JPH08122400A - Withstand voltage testing system for power cable - Google Patents

Abstract

PURPOSE: To screen a power cable connected directly with an enclosed electric apparatus efficiently and surely by applying an AC voltage of commercial frequency having such level as causing dielectric breakdown of the power cable when the insulation thereof is deteriorated. CONSTITUTION: Screening is carried out by applying an AC voltage of commercial frequency having such level as causing dielectric breakdown if the insulation of a power cable 5 to be inspected is deteriorated. Consequently, a test can be made under conditions closer to the operating conditions than a DC withstand voltage test and a cable, which may cause a fault during operation, can be detected surely and removed. Since an AC voltage of commercial frequency is employed, the cable to be tested is not required to be separated from an enclosed electric apparatus connected directly therewith, nor required to be switched to three-phase collective connection. Furthermore, the insulating gas filled in the case 1 of apparatus is not required to be sampled or refilled. Consequently, the power cable 5 connected directly with an enclosed electric apparatus can be screened efficiently and surely.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a withstand voltage test method for efficiently testing a power cable directly connected to a sealed electric device, and particularly when the power cable is insulation-deteriorated by a predetermined value or more, The present invention relates to an AC withstanding voltage test method for power cables that can be reliably screened.

[0002]

2. Description of the Related Art A power cable is subjected to a withstand voltage test on site after a new construction of a cable line, a system change work, or a trouble recovery work. In addition, the insulation performance of power cables gradually deteriorates during long-term use, which may lead to dielectric breakdown. In particular, CV cables, which have been widely used recently, may not be used in the cable insulation depending on the manufacturing conditions and the usage environment. Since the water tree that occurs in the equipment may lower the insulation performance in a relatively short period of time and lead to dielectric breakdown, in order to diagnose the insulation strength of the power cable, a withstand voltage test, corona test, leakage current test, etc. Various characteristic tests are conducted. As a withstand voltage test of the power cables after installation, a DC withstand voltage test has been conventionally performed. This is because if the distance of the cable line becomes long, a large charging current flows in the AC withstanding voltage test, so that the voltage-applying equipment such as a transformer becomes large and the withstand voltage test becomes difficult.

By the way, recently, from the standpoint of reducing the site of the substation and improving the reliability of power transmission and distribution, electrical equipment such as a switchgear and a transformer is housed in an equipment case together with an insulating medium such as gas or oil. However, since the high voltage part of these sealed electrical devices is not exposed outside the device case, both ends are directly connected to the sealed electrical devices. In the case of the electric power cable line, there is a problem that it takes a lot of time and effort when performing the above DC withstanding voltage test.

FIG. 2 shows a gas insulated switchgear (hereinafter referred to as GIS).
Is shown in the vicinity of the terminal end of the power cable directly connected to the elephant portion of the cable head is attached to the equipment case 1 in which the GIS main body (not shown) is housed. The bottom plate 3 is provided with three in-gas terminal connections 4. A power cable 5 is connected to each of these in-gas terminal connections, and a connecting rod 6 connects each of the lead-out rods 4a of each in-gas terminal connection 4 and the high-voltage part of the GIS. In addition, the side surface of the cable head elephant portion 2 is closed by a case lid 7, and an S
An insulating gas such as F ₆ is filled at a predetermined pressure.

When performing a DC withstand voltage test on a power cable directly connected to a sealed electric device having such a structure, first, the insulating gas such as SF ₆ filled in the device case 1 is removed, and the case lid 7 is removed. To remove the gas in the terminal connection 4 and GIS
Remove the connecting rod 6 connecting between the high pressure part of
As shown in FIG. 3, the withdrawal rod 4a of the in-gas terminal connection part 4
Attach the 3-phase short-circuit metal fitting 8 between the tips of the. It should be noted that removing the connecting rod 6 connecting between the in-gas terminal connection part 4 and the high voltage part of the GIS may cause various inconveniences when a high DC voltage is applied to the high voltage part of the GIS. So
To avoid it. Next, the withstand voltage adapter 10 is attached to the side surface of the cable head elephant portion 2 via the sleeve tube 9. In addition, a withstand voltage test termination connection portion 11 is previously incorporated in the lower electricity supply port of the withstand voltage adapter 10, and an electricity supply lead cable 12 having a slip-on structure is connected thereto. In addition, the terminal connection portion 1 for withstanding voltage test
A resistor 14 is attached between the pull-out rod 13 of No. 1 and the three-phase short-circuit metal fitting 8, and the side wall of the withstand voltage adapter 10 is closed by the case lid 15. Then, after evacuating the inside of the equipment case 1,
The insulating gas such as SF ₆ is filled again. When the test preparation is completed as described above, after performing a corona test, a leakage current test, etc., if necessary, a predetermined DC voltage is applied from the other end side of the charging lead cable 12 to screen the power cable 5. And confirm its soundness. After the above test is completed, the withstand voltage adapter and the like are removed and the connecting rod 6 is attached in almost the reverse order to the above order, and the insulating gas such as SF ₆ is charged again, and the GIS is operated. Will be returned to.

