JP2000209720A - Gas-insulated metal closing type switchgear - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a gas-insulated metal closing type switchgear whose outer dimensions are reduced so as to solve problems with respect to transportation and gas substitution. SOLUTION: An attachment surface, whose upper part is inclined backward by 20 deg., is formed on the front end of the upper end of a box unit 1. Polymer bushings 2A are attached to the attachment surface. A cable chamber 1c is provided behind a main circuit apparatus chamber 1a of the box unit 1. T-type bushings 8A are made to penetrate the lower part of a partition between the cable chamber 1c and the main circuit apparatus chamber 1a. With this constitution, transportation difficulties due to the shift in the center of gravity caused by the polymer bushings 2A are relaxed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a gas-insulated metal closed switchgear.

[0002]

2. Description of the Related Art FIG. 5 is a right side view showing an example of a conventional gas insulated metal closed switchgear. In FIG.
A front door 21c is mounted on the left front side of the box 21 in FIG. 5 via a hinge and a handle, and a rear door 21d is symmetrically mounted on the right rear side.

[0005] A U-shaped partition 21 a in FIG. 5 is provided inside the box 21 in an airtight manner. An atmosphere insulating chamber 21 e is formed outside the partition 21 a, and an insulating gas ( SF ₆ gas) is sealed to form a high-pressure chamber 21f.

Further, a cable duct is provided above the box 21.
A T-shaped bushing 8C is connected between a rear portion of the cable duct 21b and the high-pressure chamber 21f and is connected to a box adjacent to the box 21 via a cable. .

[0005] On the left and right sides (both sides in the direction perpendicular to the paper surface) of the rear end of the box 21, porcelain bushings 2C for the first and third phases are attached with their upper parts inclined rearward by about 45 °. The second-phase porcelain bushing 2C is vertically provided between the bushings 2C.

The leading ends of these porcelain bushings 2C are connected to load-side ends of drop-in wires (not shown). Under these porcelain bushings 2C, there is a partition
A current transformer 19 is mounted on the inner surface side of 21a, and the lower end of the center conductor 7F of the porcelain bushing 2C is connected to a power supply-side terminal of the current transformer 19.

Under the current transformer 19, an arrester 22 penetrates the bottom plate of the partition 21a from below, and a main circuit terminal of the arrester 22 is connected to a load-side terminal of the current transformer 19. Have been.

In front of the lightning arrester 22, a disconnector 22B with a grounding device on the power supply side is fixed to the upper surface of the bottom plate of the partition 21a, and a fixed terminal at the rear of the disconnector 22B with a grounding device is a current transformer 19b.
Is connected by a connection conductor 7E.

A main circuit portion of a vacuum circuit breaker 23 is erected from the bottom plate in front of the disconnecting device 22B with a grounding device, and projects downward from an intermediate portion of the vacuum circuit breaker 23 to serve as a power supply terminal. Is connected to the movable terminal at the front end of the disconnector 22B with a grounding device via a connection conductor 7D. At the front end of the bottom plate of the box 21, an operation mechanism 24C of the vacuum circuit breaker 23 is housed.

Behind the upper part of the vacuum circuit breaker 23, a disconnecting switch 22A with a grounding device is fixed via a mounting frame (not shown).
C is connected to the load side terminal at the upper end of the vacuum circuit breaker 23.

Disconnector operating mechanisms 24A and 24B for operating upper and lower disconnectors 22A and 22B with grounding devices are provided at the front end of the partition 21a.
Has been fixed. Among them, an example of mounting the porcelain bushing 2B is also disclosed in Japanese Patent Application Laid-Open No. 63-253805. In the example of FIG. 5, the height (for 66 kV) of the porcelain bushing 2B is about 1.5 m.

[0012]

However, in the gas-insulated metal-closed switchgear constructed as described above, when the porcelain bushing 2C protrudes upward from the box, the switchgear is transported from the factory to the installation location. Transport may not be possible depending on the height restrictions on the road from the manufacturing plant to the installation site.

Therefore, at the time of shipment, the porcelain bushing 2
C is removed and transported. However, if the porcelain bushing 2C is removed, it is necessary to enclose the insulating gas inside the partition 21a on site.

In this case, it is necessary to carry out the equipment for the encapsulation work and to perform a gas replacement work on site, so that not only the installation period is lengthened, but also a problem arises in the management of the gas replacement work. Accordingly, an object of the present invention is to provide a gas-insulated metal closed switchgear which can reduce the outer shape and eliminate problems such as transportation and gas replacement.

