JPH0153428B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field of the Invention) The present invention relates to a partial discharge measuring method useful for measuring insulation deterioration of power cables and connections of these cables.

(Technical background of the invention and its problems) A method as shown in FIG. 1 is known as a method for measuring partial discharge of power cables and cable connections.

That is, one point of the lead wire 3 connecting one end of the conductor of the test cable 1 and the blocking coil 2 is
It is grounded via a coupling capacitor 4 and a detection element 5 connected in series thereto.

Further, one point of the shielding layer 6 of the cable is also grounded.

In the measuring circuit configured as described above, if the high voltage power supply 7 is connected to one end of the blocking coil 2, the partial discharge signal generated inside the cable under test is detected by the detection element 5.

However, in such a conventional measurement method, since the pulse detection circuit consisting of the coupling capacitor 4 and the detection element 5 is assembled spatially, there is a drawback that external noise due to electrostatic induction or electromagnetic induction easily enters.

For this reason, as shown in FIG. 2, a method has been proposed in which a coupling capacitor cable 8 that utilizes the capacitance of the cable insulator is used instead of the coupling capacitor, and external noise is removed by a paralleler 9. There is.

That is, in the above measurement circuit, each of the shielding layers 11 and 12 of the test cable connection portion 10 and the coupling capacitor cable 8 is connected to the detection elements 13 and 14.
External noise is removed by measuring signals only when the polarities of the partial discharge signals detected by the detection elements 13 and 14 are different.

However, in this partial discharge measurement method,
Since the loop of the measuring circuit is long, there is a drawback that external noise easily enters.

For this reason, a separate measurement method has been proposed to reduce the intrusion of this external noise.

In this separation measurement method, the loop length of the measurement circuit is electrically shortened by cutting out a part of the shielding layer, so it has the advantage of reducing external noise, but has the disadvantages described below.

That is, as shown in FIG. 3, a required length of the metal sheath 15 at an arbitrary location of a coupling capacitor cable such as an OF cable is cut off, a pair of cylindrical bodies 16 and 17 are placed over the cut out part, and a pair of cylindrical bodies 16 and 17 are placed through the insulating tube 18. The pair of flanges 19 and 20 are connected together.

Similarly, the cable shielding layer 21 is also cut out, and a semiconductor layer 23 made of carbon paper or the like having a required resistance value is placed on the outer periphery of the insulator 22 at that part.
It is installed across between 1 and 21.

Note that the resistance value of the semiconductor layer 23 is greater than the resistance values of the detection elements 13 and 14, for example, 100
Although the resistance is assumed to be Ω or more, if an external semiconductive layer (not shown) is formed on the outer periphery of the cable insulator 22, the resistance of this external semiconductive layer may be used instead.

The reason why the required semiconductor layer is provided in the cut-out portion of the cable shield layer is to relieve the stress of the electric field concentrated at the end of the cable by completely separating the cable shield layer.

The so-called separation means for shortening the loop length of the measurement circuit is completed by the above, but in such separation work, it is difficult to cut out the metal sheath.
Another disadvantage is that the insulator may be damaged during the cutting operation of the cable shielding layer.

Another disadvantage is that a coupling capacitor cable must be prepared every time partial discharge is measured.

(Object of the invention) The present invention was made based on the above circumstances, and
The object of the present invention is to provide a partial discharge measuring method that does not damage the cable insulator and allows testing to be performed without having to prepare a coupling capacitor cable for each test.

(Summary of the Invention) In the present invention, each terminal of a coupling capacitor cable and, for example, a test cable is terminated, and only the conductors on one side of the resulting cable are electrically connected to each other. By doing so, the above objective is achieved.

(Embodiment of the Invention) The present invention will now be described in detail based on the drawings of one embodiment.

In FIG. 4, each terminal of a specimen 24 consisting of a connecting portion such as a CV cable such as an OF cable, and a coupling capacitor cable 25 consisting of a cable having the same structure as the above-mentioned cable are each terminated by a conventional method. , Only the conductors between the ends 26 and 27 on one side of the test piece and the coupling capacitor cable thus formed are electrically connected to each other, and if necessary, this connection part is covered with a grounded sealed metal case 28. covered.

The other terminal end 29 of the specimen 24 is covered with a grounded sealed metal case 30 if necessary, and the other terminal end 31 of the coupling capacitor cable 25 is left as it is, that is, it is air terminated, and the cable is attached to the top. An electrode rod 32 electrically connected to the conductor is exposed.

On the other hand, each of the shielding layers 33 and 34 of the specimen and the coupling capacitor cable is connected to the detection element 3.
5, 36, each lead wire 37, 3
A partial discharge detector 4 is connected between the
0 is connected.

Separation section 41 that shortens the loop length of the measurement circuit
is formed as shown in FIG.

That is, the terminals of the coupling capacitor cable and the specimen are each subjected to step stripping treatment, thereby exposing the outer semiconducting layer 42, cable shielding layer 43, and cable insulator 44, and the outer periphery of the exposed insulator is exposed. , an electric field relaxation means 47 consisting of a reinforcing insulating layer 45 and an epoxy bell mouth 46 provided on the outer periphery of the top thereof is provided, and a shield 48 that straddles the cable shielding layer 43 is provided at the tapered portion of this means. ing.

