JPH05336628A - Power receiving facility - Google Patents

Abstract

PURPOSE:To improve safety by setting an insulating medium to a predetermined value or less of vacuum, and evacuating in vacuum it when the vacuum degree in a metal vessel exceeds the predetermined value. CONSTITUTION:A vacuum pump 10 is connected to a vessel 1 of a power receiving facility through a stop valve 9. Further, a vacuum meter 11 for monitoring vacuum degree in the vessel 1 is provided. The pump 10 is operated together with the valve 9 when vacuum degree measured by the meter 11 is reduced. That is, when a pressure measured by the meter 11 becomes 10<-2>Pa or more, a power source of the pump 10 is turned ON, and the pump 10 is operated. Then, the valve 9 is closed, and the vessel 1 of the facility is evacuated in vacuum. When a pressure of the meter 11 becomes 10<-2>Pa or less, the valve 9 is closed, and the pump 10 is stopped. Thus, safety can be enhanced while maintaining a dielectric strength equivalent to SF6 gas.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to power receiving equipment.

[0002]

2. Description of the Related Art Regarding conventional power receiving equipment, 66 / 77K
An explanation will be given by taking the V-class extra-high voltage transformer equipment as an example.

66KV class power receiving equipment includes (1) open-type (open) power receiving equipment, (2) housing type power receiving equipment, and (3) gas-insulated power receiving equipment (GIS; Gas Insulate).
d Switchgear), (4) Cubicle type gas insulated switchgear (C-GIS; Cubicletype GIS).

By the way, in the open type power receiving equipment, each electrical equipment such as a circuit breaker, a disconnecting switch, a grounding disconnecting switch, an instrument transformer, a current transformer, and a lightning arrester is connected with a copper stranded wire and an aluminum pipe to provide air insulation. It was the power receiving equipment used. Therefore, the installation space is large due to the arrangement of the electric devices in series, and the charging part is exposed due to the air insulation method, which poses a safety problem.

On the other hand, as the construction cost rises and the land costs rise, downsizing and sealing of the power receiving equipment are required due to problems such as contamination of charging parts, safety and noise, and gas insulated power receiving equipment (GI
S) was developed. This is a device in which each electric device is covered with a pipe-shaped metal container, high-pressure SF ₆ gas is filled as an insulating medium, and the device is miniaturized and hermetically sealed.

The cubicle type gas-insulated power receiving equipment is
Higher reliability, safety, and
This is a power receiving facility that has been developed to simplify maintenance and inspections, construct a small site in a short period of time, and respond to requests for harmony with the surrounding environment. This is a cubicle-type container that uses low-pressure insulating gas near atmospheric pressure to store all electrical equipment in a batch, and divides the inside into structural units, similar to other closed switchboards. It is the appearance. As described above, recently, many power receiving facilities using SF ₆ gas as an insulating medium are in operation.

[0007]

This SF ₆ gas is a colorless, odorless, tasteless and nonflammable, very stable gas under normal operating conditions, and is harmless. Due to its high stability and excellent electrical properties, it is widely used as an insulating material for electrical equipment. However, A in SF ₆ gas overvoltage occurs due to accidents - the arc discharge occurs, SF _{6 gas, SOF 2, SO 2, F} 2, SO
It produces decomposition products such as F ₄ , SO ₂ , HF, and SiF ₄ and decomposition gas. The decomposition products and decomposition gas of this SF ₆ gas are harmful.

Therefore, in the power receiving equipment using SF ₆ gas, an adsorbent such as activated alumina or synthetic zeolite is installed to adsorb the decomposed gas. However, although it is difficult to process this adsorbent, the present situation is that it is difficult to use SF ₆ gas for power receiving equipment. An object of the present invention is to provide power receiving equipment having excellent reliability and safety.

[0009]

In order to achieve the above object, according to the first aspect of the invention, in a power receiving facility in which an insulating medium is enclosed in a container for accommodating electrical equipment, insulation is provided in a container for accommodating electrical equipment. In the power receiving equipment in which the medium is enclosed, the insulating medium is set to a vacuum of 10 ^-2 Pa or less, and a control means for evacuating when the vacuum degree in the metal container exceeds 10 ^-2 Pa is provided. Safety can be improved while maintaining the dielectric strength equivalent to that of ₆ gas.

According to the second aspect of the present invention, in a power receiving facility in which an insulating medium is enclosed in a container for storing electrical equipment, a vacuum circuit breaker and a vacuum disconnector are provided as the electrical equipment. 1 inside the container with the sliding part of the main contact part
Since the electric equipment housed in the container was impregnated or filled with an insulating material as well as a vacuum of 0 ^-2 Pa or less, safety can be improved while maintaining the same dielectric strength as SF ₆ gas.
Furthermore, the insulation distance can be shortened.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below.