[0015]

According to a first aspect of the present invention, there is provided a gas-insulated metal closure in which an insulating bushing connected to a high-voltage device inside a box via a central conductor is protruded from an upper portion of the box. The switchgear is characterized in that an insulating bushing is attached at an angle of 20 ° with the tip upward with respect to the installation surface of the box.

According to a second aspect of the present invention, an insulating bushing is provided on one side of an upper portion of a box, and connected to a cable connected to the outside of the box from the insulating bushing via a high-voltage device on the other side of the box. A cable room for accommodating the components is arranged.

According to a third aspect of the present invention, there is provided an insulating bushing comprising: a mounting flange fixed to the outer surface of the mounting portion and having an inner diameter larger than a through hole of a center conductor formed in the mounting portion; An inner tube made of a resin, the lower end of which is inserted into the outer tube, an outer tube inserted outside the inner tube and formed on the outer periphery of a plurality of folds, and a lower portion of the outer tube and an outer periphery of an upper portion of the mounting flange. And a ground covering.

By means of such means, in the invention corresponding to the first aspect, the increase in the outer shape due to the insulating bushing is minimized, and in the invention corresponding to the second aspect, the position of the center of gravity at the time of lifting by a wire rope or the like is reduced. In the invention according to the third aspect of the present invention, the size is reduced by improving the withstand voltage characteristics of the insulating bushing.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the gas-insulated metal switchgear of the present invention will be described below with reference to the drawings. FIG. 1 is a right side view showing a first embodiment of a gas insulated metal closed switchgear of the present invention, and corresponds to FIG. 5 shown in the prior art, and corresponds to claims 1 and 2. It is.

FIG. 1 differs from FIG. 5 shown in the prior art in that the structure of the box is also different in the structure for fixing the main circuit device in the box and the upper bushing. The rated voltage is 66/77 kV as in FIG.

That is, the box 1 comprises a main circuit device room 1a, a conductor room 1b above the main circuit device room 1a, and a cable room 1c formed behind the main circuit device room 1a and the conductor room 1b. An insulating gas (SF ₆ gas) is sealed in the conductor chamber 1b and the main circuit equipment chamber 1a.

Among these, the conductor chamber 1b has a substantially trapezoidal shape in a portion protruding forward when viewed from the side, and also has a substantially trapezoidal shape with a gentle front end in a plan view (not shown).
The front of this trapezoid is 20 ° upward and rearward with respect to the vertical
It is inclined.

A polymer bushing 2A described below is fixed to the inclined surface. In a plan view (not shown), the mounting surface of the first phase and the third phase is slightly inclined in the lateral direction on the surface to which the base end of the polymer bushing 2A is fixed. In a plan view (not shown), the tip is expanded.

The main circuit equipment room 1a is vertically provided with an intermediate partition for airtightly partitioning the main circuit equipment room 1a from side to side with respect to an intermediate part viewed from a front view (not shown). The lightning arrester 4 is attached from the right side.

A current transformer 5 is attached to the lower side of the first and third phases of the lightning arrester 4, and a disconnector 6 with a grounding device is provided below the current transformer 5. Are stored for three phases.

On the other hand, a vacuum circuit breaker (not shown) is accommodated on the left side of the intermediate partition. The first and third phases of the upper pole of the vacuum circuit breaker are connected to the current transformer 5 and the second phase Is connected to the lightning arrester 4.

The lower pole of the vacuum circuit breaker is a disconnector 6 with a grounding device.
Is connected to one side. The other side of the disconnector 6 with a grounding device is connected to the front end of a T-shaped bushing 16 which is provided from the rear below the partition between the main circuit equipment room 1a and the cable room 1c.

The rear door 1d at the rear end of the cable chamber 1c is divided into upper and lower parts, and a chain line behind the box 1 with respect to the mounting base fixed inside the square hole formed in the upper rear door. The T-shaped bushing mounting plate at the front end of the power receiving transformer 3 is fixed from behind.

The upper end of the high-pressure cross-linked polyethylene cable 9 inserted through the opening 8b at the lower end of the T-shaped bushing 8B penetrating the T-shaped bushing mounting plate from the front is connected to a central conductor (not shown) of the T-shaped bushing 8B. The lower end of the high-pressure cross-linked polyethylene cable 9 is connected to the T
Inserted through the opening 8b at the upper end of the bushing 8A,
Also connected to the center conductor.

