KR20040081810A - Gas-insulated switchgear - Google Patents

Abstract

In order to solve the problem of heat dissipation, deviation in each phase of breaking performance, manufacturing yield, airtightness, standardization of bushing, and deterioration of production efficiency, the insulating frame supporting the vacuum breaker of gas insulated switchgear is used as the insulating cylinder. And an opening for vertically penetrating the insulating cylinder near the movable portion of the vacuum valve. In addition, the main circuit part of the disconnector which has a grounding switch is arrange | positioned so that the positional relationship with a vacuum valve may be equal to one of the upper and lower sides of the insulation cylinder of each phase, and the three phase insulation spacer of the upper surface of a tank should be set separately each phase. It arrange | positioned shifting back, front, left, and right centers about a phase bushing, and the bushing of a tank lower part was made into the bushing which has a length enough to provide a current transformer outside a tank.

Description

Gas Insulated Switchgear {GAS-INSULATED SWITCHGEAR}

For example, in the conventional gas insulated switchgear described in Unexamined-Japanese-Patent No. 11-185577, the tank is provided across the base on the base. The tank has a shape in which the lower portion of the front side is notched, an opening is formed in the front side of the tank, and the opening is closed by an attachment plate. The inside of the tank is airtight and filled with insulating gas. One end of a substantially U-shaped insulating frame having a cross section made of a solid insulator is attached to the inside of the attachment plate, and a vacuum circuit breaker is attached to the inside of the insulating frame as a switch. In addition, above the insulating frame, disconnectors having grounding swtiches as switchgear are provided. On the outer side of the attachment plate, an operation unit for operating a vacuum breaker and an operation unit for operating a disconnecting device having a grounding switch are provided.

Bus bars are arranged above the tank. An opening is formed in the upper surface of the tank, and a three-phase insulating spacer as an insulating member that closes the opening is hermetically provided. This three-phase insulating spacer is a molded three-phase internal conductor molded from a solid insulator. The upper end of the inner conductor is connected to the bus bar, and the lower part is connected to the disconnector having a grounding switch.

The lower part of a tank is provided with three phases of the composite type bushing which embedded the internal conductor and the current transformer in the bushing which is a solid insulator. This bushing is hermetically attached from the inside with an O-ring interposed in the opening of the tank. A cable head is attached to this bushing from the front side of the gas insulated switchgear. The vacuum breaker and the inner conductor of the bushing are connected via a conductor, and a power cable is connected to the cable head.

In the conventional gas insulated switchgear, since the cross section of the insulating frame supporting the vacuum breaker is U-shaped, reinforcement measures are required such as increasing the thickness of the end portion, and the vacuum breaker portion is generated. There is a problem that heat is difficult to radiate.

Moreover, since the main circuit part of each phase of the disconnecting switch which has a grounding switch is arrange | positioned in the depth direction in the vicinity of a breaker, the interruption | blocking part between the vacuum switches of the electromagnetic system accompanying a fault current energization for each phase is carried out. Because of the different influence on the circuit, there is a problem that the breaking performance of the vacuum circuit breaker is disturbed according to each phase.

In addition, the three-phase insulating spacer attached to the upper surface of the tank has a complicated shape, resulting in poor yields on the manufacturing side, and the flange surface is wide, so that the planar surface must be secured extensively on the tank side to maintain the airtight performance. It is.

Moreover, since the bushing provided in the lower part of a tank embeds a current transformer, it becomes complicated and large, the manufacturing yield is bad, and workability is also bad. In addition, it is necessary to meet the specifications of the current transformers that vary from customer to customer, which is a cause of deterioration of the bushing standardization and production efficiency.

The present invention relates to a structure of a gas insulated switchgear.

1 is a side sectional view showing a first embodiment of a gas insulated switchgear of the present invention;

Fig. 2 is a side sectional view showing Embodiment 2 of a gas insulated switchgear of the present invention.