FIG. 1 is a sectional view showing a part of the power receiving equipment according to an embodiment of the present invention. In FIG. 1, a circuit breaker 3 and a disconnecting switch 4 are provided inside a container 1 of the power receiving facility so that a high voltage opening / closing operation can be performed. Further, inspection / maintenance can be performed by operating the grounding disconnector 5. The high voltage supplied by the electric power company is connected to these devices of the power receiving facility. For higher voltage, container 1
A separately provided power receiving facility is supplied via a bushing 6 penetrating through. In the power receiving equipment of the present invention, the pressure inside the container 1 of the power receiving equipment is a high vacuum of 10 ^-2 Pa or less. The container 1 of the power receiving equipment is, for example, a closed metal container that can withstand a pressure difference of 1 atm with the outside air.

A vacuum pump 10 is connected to the container 1 of the power receiving facility via a stop valve 9. Further, a vacuum gauge 11 for monitoring the degree of vacuum in the container 1 is provided,
The vacuum pump 10 is a system that operates together with the stop valve 9 when the degree of vacuum measured by the vacuum gauge 11 decreases. Specifically, the pressure measured by the vacuum gauge 11 is 1
When the pressure becomes 0 ^-2 Pa or more, the power source of the vacuum pump 10 is turned on, and the vacuum pump 10 operates. Next, the stop valve 9 is brought into the “open” state, and the container 1 of the power receiving equipment is evacuated. When the pressure of the vacuum gauge 11 becomes 10 ^-2 Pa or less, the stop valve 9 is closed and the vacuum pump 10 is stopped.

The stop valve 9 is, for example, a controllable solenoid valve. The vacuum pump 10 is composed of, for example, a turbo molecular pump, a sputter ion pump, a cryopump or the like that can make the degree of vacuum inside the container 1 high vacuum of 10 ^-2 Pa or less.

FIG. 2 shows the relationship between the pressure P and the dielectric strength.
In FIG. 2, the pressure Pmin at which the dielectric strength is minimum is 1
0 ² It is about Pa. Fig. 2 shows the dielectric strength of a high vacuum of 10 ^-2 Pa or less used as an insulating medium for internal equipment of power receiving equipment.
As shown in, it is greatly affected by the degree of vacuum. In the case of a vacuum circuit breaker, the dielectric strength in a high vacuum of 10 ^-2 Pa or less is also greatly affected by microscopic surface conditions such as oxidation of the electrode surface. Therefore, when the heat treatment in vacuum is performed to remove the adsorbed gas on the electrode surface, the dielectric strength increases as shown in FIG. However, in the case of a large facility such as a power receiving facility, it is very expensive to provide a heat treatment device for performing heat treatment. However,
A high vacuum of 10 ^-2 Pa or less, even without heat treatment, has a dielectric strength equivalent to that of the low pressure SF ₆ gas near atmospheric pressure used in the cubicle type gas insulated power receiving equipment.

As described above, the surface of the container 1 of the power receiving equipment is covered with the adsorbed gas layer. This adsorbed gas is gradually released, and the degree of vacuum decreases over the years. As shown in FIG. 2, when the degree of vacuum is reduced, the insulation performance is significantly reduced. However, since the power receiving equipment of the present invention is provided with the vacuum gauge 11, when the degree of vacuum is lowered, the stop valve 9 is brought into the “open” state, and the vacuum pump 10 is activated to operate at 10 ⁻² Pa.
The following high vacuum can be maintained and the insulation performance can be prevented from lowering.

On the other hand, since the high vacuum has a dielectric strength equivalent to that of the low pressure SF ₆ gas, the size of the power receiving equipment of the present invention is
The size can be the same as that of conventional cubicle type gas insulated power receiving equipment. The high vacuum is harmless under normal operating conditions, and even if an arc discharge is generated in the high vacuum due to an accident or the like, the plasma forming the arc will diffuse in the high vacuum. And extinguish the arc. Therefore, SF ₆
Since it does not generate decomposition products or decomposition gas like gas,
It is harmless in the event of an accident and is suitable for environmental protection.
Furthermore, since a high vacuum is used as the insulating medium, it does not deteriorate over time due to corrosion of parts in the container of the power receiving equipment.

