when 610 kV was applied, the optimum conditions were estimated, and the structure of the device was determined.

3 and 4 show the electric field distribution of the device under the optimum conditions. The electric field strength on the spherical electrode 26 side of the high-voltage embedded electrode 8 is 2% at the R portion as compared with that on the stress cone 1 insertion side,
Although the electric field was 9% higher at the r part, the position of the maximum electric field strength was the same as that of the prefabricated cable connection part actually assembled, and the magnitude of the electric field could be suppressed within 2%.

Now, in order to perform the partial discharge measurement by the insulation component testing apparatus of the present invention having the above-mentioned structure, a test voltage is applied to the lead cable 14 from the power source 37. In this example, a high test voltage of 610 kV was applied to the lead cable 14. When this voltage is applied, the spherical electrode 26
Since the lines of electric force are distributed along the spherical peripheral surface at a relatively low density, the electric field concentration is alleviated even when high voltage is applied,
It is possible to prevent the generation of corona between the ground-side electrode 27.

On the other hand, when the stress cone 1 is inserted into the insulating cylinder 7 and the test voltage is applied by the lead cable 14, the test voltage is the same as that of the actual prefabricated type cable connection part assembled by using these insulating parts. Therefore, the same electric field distribution as that in actual use can be obtained, and therefore the partial discharge can be accurately measured. Also,
Since the insulating cylinder 7 and the semiconducting portion 2 of the stress cone 1 are electrically insulated by the edge cutting pipe 21, the insulating cylinder 7 and the stress cone 1 are individually tested as described later, and the individual electric characteristics are examined. It is possible to discriminate the quality.

When a partial discharge occurs in the insulating cylinder 7 when a high test voltage of 610 kV is applied as described above, this partial discharge is detected by the insulating cylinder determining unit 32 via the detection resistor 31a as shown in FIG. That level is detected. That is, in this embodiment, the partial discharge can be measured at the detection level of the generated discharge charge amount of 3 to 7 pC even when the test voltage is 610 kV. Then, the insulation tube determination unit 32 displays the measurement result on the oscilloscope 34 and records it on the recorder 36. On the other hand, when the insulation cylinder 7 has a defect and the detected discharge charge amount is 30 pC or more, the insulation cylinder determination unit 32 activates the pre-cutoff circuit 35 to connect the power supply 37 to the lead cable 1.
Separate from 4. Thereby, damage to the lead cable 14 can be prevented.

When the stress cone 1 has a defect, the stress cone determination unit 33 measures the partial discharge through the semi-conductive portion 2, the semi-conductive layer 14a of the lead cable 14 and the detection resistor 31b, and the oscilloscope is also used. The display 34 and the recorder 36 are caused to display and record, and when the discharge charge amount is 30 pC or more, the pre-cutoff circuit 35 is operated to disconnect the power supply 37 from the lead cable 14.

As shown in FIG. 5, the spherical electrode 26 may be formed by denting a part of the peripheral surface of a metal sphere, and the point is that the surface facing the low potential side should be substantially spherical. . Further, the ground-side electrode 27 may have a smooth surface such as a curved surface facing the spherical electrode 26. In the above embodiment,
The cable insertion hole 7b of the insulating cylinder 7 may be filled with insulating oil instead of SF ₆ gas.

FIG. 6 is a sectional view of an insulating component testing apparatus according to another invention. 6, the same parts as those of the device of FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. Now, in the illustrated apparatus, the insulating rod 3 is used instead of the spherical electrode 26 (see FIG. 1).
8 is inserted into the cable insertion hole 7b of the insulating cylinder 7.
The insulating rod 38 is made of epoxy resin, and the connecting portion 38 a at the tip thereof is connected to the connecting pipe 23 via a connecting fitting 39.

Another stress cone 1A is mounted on the insulating rod 38.
The stress cone 1A is attached to the edge cutting pipe 40
It is pressed against the inner peripheral wall of the cable insertion hole 7b by the compression means 15 via. And stress cone 1A
Similarly to the other stress cones 1, the semiconductive portion 2A is also connected to the partial discharge measuring circuit shown in FIG. 2 via the semiconductive portion 38b at the end of the insulating rod 38.

