JPH09211062A - Partial discharge measurement method - Google Patents

Abstract

(57) Abstract: An auxiliary electrode is provided on a corrosion-resistant sheath, or an external semiconductive layer is cut off to form a detection electrode, so that the detection sensitivity increases as the position of partial discharge increases from the connecting portion. Becomes worse. Two cylindrical detection electrodes 1 are formed by removing a metal shielding layer 104 in a connection portion in a circumferential direction with a predetermined width.
04a and 104b are formed. Lead wires 111a and 111b communicating to the outside are connected to the two detection electrodes to detect a partial discharge pulse.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a partial discharge measuring method for measuring a partial discharge of a power cable line,
The present invention relates to a method for measuring a partial discharge which is optimal for achieving low noise and high sensitivity.

[0002]

2. Description of the Related Art FIG. 3 shows a conventional partial discharge measuring method.
This measuring method is shown in FIGS. 1 and 2 of Japanese Patent Publication No. 6-7146. In FIG. 3, the conductor 2 is at the center.
01 is arranged, and the cable insulating layer 202 is formed around it. An outer semiconductive layer 203 is coated so as to cover the surface of the cable insulating layer 202. A metal sheath 204 and a vinyl sheath 205 are sequentially coated on the outer semiconductive layer 203. These covering members are collectively separated at one place, and the sheath part is electrically insulated from this part to the left and right.

A metal sheath 204 on one side (here, on the left side)
An auxiliary electrode 206 made of metal foil is attached on top. Jumper wires 207a and 207b are connected to the auxiliary electrode 206 and the metal sheath 204 on the other side (here, the right side), and the detection impedance 208 is connected to these jumper wires.
Is connected, and the partial discharge measuring unit 209 is connected to the detection impedance 208.

The metal sheath 204 to which the auxiliary electrode 206 and the jumper wire 207b are connected forms a detection electrode. When a high voltage is applied to a cable having a partial defect such as a void, a partial discharge (corona) occurs at the defective part. When this partial discharge occurs in the cable, it produces a discharge pulse. This discharge pulse is detected by the auxiliary electrode 206 and the other metal sheath 204, and a detection impedance 208 is detected.
It is taken into the partial discharge measuring unit 209 via the and the deterioration of the insulator is grasped.

FIG. 4 shows another conventional partial discharge measuring method. In FIG. 4, the same reference numerals are used for the same elements as those in FIG. 3, and duplicate explanations are omitted. The vinyl sheath 205 is not shown in FIG. The metal sheath 204a on one side is cut out in an annular shape to form an edge cut portion 210, and a part of the metal sheath is formed into a ring shape, and this portion is used as the detection electrode 211.

The metal sheath 104b and the detection electrode 2 on the opposite side
11, the detection impedance 208b and the coupling capacitor 212 are connected, and the detection impedance 208a and the gapless arrester 213 are connected between the metal sheath 204a and the detection electrode 211. The detection impedance 208b is connected to the partial discharge measuring unit 209b, and the detection impedance 208a is connected to the partial discharge measuring unit 209a. Since the measuring method is the same as that described with reference to FIG. 3, a description thereof will be omitted. In any case, partial discharge from the cable insulating layer 202 can be measured in addition to partial discharge at the connection portion.

FIG. 5 shows a first example of the partial discharge measuring method proposed by the present applicant. The insulating connection part shown here is a conductor 301 arranged at the center, a connection sleeve 302 for connecting the conductor 301, an insulator 303 (for the line side) that insulates the conductor 301, and a reinforcing insulation part 304 (connection). Section side), the outer semiconductive layer 305 (connecting section side) and 325 (wire side) that cover the insulator 303 and the reinforcing insulating section 304, the metal shielding layer 306 that covers the outer semiconductive layer 305, and the line side metal. Sheath 326, edge semi-conductive layer 305 and metal shield layer 306 at the connection portion, which are cut off in the circumferential direction to form an electrical cutoff portion in the axial direction, external semi-conductive layer 305 and metal shield at the connection portion. A waterproof compound 308 for sealing the layer 306 from the surface, a metal shielding layer 306, and a copper body tube 3 for covering the waterproof compound 308.
09, anticorrosion vinyl layer 31 covering the copper barrel 309
0, copper barrel 309 and anticorrosion vinyl layer 31 on both sides of the connection
An insulating cylinder 311 for separating 0 is provided.