[0006]

As described above, when performing a DC withstanding voltage test of a power cable line whose both ends are directly connected to a sealed electric device, a withstanding voltage adapter is attached / removed and a connecting rod is connected. There is a problem that it takes a lot of trouble and time for preparatory work such as attachment / detachment or removal / filling of insulating gas such as SF ₆ and the like. Moreover,
Particularly in recent substations where emphasis is placed on compactness, the withstanding voltage adapter is apt to be constrained by the carry-in passageway, installation space and assembly space. However, in the case of long-distance power cable lines, it may not be possible to perform a withstand voltage test by batch charging of three phases due to the charging capacity. There is an inconvenience that it is not possible to do.

As described above, the withstand voltage test of the electric power cable line whose both ends are directly connected to the sealed electric device has been performed by the direct current method because of the size limitation of the withstand voltage adapter. Since the breakdown energy is insufficient in the DC withstanding voltage test, it may not be possible to detect defects in the power cable even if a considerably high voltage is applied. For example, in the case of a CV cable of 66 KV class, according to the result of the recent test conducted by the inventors, the DC withstanding voltage test is 2
Even if a voltage of about 152 KV is doubled, harmful trees may not be detected, which is not sufficient for accident prevention.
On the other hand, in the case of the same CV cable, if a water tree with a length of 3 mm or more exists in the cable insulator, the cable will break at a working voltage of 38 KV, but if 76 KV is applied by alternating current, a water tree with a length of 2 mm or more will be generated. If present, the cable will be destroyed. Therefore, if the cable is screened at this level of AC voltage, accidents during cable operation can be reliably prevented. Further, the AC withstand voltage test is closer to the actual operating condition than the DC withstand voltage test, and effective test data can be obtained.

Therefore, an object of the present invention is to provide a power cable withstand voltage test system for efficiently and surely screening a power cable directly connected to a sealed electric device.

[0009]

A withstand voltage test method for a power cable of the present invention is a bushing having a tapered charging port, a shield metal fitting and an internal conductor embedded in the bushing, and a bushing head. Attach three terminal end portions for withstanding voltage test, which are equipped with a removable insulating plug that closes the charging port of the device, to the wall surface of the equipment case in close proximity, and attach each shielding metal fitting of these connection portions to the sealed electrical equipment. In a sealed electric device electrically connected to the high-voltage conductors of the power cables directly connected, remove the insulation plug blocking the charging port during the withstand voltage test, and attach the charging lead cable to it.
The main feature is to apply an AC voltage of a commercial frequency at a level that causes dielectric breakdown when the insulation of the power cable is deteriorated to the high voltage conductor of the power cable via this charging lead cable. is there.

[0010]

As described above, according to the withstand voltage test method of the power cable of the present invention, when the power cable to be inspected has the insulation deteriorated, the screening is performed by applying the AC voltage of the commercial frequency of the level that causes the dielectric breakdown. Since the test is performed, the test can be performed under a condition closer to the operating condition than the DC withstanding voltage test, and the cable that may cause an accident during operation can be reliably detected and removed. The withstand voltage test termination connection to which the power lead cable is attached is extremely compact and does not occupy as much space as the conventional withstand voltage adapter. Also, attach / remove the withstanding voltage adapter, attach / detach connecting rod, etc.
Work such as extraction and filling of insulating gas such as F ₆ is not required, and workability is greatly improved.

