JP3080681B2 - Power cable withstand voltage test equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power cable withstanding voltage test apparatus for applying a test voltage to a power cable connected between substations to perform a DC withstanding voltage test.

[0002]

2. Description of the Related Art Conventionally, when a substation is installed in a city center,
Normally, a gas insulated switchgear is installed inside a building or underground, and power transmission and reception between substations is performed by connecting power cables to each other.

FIG. 7 shows a configuration example of a gas insulated switchgear of such a substation, and FIG. 8 shows an electric circuit of this switchgear in a single-line diagram. As shown in FIGS. 7 and 8, in order to reduce the installation space of the entire switchgear,
A plurality of circuit breakers 1, disconnectors 2 and the like are installed in combination. In this case, in the switchgear, a power cable 4 is connected to the cable head 3 as a power system, and the other of the power cable 4 is connected to another substation through the underground.

By the way, when another substation is newly constructed adjacent to the existing substation and a power cable is laid, a DC withstand voltage test is performed on the power cable before connecting to the existing operation system. Has been conducted to confirm the insulation performance of the power system.

FIG. 9 shows a configuration example of a conventional power cable withstand voltage test apparatus. As shown in FIG. 9, a protection resistor 5 and a cable head 6 are connected to the outlet of the cable head 3 of the newly installed switchgear opposite to the switchgear side. The cable 7 is pulled in via the drum 9. The cable 7 is connected to a lower terminal of a bushing 10 installed vertically in the air, and the upper terminal of the bushing 10 is connected to a head of a bushing 12 which is vertically set up on a DC voltage generator 8 via a water resistor 11. Connected to the unit 12a. FIG. 10 shows an electric circuit of such a withstand voltage test apparatus, and the same parts as those in FIG. 9 are denoted by the same reference numerals.

In the power cable withstand voltage test apparatus having such a configuration, the power cable 4 of the newly installed switchgear is used.
Is performed by connecting a DC voltage generator 8 to the power cable 4 and applying a DC high voltage. In this case, if the system voltage is 275 KV, a DC voltage with a very high DC withstand voltage of 414 KV is applied.

Immediately after the insulation performance of the power cable 4 is confirmed by the DC withstand voltage test, a test voltage of 414 KV remains in the cable, and it is necessary to discharge this residual voltage to the ground potential. is there. Therefore, conventionally, as shown in FIG.
The power cable 4 is set to the ground potential by contacting the water resistance 11 with the connection between the water resistance 11 and the head 12a of the bushing 12 attached to the DC voltage generator 8 to ground.

In this power cable grounding method, since the power cable 4 is grounded via the water resistance 11, the energy remaining in the cable 4 (Q = 残留 · CV ²⁾ ) Are all absorbed by the water resistance 11. For this reason, a huge volume is required as the heat capacity of the water resistance 11,
In addition to the increase in size, a large space and area are required as the installation space for the test apparatus. Therefore, in order to absorb the energy remaining in the cable 4 by using the normal water resistance 11, the DC voltage withstand test is left almost for one day, and the residual voltage is attenuated to about 1/2. We are trying to make contact with the ground in anticipation of the situation. In this case, since the residual energy is proportional to the square of the voltage, it becomes 1/4.
However, there is a problem that it takes about one and a half days to set the ground potential after the withstand voltage test.

To ground the power cable 4,
The ground rod 13 is connected to the head of the bushing 12 of the DC voltage generator 8.
12a, but immediately after the test, the bushing head
12a is the same as the residual potential of the cable.
And even after being left for one day, a high voltage of about 200 kV
The tip of the ground rod 13Get closer
Aerial breakdown between the bushing and the bushing head 12a.
And a blow-up sound was generated with the blowout
The safety of workers,
Consideration is also needed.

[0010]

As described above, in the conventional power cable withstand voltage test apparatus, the discharging of the charging voltage of the power cable after the withstand voltage test is performed by the method described above. The withstand voltage test of the cable is only at the time of new installation, so it is useless to secure a large space, and it is practical to increase the size of each device to solve the problems of the current test equipment. Is in an impossible situation.