3 is a side sectional view showing Embodiment 3 of a gas insulated switchgear of the present invention;

4 is a side sectional view showing Embodiment 4 of a gas insulated switchgear of the present invention;

MEANS TO SOLVE THE PROBLEM In order to solve the subject mentioned above, according to the gas insulated switchgear of this invention, the metal container which sealed the insulating gas, the bus side side bushing supported by the metal container, and to be connected to an external circuit, and the container wall inside a metal container A vacuum circuit breaker having an insulating frame supported at one end, a movable side terminal supported by the insulating frame and connected to an insulating rod extending through one end of the insulating frame, and a fixed side terminal supported at the other end of the insulating cylinder. A gas having a rotatable blade provided, a disconnector connected between the busbar side bushing and the vacuum breaker, a cable head connected to the vacuum breaker and connected to the power cable, and a current transformer for measuring the current flowing through the cable head In the insulated switchgear, the cross-sectional shape of the surface in which the insulating frame is perpendicular to the axial direction is annular. A gas insulated switchgear having a cylindrical shape and having an opening for connecting the movable terminal of the vacuum breaker to the disconnector can be obtained.

Furthermore, even with a flexible conductor that penetrates the insulated cylinder and connects the movable terminal to the blade, the main circuit conductor, including the busbar side bushing and disconnector, is almost perpendicular to the axis of the vacuum breaker. Even if it is in surface, bus-side bushing may mutually shift | deviate from phase to phase in the depth direction and the width direction of a gas insulated switchgear, or a current transformer may be a separate part from a cable head.

Embodiment 1

As shown in FIG. 1, in the gas insulated switchgear of this invention, the tank 3 is provided on the mount 2 comprised by the thin metal plate. The front face of the tank 3 is in the notched shape. An opening is formed in the front surface of the tank 3, and the opening is closed by the attachment plate 4, the inside of the tank 3 is airtight and filled with insulating gas.

One side of the insulating cylinder 18 which consists of a solid insulator is attached to the inside of the attachment plate 4 so that the space | interval of the main circuit part of the circuit breaker 6 may be 5 mm or more, and inside the insulating cylinder 18, a vacuum valve ( 19) and the flexible conductor 22 which connects between the movable shaft 20 of the vacuum valve 19, and the blade support terminal 21 for disconnectors which have a grounding switch so that the operation of the movable shaft 20 may not be impaired. The insulating rod 23 which insulates the circuit breaker main circuit part, etc., the movable shaft 20 of the vacuum valve 19, and the operation part 8 for circuit breakers, and the movable shaft 20 of the insulating rod 23 and the vacuum valve 19. The instrument parts such as the adapter 24 for connecting the cable are stored. In addition, a disconnecting device 7 having a grounding switch is provided on the insulating cylinder 18. And the outer side of the attachment plate 4 is provided with the operation part for circuit breakers 8 and the disconnecting part operation part 9 which has a grounding switch.

On the side opposite to the attaching plate 4 of the insulating cylinder 18, the fixed side terminal 25 of the vacuum valve is attached through the fixed terminal 26, and the upper insulating cylinder 18 protrudes upward and the ground breaker The inlet-side terminal 27 of the disconnector having the upper end is attached, and the blade supporting terminal 21 of the disconnector protruding smaller than the protruding portion and having the grounding switch is attached above the vacuum valve movable shaft 20 of the insulating cylinder 18. It is. Moreover, the opening part 28 is provided in the side of the attachment plate 4 of a small protrusion part, and penetrates the insulating cylinder 18, and the movable shaft 20 of a vacuum valve penetrates this opening part 28. It is connected to the blade support terminal 21 of the disconnecting device which has a ground switch.

Above the insulating cylinder 18 of the attachment plate 4, an opening is formed in each phase at the same pitch as the insulating cylinder 18, and the test terminal and the ground terminal 29 as an insulating member which closes the said opening airtight are provided. have. The test terminal and the ground terminal 29 have an inner conductor 29a embedded in the center thereof, and a mounting bracket 30 for attachment to the tank is embedded on the circumference of the inner conductor 29a. Outside the c), a recess 31 for attaching a packing for airtight attachment to the tank is provided around the inner conductor 29a. The tank inner end of the inner conductor 29a is connected to the ground terminal 32 of the disconnecting unit having the ground switch, and the tank outer end is connected to the ground terminal. In the circumference of the opening above the insulating cylinder 18 of the said attachment plate 4, it has a small hole for attachment of the test terminal and the grounding terminal 29 on the circumference which has the same center as the center of the said opening, The terminal 29 is inserted into the opening from the inside of the tank, and the bolt 33 which penetrates the attachment hole from the outside of the tank is inserted into the mounting bracket 30 and fastened.