[0011]

EXAMPLE An example of a withstand voltage test method for a power cable of the present invention will be described with reference to FIGS. 1, 4 and 5. In these figures, the same parts as those in FIGS. 2 and 3 are designated by the same reference numerals. FIG. 4 exemplifies the vicinity of an elephant part for a cable head of GIS to which a terminal connection part for withstanding voltage test used when applying the method of the present invention is attached, and a device accommodating a GIS main body (not shown). A cable head elephant part 2 is attached to the case 1, and a bottom plate 3 of this elephant part is attached.
There are three in-gas termination connections 4 attached thereto. A side surface and an upper surface of the cable head elephant portion 2 are airtightly closed by an elephant portion case lid 7 and a bushing mounting substrate 20 which form a part of a device case.
Three bushings 21 formed by molding an insulating material such as an epoxy resin are arranged on the bushing mounting substrate 20, and their leg portions 21a are arranged so as to penetrate the bushing mounting substrate 20, and are hermetically fixed. . In addition, these bushings 21 are, as shown in FIG.
The bushing mounting substrate 20 is arranged in close proximity to the center of the bushing mounting substrate 20 at the apex position of an equilateral triangle on the same circumference.

The bushing 21 has a shielding metal member 22 embedded in a head portion 21b located outside the cable head elephant portion 2, and an internal conductor 23 embedded in a leg portion 21a. In this embodiment, the shield member 22 and the inner conductor 23 are manufactured as an integrated body by processing a metal material such as copper, and the lower end of the inner conductor 23 projects from the leg portion of the bushing 21 and is exposed. Further, the head portion 21b of the bushing 21 is provided with tapered power outlets 21b1 and 21b2 on both left and right sides for receiving a reinforcing insulator on the side of a power lead cable described later. These charging ports are arranged such that their axes and the axes of the internal conductors 23 are substantially orthogonal to each other, and are closed by an insulating plug 24 during normal operation of the GIS.

The insulating plug 24 is formed by molding ethylene / propylene rubber or the like, and is used as a charging port 21b of the bushing 21.
Pre-molded insulator 25 having a convex tapered surface corresponding to the concave tapered surface of 1, 21b2, and a high-voltage side shield electrode 26 and a low-voltage side shield electrode 27 fixed to the inner and outer ends thereof for electric field relaxation. And a mounting plate 29 mounted on the outer surface of the low-voltage side shield electrode 27 via a spring 28. Withdrawal bar 4 of each gas end connection 4
a, the lower end of the inner conductor 23, and the high-voltage part (not shown) of the GIS main body are connected by the connecting rods 6 for each phase, and the in-gas terminal connection part 4 is supplied with electric power. The cable 5 is connected. In addition, in the device case 1 including the cable head elephant part 2, SF
Insulating gas such as ₆ is filled. Of the three bushings 21 fixed to the bushing mounting substrate 20, the leg portion 21a of the bushing connected to the central charging lead cable is longer than the remaining two bushings, and the spacer is It is airtightly fixed to the bushing mounting substrate 20 via 30.

The GIS having such a configuration is supplied with a high voltage from the upstream transformer or other power supply equipment (not shown) through the power cable 5 when the power system is normally operated. This high voltage is also applied to the shield metal fitting 22 of the withstand voltage test termination connection portion, but the taper surface of the premolded insulator 25 is tapered by the force of the spring 28 so that the head portion of the bushing 21 is tapered. 21b1 and 21b2 are crimp-fitted to form a high-voltage shield electrode 26 and a low-voltage shield electrode 2
The dielectric strength of the interface between 7 is maintained.

Next, when performing the AC withstanding voltage test of the power cable 5 connected to the GIS as described above, the power supply circuit that has applied the high voltage to the power cable 5 is shut off, and the bushings 21 for each phase are connected. One of the charging ports 21b1 and 21b2 is removed, and instead, as shown in FIG. 1, the tip of the charging lead cable 12 is inserted and fixed.