According to the present invention, safety can be ensured by eliminating the occurrence of an air arc when the power cable is grounded after a withstand voltage test, and a large-scale discharge facility can be used even in a narrow space of a substation under construction. It is an object of the present invention to provide a power cable withstand voltage test device capable of performing a DC withstand voltage test of a power cable without making the power cable immersed.

[0012]

According to the present invention, a DC withstanding voltage test is performed by connecting a DC voltage generator to a power cable and applying a test voltage to the power cable when the power cable is installed. in the withstand voltage test device for a power cable to perform the gas insulated connected in series
Insulating gas for switch and discharge resistor or discharge coil
Stored in a filled container and the bushing
Derive one electric circuit in the container from the
And connecting an electrical circuit derived from said bushing to a charge discharging portion of said cable, and connecting the other electrical circuit in said container.
And the series unit is connected in parallel with the DC voltage generator. In addition, a disconnecting switch having a closing speed of the movable contact at the time of closing of about 1 m / s or more is used as the gas insulating switch.

[0013]

In the power cable withstand voltage test device having such a configuration, the gas insulated switch of the series unit is opened during the withstand voltage test of the power cable, and the gas insulated switch is closed after the withstand voltage test. Since the residual voltage of the power cable is discharged to the discharge resistor or the discharge coil through this gas insulated switch and is consumed as Joule heat, if the time constant is set appropriately, the potential of the power cable becomes 1 after the withstand voltage test. Since it is possible to set the ground potential within 2 hours or less and no aerial arc is generated, the problem of safety can be completely solved.

[0014] In addition, by closing the movable contact portion at a closing speed of about 1 m / s or more as a gas insulated switch at a high speed with a disconnector having a closing speed of about 1 m / s or more, a pre-arc generated when the movable contact member approaches the fixed contact portion to some extent is prevented. Since it can be eliminated before the blow-up, the reliability can be further improved.

[0015]

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows an example of a circuit configuration of a power cable withstand voltage test apparatus according to the present invention. The same components as those of the conventional components shown in FIG. 10 are denoted by the same symbols. In the present embodiment, as shown in FIG. 1, the connection cable 7 is drawn into the test room from the connection point 15 of the cable head 3 of the switchgear via the protective resistor 5, and the bushing 10 installed vertically in the test room One end of a series circuit of a gas insulated disconnector 17, a gas insulated resistor or a discharge coil 18 is connected to the water resistance 11 via a bushing 16, and the other end is grounded to a ground point 19. Are connected in parallel. The range indicated by the dotted line in the drawing is the gas-insulated portion.

FIG. 2 shows an example of the arrangement of each device based on the circuit configuration of FIG. 1. The same parts as those of FIG. 7 are denoted by the same reference numerals, and the description thereof will be omitted. Show. As shown in FIG.
Is installed vertically, a connecting gas bus 21 having a bushing 16 attached to the upper portion thereof is attached to the connecting gas bus 20 and the head of the bushing 16 is connected to the bushing 10 and the water resistance 1.
1 A gas insulated disconnector 17 is connected orthogonally to the gas bus 20, and a gas insulated resistor or a coil 18 is vertically connected to an upper portion of the gas insulated disconnector 17. As shown in FIG. 3, the gas insulating disconnector 17 has a metal container 23 filled with an insulating gas 24, and a fixed contact portion 25 and a movable contact portion 26 are supported and fixed on an insulating spacer 27. A movable contact 28 that moves in the axial direction while contacting the movable contact portion 26 is connected to an insulating rod 29.
It is connected to a main shaft 32 of an operation mechanism (not shown) via a link 30 and a lever 31. Accordingly, the gas insulated disconnector 17 is opened and closed by moving the movable contact 28 in the axial direction with respect to the fixed contact portion 25 by operating the main shaft 32 by operating the operation mechanism.

On the other hand, the gas-insulated resistor or gas-insulated coil 18 has a heat capacity sufficient to absorb the energy remaining in the test cable 4 as Joule heat, and has a damping time constant CR (C is the test time). The capacity and R of the cable 4 are set so that the resistance value of the resistor or the resistance value of the resistance of the coil) is 1-2 hours or less. Further, the gas insulation resistor or the gas insulation coil 18 has a cable charging voltage as a whole,
For example, when the system voltage is 275 KV, the DC withstand voltage is 414 KV.
Is applied, the insulating performance that can withstand high voltage is ensured by the insulating gas filled in the container. Here, in the case of a resistor, it is easy to constitute a fired body mainly composed of silica, and in the case of a coil, it is completely different from a gas-insulated PT (voltage measuring instrument) used in a gas-insulated switchgear. It is possible to have the same configuration.