An insulating plug 8a constituting a part of the T-shaped bushings 8A and 8B is inserted into the upper opening of the upper T-shaped bushing 8B and the lower opening of the lower T-shaped bushing 8A. Has been fixed. An intermediate portion of the high-pressure cross-linked polyethylene cable 9 is supported by a cable support 11 fixed to a front end of the cable chamber 1c.

FIG. 2 is an enlarged sectional view of a mounting portion of the polymer bushing 2A described with reference to FIG. A thick plate mounting flange 1e shown in FIG. 2 is hermetically welded to the slope of the front end of the conductor chamber 1b shown in FIG.
The circular formed in the central portion of the inner peripheral surface of the outer mounting flange 1e of the through holes 1f, chamfering curvature R ₁ of the plate thickness amount to the inner conductor chamber 1b is subjected, small outside chamfering curvature R ₂ is formed.

Further, an annular groove is formed on the mounting surface side, and an O-ring 13 is inserted into this groove. On the mounting surface side of the mounting flange 1e, a flange having a substantially convex cross section is provided.
12A is mounted, and is fixed to the mounting flange 1e with a plurality of bolts 16 to compress the O-ring 13 and is air-tightly fixed.

The polymer bushing 2A has a cylindrical inner insulating tube 14 made of glass fiber reinforced epoxy resin having a small diameter at the tip, and a continuous fold of silicone resin inserted around the inner insulating tube 14 and inserted around the inner insulating tube 14. And a cylindrical outer insulating tube 15 formed in the shape shown in FIG. This polymer bushing 2A is made of a conventional porcelain bushing 2C shown in FIG.
It is significantly lighter (35kg / piece) compared to.

The outer periphery of the lower end of the inner insulating tube 14 is press-fitted and joined to the inner periphery of the flange 12A.
Is in contact with the upper end surface of the flange 12A. On the outer periphery of the lower end of the outer insulating cylinder 15 and the outer periphery of the upper end of the flange 12A,
A semiconductive layer 18 is applied, and the upper end of the semiconductive layer 18 reaches a curved surface at the base end of a fold 15 a formed at the lower end of the outer insulating cylinder 15.

In the gas insulated metal closed type switchgear configured as described above, the depth dimension of the outer shape in the side view of FIG. 1 is L ₀ and the height is H ₀ , which is the outer shape at the time of packing. The height from the folding point A formed by the center conductor 10 of the polymer bushing 2A at the center in the depth direction of the conductor chamber 1b to the installation surface of the box ₁ is indicated by H1.

FIG. 3 is a view showing a state in which the inclination angle of the polymer bushing 2A in FIG. 1 is changed by 20 ° to maintain an insulation distance between the charged portion at the tip of the polymer bushing 2A and the ground potential portion of the jacket of the box 1. 6 is a graph showing changes in the height H ₀ and the depth L ₀ .

As shown in FIG. 3, the curve representing the height H ₀ and the curve representing the depth L ₀ intersect at an angle θ of 20 °, and under this condition, the ratio of the magnitudes becomes minimum. Further, the depth L ₁ to the center and front door of the main circuit equipment room 1a, the ratio of the depth L ₂ until the rear end of the cable chamber 1c is 1: Since the 1.5, the polymer bushing 2A projecting forwardly Even if the weight is included, the deviation of the center of gravity in the front-rear direction is small, and the operation for lifting with a rope is easy.

The lower T-shaped bushing 8A of the high-pressure crosslinked polyethylene cable 9 is fixed to the box 1 side, and the upper T-shaped bushing 8B is mounted to the transformer 3 side.
Since these are connected by the high-pressure cross-linked polyethylene cable 9, installation errors in the vertical and horizontal directions of the front and rear devices can also be absorbed.

Further, upper and lower T-shaped bushings 8A, 8B
By removing the insulation plug 8a and connecting a cable for withstand voltage test, the withstand voltage of the main circuit can be easily measured.

The inner peripheral surface of the flange 12A at which the electric field strength is increased at the mounting portion of the polymer bushing 2A is alleviated by a small-diameter through hole 1f formed in the mounting flange 1e. Is relaxed by the chamfers of the curvatures R ₁ and R ₂ .

The formation of the semiconductive layer 18 causes the ground potential to move upward, and the upper end of the semiconductive layer 18 covers the curved surface of the base of the fold 15a at the lower end of the outer insulating cylinder 15. The electric field at the upper end can be reduced. As a result, partial concentration of the electric field can be prevented as indicated by a plurality of equipotential lines 17 shown by broken lines in FIG.