On the other hand, a cylindrical metal fitting 51 having a small diameter flange 50 is fitted onto the end of the metal sheath 49 of the coupling capacitor cable and the specimen, and the end thereof is fixed to the metal sheath 49 by lead work.

Further, the large diameter flange 52 side of the cylindrical metal fitting 54 having a large diameter flange 52 at one end and a small diameter flange 53 at the other end is fixed to the sealed metal case 28 or 30 with bolts 55.

By connecting the small-diameter flanges 50 and 53 with the insulating bolt 57 via the insulating ring 56, the pulse-like cutting operation of the metal sheath 49 is completed.

Note that 58 is an epoxy sleeve that surrounds the cable terminal, and a corona shield 59 is provided at the top of this tube as shown in FIG.

Furthermore, each sealed metal case is sealed or filled with an insulating fluid such as SF ₆ gas or insulating oil.

FIG. 6, in which the same parts as in FIGS. 4 and 5 are given the same numbers, shows a case where a blocking coil 60 is connected to the other end of the coupling capacitor cable, and this connected part is grounded in the same manner as described above. An example in which the device is covered with a metal case 61 is shown.

This embodiment has the advantage that external noise coming from the test voltage application side, that is, the air terminal, can be removed by the blocking coil.

Further, the space between the sealed metal cases may be covered with a grounded cylindrical metal fitting 62, as shown by the dotted line in FIG. 6, for example.

In this case, since the entire measuring circuit is covered with a grounded hermetic body, there is an advantage that the intrusion of external noise can be further reduced.

When the measuring circuit is constructed as described above and a test voltage is applied to the other end of the capacitor cable, the partial discharge signal generated inside the specimen 24 is detected by each of the detection elements 35 and 36.

Therefore, if each of these signals is detected by the partial discharge detector 40 via the parsers 39 that operate when the polarities thereof are different, it is possible to measure a partial discharge signal that does not include external noise.

In addition, although the above-mentioned Example described the case where a cable connection part was used as a test object, this invention is not limited to this and may be applied to a cable, for example.

In addition, in FIGS. 3 and 5, the reference numeral 63 indicates a leadwork section, and in FIG. 2, the reference numeral 64 indicates a partial discharge detector.

(Effects of the Invention) In the present invention described above, each terminal of a coupling capacitor cable and, for example, a test cable is terminated, and only the conductors between the terminal ends on one side of the resulting cable are electrically connected. Since the metal sheath and cable shielding layer of the coupling capacitor cable can be separated from those of the specimen, the closed loop of the measurement circuit can be shortened.

That is, by connecting the small-diameter flanges between the ends of the coupling capacitor cable and the specimen on one side through an insulating tube,
Since the so-called sheath separation operation can be performed, there is no need to cut out the metal sheath at arbitrary locations, which was conventionally difficult, and there is no risk of damaging the insulator.

Furthermore, in the present invention, once a coupling capacitor cable with both ends treated is created, this coupling capacitor cable can be reused for other partial discharge tests, thereby reducing the working time.

[Brief explanation of drawings]

Figure 1 is a circuit diagram for the conventional partial discharge measurement method, Figure 2 is a schematic diagram for the separation measurement method, Figure 3 is a longitudinal sectional view of the main part showing the separation status of the shielding layer, and Figure 4 is a schematic diagram for the separation measurement method.
The figure is a schematic diagram of the partial discharge measuring method of the present invention, FIG. 5 is a longitudinal cross-sectional view of a main part showing the separation state of the shielding layer in the present invention, and FIG. 6 is a schematic diagram showing another embodiment of the present invention. . 24...Specimen, 25...Coupling capacitor cable, 26, 27, 29, 31...Terminal part, 2
8, 30, 61... Sealed metal case, 33, 34
...shielding layer, 35, 36... detection element, 39...
Parancer, 40... Partial discharge detector, 41... Separation section, 47... Electric field relaxation means, 56... Insulating ring, 60... Blocking coil.

Claims (1)

[Claims] 1. A cable for a coupling capacitor in which termination portions are formed at both ends and each shielding layer is grounded via a detection element, and a conductor between one termination portion of a specimen under test is electrically connected. and measuring the partial discharge signal when the polarity of the partial discharge signal detected by each of the detection elements is different when a test voltage is applied to the conductor at the other end of the coupling capacitor cable. Characteristic partial discharge measurement method. 2. Claim 1, characterized in that the connecting portion between one end of the coupling capacitor cable and the specimen and the other end of the specimen are covered with a grounded sealed metal case. partial discharge measurement method. 3. Claim 1 or 2, characterized in that the test voltage is applied via a blocking coil electrically connected to the conductor at the other end of the coupling capacitor cable. partial discharge measurement method. 4. The partial discharge measuring method according to claim 3, wherein the blocking coil and the other terminal end of the coupling capacitor cable connected thereto are covered with a grounded sealed metal case. .