In the power cable withstand voltage test apparatus thus constructed, the withstand voltage test of the power cable 4 is performed by opening the disconnector 17 shown in FIG. The voltage is the test voltage, for example,
Step up to V. Thereafter, a high voltage is applied to the power cable 4 from the DC voltage generator 8 via the water resistance 11,
A withstand voltage test is performed. Next, when the disconnector 17 is closed after a predetermined voltage application time has passed, the power cable 4
Is grounded via the drop cable 7, the disconnector 17, the discharge resistor or the coil 18, and the electric charge charged in the power cable 4 is quickly discharged. At this time, Joule heat is absorbed by the discharge resistor or the coil 18, and the residual energy of the power cable 4 is attenuated by the time constant of the product CR of the capacitance C of the power cable 4 and the discharge resistance or the resistance value R of the coil 18.

Therefore, by appropriately setting the time constant as described above, the residual voltage of the power cable 4 can be discharged in about 1 to 2 hours after the withstand voltage test is performed. Further, since the charging water resistance 11 does not enter the discharge circuit at this time, the water resistance 11 does not need to absorb the residual energy of the cable. As a result, the capacity of the water resistance 11 is substantially the same as that of the prior art, and it is possible to make the water resistance 11 smaller than before. Furthermore, since the discharge of the charged charges of the power cable 4 is performed in the gas insulated disconnector 17, the arc at the time of closing is in the tank and the sound is reduced.

FIG. 11 shows a situation when the gas insulated disconnector 17 performs a closing operation. Movable contact 2 in closed circuit
8 is operating toward the fixed contact portion 25, but the fixed contact portion 25 has a residual voltage of the power cable 4, for example, DC 414 KV.
Therefore, this voltage is applied between the movable contacts 28. Therefore, when the movable contact 28 approaches the fixed contact portion 25 to some extent, the pre-arc 33
Occurs.

When the closing speed of the movable contact 28 is low, while the movable contact 28 reaches the fixed contact portion 25,
The pre-arc 33 generates a force that rises due to a current flowing through the arc and a magnetic field generated by the arc, extends up as shown by the arrow in FIG. 11, eventually reaches a metal container having a ground potential, and may be directly grounded during discharge. For this reason, even if the pre-arc 33 occurs, it is necessary to bring the movable contact 28 into contact with the fixed contact portion 25 immediately before the arc blows up so much to complete the closing and to extinguish the arc. The closing speed of the movable contact 28 necessary for this is related to the gap voltage, that is, the rated voltage of the power cable 4. However, if the closing speed is approximately 1 m / s or more, the closing speed before the pre-arc blow-up occurs. Reduction is possible. As described above, if the gas insulated disconnector 17 is closed at a high speed of about 1 m / s or more by an electric spring operation or the like, a more reliable effect can be obtained.

In the above embodiment, the connection cable 7 is connected to the connection point 15 of the cable head 3 of the switchgear via the protection resistor 5. the resistance value R ₂ of the comparison by the resistance value R ₁ discharge resistor or a coil 18, by the relation of R ₁ << R _2, it is possible to omit the water resistance 11 as shown in FIG. 4, the test Equipment can be greatly simplified.

In the above embodiment, the DC voltage generator 8 may be gas-insulated, and the DC voltage generator 8 may be connected to a branch provided on the gas-insulated bus 21. FIG. 5 shows an electric circuit having such a configuration, and FIG. 6 shows an arrangement configuration of each device of the test facility. With such a configuration, the space occupied by the test equipment can be further greatly reduced. What
Note that the gas insulated disconnector 17 and the gas insulated resistor or discharge
The connection order of the gas insulated disconnector 17
A similar effect can be obtained even when grounded.