Corrosion-proof vinyl layers 31 on both sides of the insulating cylinder 311
The metal foil electrodes 312a and 312b are adhered to the surface of 0, and the copper barrel 309 is attached to the metal fittings 313a and 313b.
Is attached. And the mounting brackets 313a, 3
A jumper wire 314 is connected to 13b, and a plurality of high-frequency iron cores 315 for increasing impedance are attached to the jumper wire 314. Furthermore, the metal foil electrode 312
A detection impedance 316 is connected between a and 312b, and a partial discharge measuring instrument 317 is connected to the output end of the detection impedance 316.

In the configuration of FIG. 5, when measuring partial discharge, a high frequency iron core 315 is attached to the jumper wire 314 of the normal connection portion, and the copper barrels 309 on both sides of the insulating cylinder 311 are converted into high frequency signals by the high frequency iron core 315. It will be insulated against it. When a partial discharge occurs in this state, a partial discharge pulse is induced between the copper body tubes 309 on both sides of the insulating cylinder 311, and the partial discharge pulse is detected from the metal foil electrodes 312a and 312b. When the partial discharge pulse is detected by the pair of metal foil electrodes 312a and 312b, a potential difference is generated at both ends of the detection impedance 316, and the partial discharge measuring instrument 317 outputs the partial discharge signal based on the potential difference to the most S / N.
The partial discharge is measured by tuning and amplifying at a high frequency of.

FIG. 6 shows a second example of the partial discharge measuring method proposed by the present applicant. In FIG. 6, the same reference numerals are used for the same elements as those in FIG. 5, and thus duplicated description will be omitted below. This structure is different from the structure shown in FIG. 5 in the processing of the outer semiconductive layer 305 and the metal shielding layer 306. That is, in FIG. 5, the main edge cutout 307 is provided, whereas in FIG. 6, only the metal shielding layer 306 is partially cut off to provide the edge cutout 306a. Other configurations and operations are the same as those in FIG.

The structures shown in FIGS. 5 and 6 are examples of externally attached sensors, and partial discharge can be detected from the connection portion that normally acts as a connection portion when the high-frequency iron core is not mounted.
The measurement of the partial discharge is the same as that in FIG. 3, and thus the description thereof is omitted here. According to the configurations of FIGS. 5 and 6,
It is possible to measure with a detection sensitivity almost equal to the detection sensitivity of the partial discharge from the insulation connection part.

FIG. 7 shows a third example of the partial discharge measuring method proposed by the present applicant. This configuration is an example of a sensor built-in system in which a sensor is provided inside the connection portion, and the overall configuration of the power cable is the same as that in FIG. In this configuration, the metal shielding layer 306 is cut off at two places to cut the edge cut portions 318a and 318.
b is formed, and the separated metal shielding layer 306 is used as a detection electrode, and lead lines 319a and 319b introduced from the outside are connected to the detection electrode. In order to support the lead wires 319a and 319b, the copper barrel 3
09 and the anticorrosion vinyl layer 310 are penetrated, and lead wire lead-out portions 327a and 327b are provided. Further, in order to perform the partial discharge measurement, a transformer 320 as a detection impedance and an arrester 321 are provided on the lead wire 319a.
And the partial discharge measuring unit 317 is connected. The arrester 321 is used to protect the measuring instrument or the like from a surge voltage, and grounding is performed via the lead wire 319c to the copper body tube 30.
9 is connected.

In the configuration of FIG. 7, when a partial discharge occurs, a partial discharge pulse is induced in the metal shield layer 306.
For this reason, a potential difference is generated at both ends of the transformer 320 in which one of the primary windings is connected to the copper body tube 309, and the partial discharge measuring instrument 317 outputs the partial discharge signal based on the potential difference to the most S / N.
It is measured by tuning and amplifying at a high ratio frequency. FIG. 8 shows a fourth example of the partial discharge measuring method proposed by the present applicant. This configuration is also an example of a sensor built-in system in which a sensor is provided inside the connection portion. The overall configuration is the same as in FIG. 7. In this configuration, the metal shielding layer is cut off to cut the edge cut portions 318a to 318.
7A and 7B show that the detection electrodes 322a and 322b are connected to the detection electrodes 322c and the lead lines 328a and 328b are connected to the detection electrodes 322a and 322b.
The configuration is different. Since there are two lead lines, the detection impedance 323 by the transformer with the intermediate tap is used accordingly, and two arresters (gapless arresters 321a and 321b) are provided.

