JPS63182580A - Measuring method for partial discharge of cable - Google Patents

Abstract

PURPOSE:To secure electric contacting with a cable to be tested and to hold the sensitivity of partial discharging excellent by charging liquid in an electrode pressure member and applying liquid pressure when a power cable is inserted into the opening part of a semiconductive electrode. CONSTITUTION:The cable to be tested has an extruded insulating layer 14 at the outer periphery of a center conductor 13 and an external semiconductive layer 15 is formed at the outer periphery of the insulating layer 14. The semiconductive electrode 16 which is a cylinder where the cable to be tested is inserted and formed of a semiconductive material with flexibility and lubricity while having curved parts opened radially at both end parts of the opening part is formed at the outer periphery of the cable. The outer peripheral part of the electrode 16 is covered with a flexible conductive electrode 17, an insulating material is arranged annularly at the outer peripheral part of the electrode 16, and the electrode pressing member 18 which expands when liquid is charged therein is formed. Therefore, when the liquid is charged in the member 18 to apply pressure at the time of inserting the cable into the opening part of the electrode 16, the member 18 expands and surface pressure is applied to the electrode 16 through the electrode 17 while the member is placed in a position control state by a pressure jig 19.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a method for measuring partial discharge in cables, and more particularly, to an improvement in the method for measuring pinholes caused by manufacturing defects in high-voltage cables. It is something.

[Prior Art] In general, there are various types of partial discharge detection devices for this type of cable, including devices for detecting partial discharge in a test cable having an extruded inner semiconducting layer and an outer insulating layer. An example of this is a two-layer type cable having only an extruded internal semiconducting layer and an insulating layer, as shown in FIG.

That is, a cable 1 having an extruded internal semiconducting layer and an insulating layer is wound on a drum 2 (the central conductor at the starting end is connected to a ground wire 3 via a slip ring electrode mechanism (not shown). A cable 1 that is grounded and pulled out from the drum 2 is connected to a partial discharge detection device section 20 whose details will be described later.
After passing through, it is wound onto a winding drum 4.

The partial discharge detection device section 20 has an insulating tube 5 made of an insulating material such as a cylindrical acrylic pipe material filled with distilled water 7 in its middle portion, and a conductive material at both ends. Containers 6, 6 formed of the above are arranged in communication with each other via a watertight packing (not shown). The containers 6, 6 are grounded via grounding wires 9, 9, and the distilled water 7 is brought to the ground potential. Further, such distilled water 7 is circulated by a circulation device (not shown).

A cable 1 is provided in the center of the inside of the insulating tube 5.
A measuring electrode 8 shaped to cover the outer periphery of the measuring electrode 8 is disposed, and one end of the measuring electrode 8 is connected to the output of a high voltage source 10 that generates a predetermined test voltage, and the other end is grounded. moreover,
This measuring electrode 8 is connected to a partial discharge detector 12 via a coupling capacitor 11.

Therefore, the output of the high voltage source 10 is applied between the measuring electrode 8 and the ground, and as a result, the output of the high voltage source 10 is applied between the center conductor of the cable 1 and the measuring electrode 8 via the distilled water 7. . At the same time, when the cable 1 wound around the drum 2 is pulled out and wound onto the drum 4 side, the cable 1 runs inward of the measurement electrode 8.

In this state, if there is a defect such as a pinhole in the cable 1, a partial discharge will occur at the defective part, so the pulse at this time will be transmitted to the coupling capacitor 1.
1 to a partial discharge detector 12, and the partial discharge detector 12 detects partial discharge in the cable 1. Therefore, it is determined that there is a defect in a portion corresponding to the position of the measurement electrode 8.

The reason why the distilled water 7 (pure water) is used is that the output voltage of the high voltage source 10 is divided by the impedance (resistance component) of the distilled water 7 in the insulating tube 5, and the partial discharge detector 12 detects the voltage. Distilled water, which has a high electrical resistance, is used in order to facilitate this process and to absorb the Joule heat generated in the distilled water 7.

On the other hand, an example of an apparatus for measuring partial discharge in a three-layer type power cable having an extruded outer semiconductive layer is shown in FIG.

That is, the drum 32 around which the cable 31 is wound is grounded all at once, the output of the high voltage source 10 is supplied to the center conductor of the cable 31, and the partial discharge at that time is transferred to the coupling capacitor 1.
1 and is detected by a partial discharge detector 12. In addition,
10' is the output impedance of the high voltage source 10, and 12' is the input impedance of the partial discharge detector 12.