Next, FIG. 4 is a partially enlarged sectional view of a polymer bushing 2B showing a second embodiment of the gas insulated metal closed type switchgear of the present invention, and corresponds to FIG.
FIG. 4 is different from FIG. 3 in the cross-sectional shape of the upper end of the flange 12B, and the inside is chamfered in an arc shape.

The flange 12B having the upper end formed as described above
Can reduce the electric field inside the upper end of the flange 12B, which increases the electric field strength, suppress the increase in the outer shape of the polymer bushing, and reduce the weight. .

[0044]

As described above, according to the invention corresponding to the first aspect, the gas insulated metal closure in which the insulating bushing connected to the high-voltage equipment inside the box through the center conductor protrudes from the upper part of the box. In the switchgear type, the insulation bushing is mounted at an angle of 20 ° with the tip facing upward to the installation surface, minimizing the increase in the outer shape due to the insulating bushing. A gas-insulated metal-closed switchgear which can solve the problem can be obtained.

According to the invention corresponding to claim 2,
An insulated bushing protrudes from one side of the upper part of the box, and a cable room for storing cables and connectors connected to the outside of the box via the high-voltage equipment from the insulated bushing is arranged on the other side of the box, so that the wire Since the imbalance in the position of the center of gravity during lifting by a rope or the like is alleviated, it is possible to obtain a gas-insulated metal closed switchgear that can reduce the outer shape and solve problems such as transportation and gas replacement.

Further, according to the third aspect of the present invention, the insulating bushing includes a mounting flange fixed to the outer surface of the mounting portion and having an inner diameter larger than a through hole of the center conductor formed in the mounting portion. A resin inner pipe having a lower end inserted into the inner circumference of the flange, an outer pipe inserted outside the inner pipe and formed on the outer circumference of a plurality of folds, and an outer circumference at a lower portion of the outer pipe and an upper portion of the mounting flange; By forming an insulating bushing with the ground coating formed on the surface, the size of the insulating bushing can be reduced by improving the withstand voltage characteristics of the insulating bushing. An insulated metal closed switchgear can be obtained.

[Brief description of the drawings]

FIG. 1 is a right side view showing a first embodiment of a gas-insulated metal closed switchgear of the present invention.

FIG. 2 is an enlarged sectional view showing a mounting portion of the polymer bushing shown in FIG.

FIG. 3 is a graph showing the operation of the gas-insulated metal closed switchgear of the present invention.

FIG. 4 is a partially enlarged cross-sectional view showing a second embodiment of the gas insulated metal closed switchgear of the present invention.

FIG. 5 is a right side view showing an example of a conventional gas insulated metal closed switchgear.

[Explanation of symbols]

1, 21 ... box, 2A, 2B ... polymer bushing, 3 ...
Power receiving transformer, 4 ... Lightning arrester, 5 ... Current transformer, 6 ... Disconnector with grounding device, 7A, 7B ... Connection conductor, 8A, 8b ... T-shaped bushing, 9 ... High-pressure cross-linked polyethylene cable, 10 ... Central conductor, 11 … Cable support, 12A, 12B… Flange, 13…
O-ring, 14: inner insulating cylinder, 15: outer insulating cylinder, 16: bolt, 17: equipotential line, 18: semiconductive layer.

Claims (3)

[Claims] An insulated bushing connected to a high-voltage device inside a box via a central conductor is provided on a gas-insulated metal closed switchgear protruding from an upper portion of the box. A gas-insulated metal closed switchgear, wherein the insulating bushing is mounted at an angle of 20 ° with its tip facing upward. 2. A cable and a connector for projecting the insulating bushing on one side of an upper portion of the box, and connecting the other side of the box to a cable connected to the outside of the box from the insulating bushing via the high-voltage device. The gas insulated metal closed type switchgear according to claim 1, wherein a cable chamber for accommodating the gas is disposed. 3. A mounting flange fixed to an outer surface of the mounting portion and having an inner diameter larger than a through hole of the center conductor formed in the mounting portion, and a lower end formed on an inner periphery of the mounting flange. An inner tube made of a resin to be inserted, an outer tube inserted outside the inner tube and formed around a plurality of folds, and a ground covering formed on a lower portion of the outer tube and an outer periphery of an upper portion of the mounting flange. The gas insulated metal closed switchgear according to claim 1 or 2, wherein the switchgear is configured as follows.