The charging lead cable 12 has a slip-on structure at its tip. That is, the reinforcing insulator 32 is formed with a convex tapered surface having a shape corresponding to the charging ports 21b1 and 21b2 on the bushing 21 side at the tip of the cable insulating layer 31 of the charging lead cable 12.
And a semi-conductive layer 33 at the outer end thereof is electrically connected to the shielding layer 34 of the lead cable 12 and a supporting mechanism 36 having a spring 35 for exerting a pressing force on the reinforcing insulator 32 is provided. Using a thing, it attaches so that the convex taper surface of the reinforcement insulator 32 may adhere to the charging ports 21b1 and 21b2 of the bushing 21 side. In this case, a plug 38 is fixed via a wedge to the cable conductor 37 exposed by stripping off the insulating layer end portion of the power charging lead cable 12, and an annular ring that expands and contracts in the radial direction on the outer circumference of the plug. The conductive contactor (multi-ram band) is covered, and when the reinforcing insulator 32 is mounted, the cable conductor 37 and the shielding metal member 22 are wedged and electrically connected via the plug 38 and the conductive contactor.

As described above, the charging lead cable 12
When the connection is completed, the AC voltage of the commercial frequency is applied from the other end side simultaneously for three phases or for each single phase. The voltage applied in this case is set to a level above which insulation breakdown occurs when the insulation of the power cable 5 to be tested has deteriorated. That is, for example, in the case of the above-mentioned 66 KV class CV cable, the length of the cable insulator is 3 m.
If a water tree of m or more is present, the cable will have a working voltage of 3
It breaks at 8 KV, but if AC voltage of 76 KV is applied, the cable will break due to the existence of a water tree with a length of 2 mm or more, so if you want to remove the cable with a water tree of 2 mm or more, use 76 KV. The above AC voltage should be applied. If the power cable under test is destroyed by this screening, the cable had a high risk of causing an accident during operation, so it is disqualified and removed and replaced with another power cable. After the connection work of this new power cable is completed, the AC withstand voltage test is performed again in the same manner as described above, and if it withstands this, the test is judged to have passed.

As described above, according to the present invention, an alternating voltage is applied to a cable to test its withstand voltage. Therefore, the test environment is close to the actual use conditions of the cable and the deteriorated cable is If present, it can be reliably detected and removed. Moreover, since the AC voltage of the commercial frequency is used, it is not necessary to disconnect the cable under test from the sealed electric equipment to which they are directly connected or switch to the three-phase batch connection, and the cable is filled in the equipment case. There is no need to extract or refill insulating gas. Also,
GI is a sealed electrical device that is directly connected to the cable under test.
In the case of S, if it is not desired to apply a test voltage to the high voltage part or electric equipment connected thereto, the GIS may be opened to conduct the test. The withstand voltage test termination connection used in the present invention is very compact, and the high-voltage part is always closed by an insulating plug, so it is safe, Connection work is also easy.

Particularly, in the case of using a withstand voltage test terminating portion arranged such that the axis of the tapered charging port of the bushing and the axis of the internal conductor are substantially orthogonal to each other as described in claim 2. Since the charging lead cable can be pulled out in a direction parallel to the bushing mounting substrate, it is not necessary to bend the charging lead cable with a large curvature even in a narrow substation or the like, and installation work is easy. Further, as described in claim 3, when using a withstand voltage test termination connecting portion in which two tapered charging ports are provided symmetrically with respect to the inner conductor in the bushing,
It is also possible to directly connect another cable, for example, the power cable 5 for power supply, to the charging port that is not used for attaching the charging lead cable, and in that case, the in-gas terminal connecting portion 4 can be omitted.

Further, as described in claims 4 and 5, the three withstanding voltage test termination connection portions are provided on the bushing mounting substrate forming a part of the equipment case of the hermetically sealed electrical equipment, substantially from the center thereof. Install one bushing mounting board on one end terminal for withstanding voltage test, which is connected to the center lead voltage lead cable of the lead wire cables that are installed in close proximity to each other and arranged in parallel. If the bushing leg that penetrates is longer than the other two bushing legs of the terminal connection for withstanding voltage test, and if it is attached to the bushing attachment board via the spacer arranged outside the equipment case, three Since the terminal connection portion for the withstanding voltage test can be arranged in a staggered pattern and the lead cable for charging can be arranged in a three-row bales, the mounting range of the terminal connection portion for the withstanding voltage test can be further reduced.