The testing device having the above-mentioned structure is an insulating rod 38.
It is possible to make the electric field distribution on the side of the cable insertion hole 7b the same as the actual electric field distribution of the prefabricated cable connecting portion by appropriately selecting the dimensions and the material. Therefore,
Since a high voltage test voltage is applied and the partial discharge measurement can be performed with the same electric field distribution as in actual use, the measurement test can be performed with high accuracy. Further, it is also possible to simultaneously detect and evaluate the insulating characteristics of the insulating cylinder 7 and the pair of stress cones 1 and 1A in one test.

FIG. 7 is a sectional view showing a modified example of the insulating component testing apparatus according to the invention of FIG. In this modification, the insulating rod 3
The low-dielectric-constant insulating layer 41 is provided on the peripheral surface in contact with the stress cone 1A of FIG. The low dielectric constant insulating layer 41 is formed of polyethylene or the like having substantially the same dielectric constant as the insulating layer of the cable. Therefore, when a test voltage is applied to the lead cable 14, an electric field distribution that is closer to the actual usage state is obtained, so that a measurement test can be performed with high voltage and high accuracy.

In the embodiment shown in FIGS. 6 and 7, the connecting pipe 23 and the insulating rod 38 may be connected by a slip-on method or a screwing method to simplify the connecting and separating operations. Further, the present invention can be applied to an electrical test of an insulating component of a prefabricated oil stop connection portion of an OF cable line.

[0030]

As described above, according to the present invention,
High-voltage test voltage can be applied to the insulation cylinder and stress cone of the prefabricated cable connection, and an electric field distribution that is almost the same as the actual usage condition can be obtained, so the insulation characteristics of these insulation parts can be tested with high accuracy. In addition, it is possible to measure the insulation characteristics of these insulation parts individually in a single test, and the workability of the prefabricated cable connection part is excellent because of the structure that can be easily assembled and disassembled. A test device can be provided.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an insulating component testing device according to the present invention.

FIG. 2 is a block diagram of a partial discharge measurement circuit.

FIG. 3 is an explanatory diagram of an electric field distribution in the device of the present invention.

FIG. 4 is an explanatory view showing an electric field distribution in the vicinity of the high-voltage embedded electrode in the device of the present invention and an actual prefabricated cable connection portion.

FIG. 5 is a view showing a modified example of the spherical electrode according to the present invention.

FIG. 6 is a cross-sectional view of an insulating component testing device according to another invention.

7 is a cross-sectional view of a main part according to a modified example of the device in FIG.

FIG. 8 is a cross-sectional view of a conventional stress cone testing device.

FIG. 9 is an explanatory diagram of an electric field distribution in a conventional device.

[Explanation of symbols]

1,1A Stress cone 2,2A Semi-conductive part 7 Insulation cylinder 10,11 Fixed flange 12 Fixing bolt 14 Lead cable 15 Compression means 21,40 Edge cut pipe 26 Spherical electrode 27 Earth side electrode 30 SF ₆ Gas 38 Insulation rod 41 Low Dielectric constant insulating layer

Claims (3)

[Claims] 1. A device for electrically testing an insulating cylinder and a stress cone constituting a prefabricated cable connecting part, which comprises frame-shaped fixing means for detachably fixing the insulating cylinder, and a terminal to which the stress cone is mounted. Is inserted into one end side of the insulating cylinder and a test voltage is applied, compression means for pressing the stress cone into one end of the insulating cylinder, and a semiconducting portion of the pressed stress cone. An edge cutout electrically insulating between the insulating cylinder, a spherical electrode fixed to the conductor of the lead cable terminal and arranged in the other end of the insulating cylinder, and in the other end of the insulating cylinder. An insulating component testing device for a prefabricated cable connecting part, comprising: the spherical electrode and an earth side electrode arranged to face each other. 2. An apparatus for electrically testing an insulating cylinder and a stress cone constituting a prefabricated cable connecting portion, which comprises frame-shaped fixing means for detachably fixing the insulating cylinder, and a terminal to which the stress cone is mounted. Is inserted into one end of the insulating cylinder and a test voltage is applied, a lead rod to which another stress cone is attached and inserted into the other end of the insulating cylinder, and both stress cones are A prefabricated cable comprising: a compressing unit that presses into both ends of the insulating cylinder; and an edge portion that electrically insulates between the semiconductive portion of at least one of the stress cones and the insulating cylinder. Insulation component testing device for connection parts. 3. The insulation of the prefabricated cable connecting portion according to claim 2, wherein an insulating layer having a dielectric constant close to that of the insulator of the cable is provided on the outer periphery of the insulating rod. Parts testing equipment.