In the structure shown in FIG. 8, when partial discharge is generated at the normal connection portion, the partial discharge pulse is generated by the edge cutting portion 318c.
Is induced by the detection electrodes 322a and 322b on both sides of, and a potential corresponding to the partial discharge pulse is generated at the detection electrodes 322a and 322b. Therefore, the detection impedance 323
A potential difference corresponding to the potential difference between the detection electrodes 322a and 322b is generated at both ends of the partial discharge measuring instrument 317, and the partial discharge measuring instrument 317 tunes and amplifies the partial discharge signal based on the potential difference at a frequency with the highest S / N ratio to generate partial discharge. Measure.

[0015]

However, according to the conventional partial discharge measuring method, in the configuration of FIGS. 3 and 4,
The partial discharge of the cable portion causes the signal to be attenuated as the distance from the detection connection portion increases, so that there is a problem that the detection sensitivity gradually deteriorates. Further, the partial discharge measuring method having the configuration of FIGS. 5 and 6 has the same problems as the partial discharge measuring method of FIGS. 3 and 4, and it is difficult to increase the detection sensitivity. Further, in the configurations of FIGS. 7 and 8, there is a problem that it is difficult to detect the influence of external noise, but it is difficult to detect the partial discharge generated in the cable portion.

Therefore, an object of the present invention is to provide a partial discharge measuring method capable of detecting a partial discharge from a connecting portion with high sensitivity and also detecting a partial discharge from a cable portion.

[0017]

In order to achieve the above-mentioned object, the present invention cross-bonds an insulating connecting portion in which a main edge portion is provided in an outer semiconductive layer and a metal shielding layer at a substantially central position inside. In the power cable line connected by the method, the metal shielding layer is removed with a predetermined width on both sides of the main edge cut portion to form two detection electrodes, and a partial discharge pulse is detected between the two detection electrodes. The feature is to do.

According to this method, a part of the metal shielding layer in the connecting portion is removed and separated in the circumferential direction, so that
If two cylindrical detection electrodes are formed and a lead wire is externally connected to each of the two detection electrodes, a partial discharge pulse at the connection portion can be detected. Also,
A large resistance is formed at the edge cut portion of the detection electrode and functions to prevent noise from entering from the line side. Therefore, it is possible to detect the partial discharge from the reinforced insulating portion, which is likely to cause defects, with high sensitivity.

Further, the above-mentioned object is to provide a power cable line in which an insulating connection portion, in which a main edge cutting portion is provided on an outer semiconductive layer and a metal shielding layer, is connected in a cross-bonding manner at a substantially central position inside, and the metal shielding is provided. The layer is removed with a predetermined width on both sides of the main edge cut portion to form two detection electrodes, and two metal foil electrodes are attached to the surface of the corrosion-resistant insulating sheath on both sides of the insulating cylinder of the insulating connection portion. It is also achieved by a method of detecting a partial discharge pulse from between the two detection electrodes, between the two metal foil electrodes, or both.

According to this method, a part of the metal shielding layer in the connection portion is removed and separated in the circumferential direction, so that 2
If two cylindrical detection electrodes are formed and a lead wire is externally connected to each of the two detection electrodes, a partial discharge pulse at the connection portion can be detected. Also,
A large resistance is formed at the edge cut portion of the detection electrode and functions to prevent noise from entering from the line side. Furthermore,
The partial discharge generated in the cable portion (line side) can be detected by connecting a lead wire from the outside between the two metal foil electrodes to detect a partial discharge pulse in the cable portion. Therefore, it is possible to detect both the partial discharge pulse from the reinforced insulating portion and the partial discharge pulse in the cable portion where defects are likely to occur.

When the separated barrels are connected by jumper wires and a high-frequency iron core is attached to the jumper wires, the high-frequency impedance of the jumper wires can be set to a predetermined value and the impedance can be lowered for commercial frequencies. The function as the connecting portion is not impaired. In this case, when the jumper wire has a predetermined high frequency impedance, it is not necessary to mount the high frequency core.