Therefore, if there is a defect such as a pinhole in the cable 31 wound around the drum 32, a partial discharge will occur at the defective part, and the pulse at this time will be transmitted to the partial discharge detector 12 via the coupling capacitor 11. The partial discharge detector 12 detects that a partial discharge is occurring inside the cable 31, and it can be determined that there is a cable defect in the middle of the cable 31 wound around the drum 32. It has become.

[Problems to be Solved by the Invention] However, in the cable partial discharge detection device shown in FIG. Although this has the advantage of ensuring electrical contact to the cable 1, the resistance value of the distilled water 7 is much higher than that of the external semiconducting layer, which causes heat generation and power consumption due to the impedance of the distilled water 7. becomes very large and becomes impractical.

For this reason, this type of cable partial discharge detection device is limited to application to two-layer type cables that do not have an external semiconducting layer.

On the other hand, in the cable partial discharge detection device shown in Fig. 4, all the capacitances of the cable 31 are connected in parallel to the partial discharge detection circuit system, so the detection sensitivity of partial discharge pulses is reduced. However, there is a problem in that it is difficult to detect weak partial discharges.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a method for measuring partial discharge of a power cable, in which electrical contact to the cable under test can be made reliably, and partial discharge detection sensitivity can be maintained at a good level.

[Means for Solving the Problems] A method for measuring partial discharge in a cable according to the present invention is a method for measuring partial discharge in a power cable having an extruded outer semiconducting layer continuously or intermittently over the entire length of the cable. A semiconducting conductor is formed of a cylindrical body through which a power cable is inserted, has curved parts opening radially at both open ends of the cylindrical body, and is made of a semiconductive material having flexibility and lubricity. a conductive electrode made of a flexible metal conductive material disposed so as to cover the outer periphery of the semiconductive electrode, and a ring-shaped conductive electrode made of an insulating material so as to cover the outer periphery of the conductive electrode. When a power cable is inserted into the opening of the semi-conductive electrode, the electrode press member expands when the inside thereof is filled with fluid. Filled with fluid and applying fluid pressure, the electrode suppression portion (A) expands to bring the semiconductive electrode into close electrical contact with the outer semiconductive layer of the power cable via the conductive electrode. That is.

[Function] Therefore, when the power cable is inserted into the opening of the semiconductive electrode, if the inside of the electrode pressing member is filled with fluid and fluid pressure is applied, the expansion of the electrode pressing member causes the electric power to flow through the conductive electrode. The semi-conductive electrode is brought into close contact with the outer semi-conductive layer of the cable to ensure electrical contact.

[Example] Hereinafter, the method of the present invention will be explained in detail using FIGS. 1 and 2.

FIG. 1 is a longitudinal sectional view of a power cable partial discharge measuring device applied to the measuring method of the present invention in actual use, and FIG. 2 is a horizontal sectional view showing the state before actual use. In the figure, the test cable has an extruded insulating layer 14 formed around the outer periphery of a center conductor 13, and an outer semiconductive layer 15 formed around the outer periphery of this insulating layer 14.

The outer periphery of such a test cable is formed into a cylindrical body through which the cable is inserted, and has curved parts that open radially at both open ends of the cylindrical body, and has a flexible and lubricating half. A semiconductive electrode 16 made of a conductive material is formed. The semiconductive electrode 16 is formed of a stretchable plastic thin film made of a base resin of, for example, fluororesin, and a highly conductive powder or fiber 9 blended with carbon, metal, or the like.

A conductive electrode 17 made of a flexible metal conductive material is formed on the outer periphery of the semiconductive electrode 16 so as to cover it. This conductive electrode 17 is formed of, for example, a metal braided wire. Such a conductive electrode 17
An electrode pressing member 18 is formed on the outer periphery of the electrode pressing member 18, which is annularly disposed with an insulating material so as to cover the electrode pressing member 18 and expands when the inside thereof is filled with fluid (for example, air).

A cylindrical holding jig 19 is disposed on the outer periphery of the electrode pressing member 18 so as to restrict its expansion.

Furthermore, the center conductor 13 of the cable is connected to a high voltage source (not shown) to supply a predetermined output voltage.

Further, although not shown, a partial discharge detector for detecting partial discharge pulses is connected to the conductive electrode 17.