[0025]

As described above, according to the present invention, it is possible to significantly reduce the size of the test equipment and greatly reduce the extra space for temporary testing when constructing a substation. Can be. This is very effective in substations and switchyards installed deep underground in buildings. In addition, since a ceramic resistor or metal resistor is used instead of the conventional water resistor as the discharge resistor,
The heat capacity with respect to the energy absorption at the time of discharge can be realized compactly, and even immediately after the DC withstand voltage test, the discharge can be quickly performed and the next field test can be performed. This will shorten the installation period for substations and switchyards. Further, the switch for closing operation during discharge is housed in a metal container and can be operated at high speed, so that the arc generated at the time of closing is extremely shortened to several milliseconds to several tens of milliseconds, and the generation time is extremely shortened. Because it does not touch the surface, it can greatly contribute to the safety of field tests.

[Brief description of the drawings]

FIG. 1 is an electric circuit diagram showing an embodiment of a withstand voltage test apparatus for a power cable according to the present invention.

FIG. 2 is an arrangement configuration diagram of each device of the embodiment.

FIG. 3 is a sectional view showing details of a gas insulated disconnector in the embodiment.

FIG. 4 is an electric circuit diagram showing another embodiment of the present invention.

FIG. 5 is an electric circuit diagram showing another different embodiment of the present invention.

6 is an arrangement configuration diagram of each device of the embodiment shown in FIG.

FIG. 7 is an arrangement configuration diagram of each device of the gas insulated switchgear.

FIG. 8 is a typical single connection diagram of the switching device.

FIG. 9 is an arrangement diagram of each device showing a conventional power cable withstand voltage test apparatus.

FIG. 10 is an electric circuit diagram of FIG. 9;

FIG. 11 is a view for explaining a situation when a closing operation is performed by the gas insulated disconnector of FIG. 2;

[Explanation of symbols]

3, 6 ... cable head, 4 ... power cable, 5 ...
... Protective resistor, 7 ... Incoming cable, 8 ... DC voltage generator, 9 ... Cable drum, 10, 12, 16 ...
Bushing, 11 water resistance, 17 gas-insulated disconnector, 18 gas-insulated resistor or coil, 19 ground point, 20, 21 connection gas bus.

──────────────────────────────────────────────────続 き Continued on the front page (72) Koji Hashimoto, Inventor 1-3-1, Uchisaiwaicho, Chiyoda-ku, Tokyo Inside Tokyo Electric Power Company (72) Inventor Yasutaka Fujiwara 2-1-1, Eiji Oda, Kawasaki-ku, Kawasaki-ku, Kawasaki, Kanagawa Prefecture Showa Electric Wire & Cable Co., Ltd. (72) Inventor Osamu Tanda 1-1-1, Oda Ei, Kawasaki-ku, Kawasaki City, Kanagawa Prefecture Inside of Showa Electric Wire & Cable Co., Ltd. (72) Inventor Ikuo Miwa No. 2-1 Ukishima-cho, Kawasaki-ku, Kawasaki-shi, Kanagawa Prefecture In-house Toshiba Hamakawasaki Plant (56) References JP-A-61-292074 (JP, A) Hei 4-328474 (JP, A) Fully open 49-103479 (JP, U) Fully open 1956-96810 (JP, U) Fully open 1955-175945 (JP, U) (58) Survey The field (Int.Cl. ^7, DB name) G01R 31 / 08,31 / 12 H02B 13/00 - 13/08

Claims (2)

(57) [Claims] The method according to claim 1] to connect a DC voltage generator to said power cable distribution設時power cable for applying a test voltage, the withstand voltage test device for a power cable to perform the DC withstand voltage test, the series Gas connected to
Insulating gas for edge switch and discharge resistor or discharge coil
Into a container filled with
Deriving one electric circuit in the container from the sing
And connecting the electrical path derived from the bushing to the charge discharging portion of the cable, and connecting the other electrical path in the container.
A withstand voltage test apparatus for a power cable, wherein the series unit is connected in parallel to the DC voltage generator by grounding a path . 2. A withstand voltage test of a power cable according to claim 1, wherein a disconnecting switch having a closing speed of a movable contact at the time of closing of about 1 m / s or more is used as said gas insulated switch. apparatus.