Further, FIG. 3 shows a sectional view in which a part of power receiving equipment showing another embodiment of the present invention is cut. In FIG.
Regarding the circuit breaker 3, disconnector 4, and ground disconnector 5 in the container 1, the pressure of the container at the main contact portions 3a, 4a, 5a is, for example, 10 ^-2 Pa.
The following vacuum circuit breakers and vacuum disconnectors were used.
The contact of the circuit breaker 3 can be opened and closed by setting the pressure in the container of the sliding portion 3b of the contact connected to the operating mechanism of the circuit breaker 3 to a high vacuum of 10 ^-2 Pa or less. Similarly, the pressure inside the container of the sliding portions 4b, 5b of the contacts connected to the operating mechanism of the disconnecting switch 4 and the grounding disconnecting switch 5 is also set to a high vacuum of 10 ^-2 Pa or less, so that It can be opened and closed. By operating this grounding disconnector 5,
Inspection / maintenance is possible. The main equipment in the container 1 of these power receiving facilities was insulated by impregnating or filling with a solid insulator of epoxy resin, for example. Further, the high voltage supplied from the power company is connected to these devices of the power receiving facility. In addition, the high voltage causes the bushing 6 to penetrate the container 1.
Is supplied to a substation facility provided separately.

A vacuum pump 10 is connected via a stop valve 9 to the containers 3b, 4b, 5b of the sliding parts of the circuit breaker 3, the disconnecting switch 4 and the grounding disconnecting switch 5. Also, the container 3 of the sliding part
b, 4b, 5b vacuum gauge 11 for monitoring the degree of vacuum,
It is provided. The vacuum pump 10 is a system that operates together with the stop valve 9 when the degree of vacuum measured by the vacuum gauge 11 decreases. Specifically, when the pressure measured by the vacuum gauge 11 becomes 10 ^-2 Pa or more, the power source of the vacuum pump 10 is turned on and the vacuum pump 10 operates. Next, the stop valve 9 is brought into the “open” state, and the container 1 of the power receiving equipment is evacuated. When the pressure of the vacuum gauge 11 becomes 10 ⁻³ Pa or less, the stop valve 9 becomes “closed” and the vacuum pump 10 stops. The stop valve 9 is a controllable solenoid valve. If the vacuum degree in the container 1 is set to 1 in this way, the vacuum pump 10 can insulate the area where particularly high dielectric strength is required.
^Since the vacuum is set to ^-2 Pa or less, the same effect as that of the above-described embodiment can be obtained. Further, since the main equipment in the container 1 of the power receiving equipment is insulated by being impregnated or filled with a solid insulator such as an epoxy resin, it is possible to shorten the insulation distance between the respective equipment, and to make the power receiving equipment compact. It is possible.

[0020]

As described above, according to the first aspect of the present invention, in the power receiving equipment in which the insulating medium is enclosed in the container for housing the electric equipment, the insulating medium is evacuated to 10 ^-2 Pa or less, and the vacuum in the container is reduced. Since the control means for evacuating when the temperature exceeds 10 ^-2 Pa is provided, it is possible to obtain the power receiving equipment with improved reliability and safety.

According to the second aspect of the invention, a vacuum circuit breaker and a vacuum disconnector are provided as electrical equipment housed in the container, and a sliding portion between the vacuum circuit breaker and the main contact portion of the vacuum disconnector is provided. The inside of the container is evacuated to 10 ^-2 Pa or less, and the electrical equipment is impregnated or filled with an insulator, improving reliability and safety, and obtaining a power receiving facility that can be made compact by shortening the insulation distance. be able to.

[Brief description of drawings]

FIG. 1 is a cross-sectional view in which a part of power receiving equipment according to an embodiment of the present invention is cut.

FIG. 2 is a diagram showing pressure-dielectric strength characteristics of the present invention and conventional power receiving equipment.

FIG. 3 is a cross-sectional view in which a part of the power receiving equipment showing another embodiment of the present invention is cut.

[Explanation of symbols]

 9 ... Stop valve, 10 ... Vacuum pump, 11 ... Vacuum gauge

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification number Reference number within the agency FI Technical indication location H02B 13/06 N (72) Inventor Shubun Takemoto 1-1-1 Shibaura, Minato-ku, Tokyo Toshiba headquarters office

Claims (3)

[Claims] 1. In a power receiving facility in which an insulating medium is enclosed in a container for storing electric equipment, the insulating medium is supplied at 10 ^-2 Pa.
A power receiving facility comprising the following vacuum and a control means for performing vacuuming when the degree of vacuum in the container exceeds 10 ^-2 Pa. 2. A power receiving facility in which an insulating medium is sealed in a container for housing an electric device, the electric device including a vacuum circuit breaker and a vacuum disconnector, and a main contact portion of the vacuum circuit breaker and the vacuum disconnector. A power receiving facility, characterized in that a vacuum of 10 ^-2 Pa or less is provided in a container provided with a sliding portion, and an electric device housed in the container is impregnated or filled with an insulator. 3. A control means for evacuating when the degree of vacuum in the container provided with the sliding portion of the main contact portion of the vacuum circuit breaker and the vacuum disconnecting switch exceeds 10 ^-2 Pa. The power receiving equipment according to claim 2.