Therefore, when the cable described above is inserted into the opening of the semiconductive electrode 16 and the inside of the electrode pressing member 18 is filled with fluid and pressurized, the electrode pressing member 18 expands.
The semi-conductive electrode 16 is moved through the conductive electrode 17 while its expansion is restricted in its outer peripheral position by the holding jig 19.
Since a surface pressure is applied to the cable, it is brought into close and reliable electrical contact with the outer semiconductive layer 15 of the cable.

When the cable is run in such a state, a partial discharge occurs between the semiconductive electrode 16 and the center conductor 13 at the position where the cable defect occurs, and this state is detected by a partial discharge detector (not shown).

At this time, lubricity is maintained between the cable and the semiconductive electrode 16, and the cable and the semiconductive electrode 16 are brought into close contact with each other with a predetermined pressing force, so that electrical contact is extremely reliable and measurement can be performed with high sensitivity. Here, if the pressure of the fluid (for example, air) in the electrode pressing member 18 is adjusted, the outer semiconductive layer 15 of the power cable and the conductive electrode 17 can be moved. The degree of electrical contact with the measuring electrode, such as the semiconductive electrode 16, can be arbitrarily and easily changed.

Furthermore, since the measuring electrode follows slight fluctuations in the running power cable, the outer semiconducting layer of the power cable is not damaged in any way.

Note that this invention is not limited to the above-mentioned method, but
Various modifications can be made without departing from the spirit of the invention.

For example, by applying a lubricant such as silicone oil or water between the semiconductive electrode 16 and the external semiconductive layer 15 to the extent that electrical contact is not a problem, the lubrication state between the two can be further ensured.

Further, in order to make the work of inserting the cable more efficient, the semiconductive electrode 16 and the like may be constructed in a split mold, such as in two parts.

Furthermore, a plurality of measurement electrode systems can be provided in the length direction of the cable and used as guard electrodes or differential detection electrodes.

Also, in one measurement electrode system, only the conductive electrode or a conductive electrode and a semi-conductive electrode are combined as a set, and multiple sets of these are provided and these are used for the measurement electrode.

It can also be used as a guard electrode, differential detection, etc.

Furthermore, it is also possible to use a combination of the electrode system according to the present invention and a conventional type electrode system.

[Effects of the Invention] As described above, the cable partial discharge measuring method according to the present invention does not involve measuring in distilled water as in the conventional method, and thus eliminates problems such as heat generation.

Furthermore, since all of the capacitance of the cable is not connected to the partial discharge detection circuit system, it is possible to easily detect weak partial discharges.

Furthermore, since electrical contact with the cable is ensured by using a semiconductive electrode having flexibility and lubricity using an electrode pressing member, extremely stable electrical contact can be maintained.

Furthermore, even if the outer diameter or shape of the cable changes for some reason, the semiconducting electrode follows the change and is brought into close contact with the cable to ensure electrical contact.

In summary, the cable partial discharge measuring method according to the present invention ensures reliable electrical contact with the running test cable and maintains good partial discharge detection sensitivity.

[Brief explanation of the drawing]

FIG. 1 is a vertical cross-sectional view of a cable partial discharge measuring device applied to the method of the present invention in actual use, FIG. 2 is a cross-sectional view showing the same state before actual use, and FIG. FIG. 4 is a schematic configuration diagram showing an example of a cable partial discharge detection device applied to a conventional method. FIG. 4 is a schematic configuration diagram of a cable partial discharge detection device applied to another method. 13...Center conductor 14...Insulating layer 15...Outer semiconducting layer 16...Semiconducting electrode 17...Conducting electrode 18 ... Electrode pressing member 19 ... Pressing jig

Claims (1)

[Claims] A method for measuring the partial discharge of a power cable having an extruded outer semiconducting layer continuously or intermittently over the entire length of the cable, comprising: A semiconductive electrode is formed of a semiconductive material having flexibility and lubricity, and has curved parts that open radially at both ends of the opening of the cylinder, and a semiconductive electrode that covers the outer periphery of the semiconductive electrode. A conductive electrode made of a flexible metal conductive material is disposed on the conductive electrode, and an insulating material is disposed in a ring shape to cover the outer periphery of the conductive electrode, and when the inside is filled with fluid. Using an electrode consisting of an inflatable electrode pressing member, when a power cable is inserted into the opening of the semiconductive electrode, the inside of the electrode pressing member is filled with fluid to apply fluid pressure, and the electrode pressing member is expanded. A method for measuring partial discharge in a cable, characterized in that the semiconductive electrode is brought into close electrical contact with the outer semiconductive layer of the power cable via the conductive electrode by expansion.