[0022]

1 shows a partial discharge measuring method according to the present invention. FIG. 2 is an equivalent circuit of the partial discharge measurement system of FIG. In FIG. 1, a conductor 101 arranged at the center and a conductor connecting portion 10 for connecting the conductors 101 to each other.
2, an outer semiconductive layer 103 provided coaxially to the conductor connecting portion 102, a metal shielding layer 104 covering the outer semiconductive layer 103, a main edge cutting portion formed on the outer semiconductive layer 103 and the metal shielding layer 104. 105, metal shield edging portions 106a, 106b at the cable end portions, which cut out only the metal shield layer 104 on both sides of the connection portion on the ring to form electrical shield portions to form the detection electrodes 104a, 104b. A copper barrel 107 that is in close contact with the metal shielding layer 104 and has a large diameter portion at the connection portion, a vinyl sheath 108 that covers the copper barrel 107, and the copper barrel 107 and the vinyl sheath 108.
A sheath insulating cylinder 109 that separates the conductor 101, insulators 116a and 116b provided between the conductor 101 and the outer semiconductive layer 103, and between the metal shielding layer 104 and the detection electrodes 104a and 104b and the copper body tube 107. Has become.

At this connection, a metal foil electrode 110 is formed on the surface of the vinyl sheath 109 on both sides of the insulating cylinder 109.
a and 110b are attached. Furthermore, the detection electrode 10
Lead wires 111a and 111b are connected to the wires 4a and 104b, and lead wire lead-out portions 112 are provided on both sides of the insulating cylinder 109.
a and 112b are attached, and the lead wire 11 is
1a and 111b are inserted. Further, sheath terminals 113a and 113b are attached to both ends of the connecting portion, and a jumper wire 114 is connected between the sheath terminals 113a and 113b. The jumper wire 114 has a plurality of high-frequency iron cores 1.
15a, 115b, 115c, 115d are attached.

In the measurement system, as shown in FIG. 5, a detection impedance (not shown) is connected between the metal foil electrodes 110a and 110b, and a partial discharge measuring section is connected to this detection impedance. Further, another detection impedance (not shown) is also connected to the lead wires 111a and 111b connected to the detection electrodes 104a and 104b, and another partial discharge measurement unit is connected to this detection impedance.

Next, the equivalent circuit of FIG. 2 will be described.
Capacitances C ₁ and C ₂ are formed between the conductor 101 and the detection electrodes 104a and 104b (= lead wires 111a and 111b), and a capacitance C ₁ ′ is formed between the conductor 101 and the metal shielding layer 104. , C ₂ 'is formed. A resistor r ₁ is formed between the metal shield layer 104 on the right side of FIG. 1 and the detection electrode 104a, that is, a portion of the metal shield edging portion 106a, and between the metal shield layer 104 on the left side of FIG. 1 and the detection electrode 104b. That is, the resistance r ₂ is formed in the portion of the metal shield edging portion 106b. Further, a capacitance C ₄ is formed between the detection electrode 104a and the metal foil electrode 110a, and
A capacitance C ₃ is formed between the detection electrode 104b and the metal foil electrode 110b.

In the circuit of FIG. 2, the resistors r ₁ and r ₂ have a sufficient electrostatic shielding effect for commercial frequencies, and the shielding effect seen from the reinforcing insulating layer is sufficient. On the other hand, in the high frequency band for the partial discharge pulse or the partial discharge measurement, the operation is performed so that the edge cutting effect is sufficiently exhibited. Here, for example, when partial discharge occurs from the side of the capacitance C ₁ , the capacitance C _{2 functions} as a coupling capacitor, and the capacitances C ₃ and C ₄ (between the terminals A and B) are located at 9 positions. This makes it possible to detect partial discharge. In this case, the resistances r ₁ and r ₂ exhibit sufficiently high impedance values, so that the capacitance of one half of the connection portion acts as the capacitance of the test material. The smaller the capacitance, the more sensitive the partial discharge can be detected. Also, the resistances r ₁ and r ₂
Noise is also prevented from entering from the cable portion (capacitances C ₁ ′, C ₂ ′) via the, so that the S / N ratio becomes high and the partial discharge from the reinforcing insulating layer, which is apt to cause defects, is increased. Can be detected with sensitivity. If partial discharge occurs from the cable (capacitance C ₁ ′, C ₂ ′), the capacitance C
_3, C ₄ through the foil electrode metal foil electrodes 110a, 110
Partial discharge can be detected between b.

As described above, the partial discharge from the connecting portion can be performed with high sensitivity, and the partial discharge from the cable portions on both sides can be detected as in the conventional method.