[0021]

As described above, according to the present invention, the power cable that may cause dielectric breakdown during actual use can be reliably detected and removed, so that the reliability of the power system can be improved. In addition, as in the case of DC withstanding voltage test, it is not necessary to disconnect the cables under test from the sealed electrical equipment to which they are directly connected or to switch to the three-phase batch connection, and to fill the equipment case with There is no need to remove or refill the insulating gas that is present. Therefore, the power cable directly connected to the sealed electric device can be efficiently and reliably screened.

[Brief description of drawings]

1 is a vertical cross-sectional view showing a state in which a charging lead cable is attached to a terminal connection portion for withstanding voltage test in the elephant portion for cable head of FIG.

FIG. 2 is a vertical cross-sectional view showing the vicinity of a terminal end portion of a power cable directly connected to a conventional GIS.

FIG. 3 is a vertical cross-sectional view showing a state in which a charging lead cable is attached to a terminal end portion of the power cable of FIG. 2 via a withstand voltage adapter.

FIG. 4 is a vertical cross-sectional view illustrating the vicinity of an elephant part for a cable head of a GIS to which a terminal connection part for withstanding voltage test used when applying the method of the present invention is attached.

FIG. 5 is a plan view of the vicinity of a terminal connection portion for withstanding voltage test and a charging lead cable in FIG.

[Explanation of symbols]

 1 ...... Equipment case 2 ...... Elephant part for cable head 4 ...... Gas end connection part 5 ...... Power cable 6 ...... Connection rod 8 ...... Three-phase short-circuit fitting 10 ...... Withstanding voltage adapter 11 ...... Withstanding voltage Terminal connection for testing 12 ...... Electrical supply lead cable 13 ...... Drawer rod 14 ...... Resistor 20 ...... Bushing mounting board 21 ...... Bushing 21b1, 21b2 ...... Electrical charging port 22 ...... Shielding metal fitting 23 ...... Inner conductor 24 ... Insulation plug 25 ... Premolded insulator 26 ... High-voltage side shield electrode 27 ... Low-voltage side shield electrode 30 ... Spacer 32 ... Reinforcement insulator 37 ... Cable conductor 38 ... Plug

Claims (5)

[Claims] 1. A. A leg that airtightly penetrates the wall surface of the case of the sealed electric device, and a head has a bushing provided with a tapered charging port for receiving the reinforcing insulator on the charging lead cable side; and b. A shield fitting embedded in the bushing and electrically connected to the cable conductor when the charging lead cable is mounted; c. An internal conductor having one end connected to the shielding metal member and the other end exposed from the tip of the bushing leg in the device case; d. Detachable insulation plugs for closing the charging port of the head of the bushing and three terminal end portions for withstanding voltage test are attached in close proximity to the wall surface of the equipment case. In a sealed electric device electrically connected to a high-voltage conductor of a power cable directly connected to the sealed electric device, remove the insulating plug closing the charging port, and attach the charging lead cable there, The high voltage conductor of the power cable is charged with an AC voltage of a commercial frequency of a level that causes dielectric breakdown when the power cable is insulation deteriorated through the power lead cable to screen the power cable. A withstanding voltage test method for power cables. 2. A terminal connection portion for a withstanding voltage test, which is arranged such that the axis line of the tapered charging port of the bushing and the axis line of the inner conductor are substantially orthogonal to each other. Withstanding voltage test method for power cables. 3. A withstand voltage test termination connection in which a shielding metal member and an internal conductor are integrally formed, and two tapered charging ports are provided symmetrically around the internal conductor in a bushing. 3. Use of parts
The withstand voltage test method for power cables described in. 4. The three terminal connection parts for withstanding voltage test are mounted on a bushing mounting board which constitutes a part of a device case of a sealed electric device in the vicinity of substantially equal triangular positions from the center thereof. The withstand voltage test method for a power cable according to claim 1, wherein 5. The three terminal end portions for withstanding voltage test are respectively connected to the tip end portions of the electric charge lead cables arranged substantially in parallel, and are connected to the electric charge lead cables located at the center. In one of the withstanding voltage test termination connecting portions, the bushing leg portion that penetrates the bushing mounting substrate is longer than the other two withstanding voltage test termination connecting portion bushing leg portions, and is outside the equipment case. The withstand voltage test method for a power cable according to claim 4, wherein the withstand voltage test method is mounted on the bushing mounting substrate via a spacer arranged in.