[0028]

As is apparent from the above, according to the present invention, the metal shielding layer in the connecting portion is removed in the circumferential direction.
Since two cylindrical detection electrodes are formed and the partial discharge pulse is detected between the two detection electrodes, it is possible to detect the partial discharge from the reinforced insulating portion where defects are likely to occur with high sensitivity. .

Further, since the metal foil electrodes are attached to the surfaces of the insulating sheaths on both sides of the insulating cylinder and the partial discharge pulse is detected from between the two detection electrodes and between the two metal foil electrodes, a defect occurs. It is possible to detect both the partial discharge pulse from the reinforced insulating portion and the partial discharge pulse in the cable portion that are apt to occur.

[Brief description of drawings]

FIG. 1 is a connection diagram and a cable cross-sectional view showing a partial discharge measuring method according to the present invention.

FIG. 2 is an equivalent circuit of the partial discharge measurement system of FIG.

FIG. 3 is a connection diagram and a cable cross-sectional view showing a conventional measuring method.

FIG. 4 is a connection diagram and a cable cross-sectional view showing another conventional partial discharge measuring method.

FIG. 5 is a connection diagram and a cable cross-sectional view showing a first example of a partial discharge measurement method that the applicant of the present invention has proposed.

FIG. 6 is a connection diagram and a cable cross-sectional view showing a second example of the partial discharge measuring method that the applicant of the present invention has proposed.

FIG. 7 is a connection diagram and a cable cross-sectional view showing a third example of the partial discharge measurement method that the applicant of the present invention has proposed.

FIG. 8 is a connection diagram and a cable cross-sectional view showing a fourth example of the partial discharge measuring method that the applicant of the present invention has proposed.

[Explanation of symbols]

 Reference Signs List 101 conductor 102 conductor connection portion 103 outer semiconductive layer 104 metal shielding layer 105 main edge cutting portions 106a, 106b metal shield edge cutting portion 107 copper barrel 108 vinyl sheath 109 insulating cylinders 110a, 110b metal foil electrodes 111a, 111b built-in sensor lead wire 112a , 112b Lead wire lead-out portions 113a, 113b Sheath terminal 114 Jumper wires 115a, 115b, 115c, 115d High frequency iron core

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akira Endo 5-1-1, Hidaka-cho, Hitachi-shi, Ibaraki Power Systems Laboratory, Hitachi Cable, Ltd. (72) Inventor Tsutomu Tashiro 5 Hidaka-cho, Hitachi-shi, Ibaraki 1-1-1, Hitachi Cable Co., Ltd. Power Systems Research Laboratory (72) Inventor Hiroshi Suzuki 5-1-1, Hidakacho, Hitachi City, Ibaraki Hitachi Cable Co., Ltd. Power Systems Research Center

Claims (5)

[Claims] 1. A power cable line in which an insulating connection portion, in which an outer semiconductive layer and a metal shielding layer are provided with a main edging portion at a substantially central position inside, is connected by a cross bond method, wherein the metal shielding layer is the main edging portion. A method for measuring partial discharge, characterized in that two detection electrodes are formed on both sides of the part by removing the electrodes with a predetermined width, and a partial discharge pulse is detected between the two detection electrodes. 2. The partial discharge measuring method according to claim 1, wherein lead wires are connected to the two detection electrodes in advance and the lead wires are led out to the outside. 3. A power cable line in which an insulating connection portion, in which a main edging portion is provided on an outer semiconductive layer and a metal shielding layer at a substantially central position inside, is connected by a cross bond method, wherein the metal shielding layer is the main edging portion. Two detection electrodes are formed by removing the electrodes with a predetermined width on both sides of the portion, and two metal foil electrodes are attached to the surface of the corrosion-resistant insulating sheath on both sides of the insulating cylinder of the insulating connection portion to detect the two detection electrodes. A partial discharge measuring method comprising detecting a partial discharge pulse from between electrodes for use or between the two metal foil electrodes or both. 4. The partial discharge measuring method according to claim 3, wherein the body tube insulated by the insulating cylinder of the insulating connection portion is connected by a jumper wire having a predetermined high frequency impedance. 5. The partial discharge measuring method according to claim 3, wherein the body tube insulated by the insulating cylinder of the insulating connecting portion is connected by a jumper wire, and a high-frequency iron core is attached to the jumper wire.