An opening is formed on the upper surface of the tank 3 at a pitch equal to that of the insulating cylinder 18 above each insulating cylinder 18 and slightly larger than the outer diameter of the busbar 10 and shifted in the front-rear direction. A single-phase bushing 34 for a bus bar, which is formed, and which closes the opening in an airtight manner, is provided. In this single-phase bushing 34, an inner conductor 34a is buried in the center, a mounting bracket 35 for attaching to the tank 3 is embedded on a circumference centering on the inner conductor 34a, and an attachment bracket 35 is provided. On the outer side of the inner side of the inner conductor 34a is provided a recess 36 for attaching a packing for airtight attachment to the tank. The tank inner end of the inner conductor 34a is connected to the inlet side terminal 27 of the disconnecting unit having the grounding switch via the connecting conductor 38, and the tank outer end is connected to the bus bar 10. Around the opening of the tank upper surface, there is a small hole for attaching the single-phase bushing 34 on the circumference having the same center as the center of the opening, and the single-phase bushing 34 is inserted into the opening from the inside of the tank, and the outside of the tank. The bolt 37 which penetrated the attachment hole from the said hole is inserted into the said mounting bracket, and it fastens.

In the lower part of the front surface of the tank 3, openings are formed at the same pitch as the insulating cylinder 18 below each insulating cylinder 18, and the single-phase bushing for cable connection as an insulating member which closes the opening in an airtight manner. 39 is provided. In this single-phase bushing 39, the inner conductor 39a is buried in the center, the mounting bracket 40 is attached to the tank 3 on the circumference centering on the inner conductor 39a, and the mounting bracket 40 is attached. On the outer side of the inner side of the inner conductor 39 is provided a recess 41 for attaching a packing for hermetic attachment to the tank. The tank inner end of the inner conductor 39 is connected to the fixed terminal 26 of the circuit breaker via the connecting conductor 42, and the tank outer end is connected to the power cable 17 via the cable head 15. . Around the opening of the lower part of the front face of the said tank 3, it has the small hole for attaching the single phase bushing 39 on the circumference which has the same center as the center of the said opening, and the single phase bushing 39 is connected to the opening from the inside of a tank. The bolt 42 which penetrated the attachment hole from the tank outer side is inserted into the said mounting bracket, and it fastens.

In the gas insulated switchgear of this embodiment, since the insulating frame which supports a vacuum circuit breaker is a cylindrical body, and has an opening part, reinforcement measures, such as increasing the thickness of an edge part, are unnecessary as usual, and a vacuum circuit breaker part is not necessary. The heat dissipation of heat generated in can be efficiently performed. In addition, since the main circuit conductor including the busbar side bushing and the disconnector is in a nearly vertical plane including the axis of the vacuum breaker, the breaking performance of the vacuum breaker for each phase becomes equal. In addition, since the busbar side bushings are shifted from phase to phase in the depth direction and the width direction of the gas insulated switchgear, the shape of the insulating spacer attached to the tank upper surface can be simplified, and the production yield and airtight performance can be easily maintained. It can be done. In addition, since the current transformer is a separate part from the cable head, the manufacturing yield is good, the workability is good, and the specification of the current transformer can be easily changed for each customer.

Embodiment 2

Next, Embodiment 2 is demonstrated based on FIG. As can be seen by comparing FIG. 2 with FIG. 1, the blade support terminal 21 and the fixed terminal 26 of the disconnecting device having the grounding switch without the circuit breaker inside the insulated tube and the short circuit conductor 45 are connected to the switch. We are connected without passing through.

Embodiment 3

Next, Embodiment 3 will be described based on FIG. 3. As can be seen by comparing FIG. 3 with FIG. 2, the positions of the disconnecting tube 7 having the insulating cylinder 18 and the ground switch are reversed up and down without changing the mutual positional relationship, and the fixed terminal of the circuit breaker ( 26 is connected to the single-phase bushing 34 on the upper surface of the tank via the connecting conductor 46, and the inlet-side terminal 27 of the disconnecting unit having the grounding switch is connected to the single-phase bushing under the tank front by the connecting conductor 47. (39). Moreover, although the state which connected the instrument transformer 47 instead of the power cable 17 is shown to the single-phase bushing 39 of a tank front lower part, a power cable, an arrester, etc. can also be connected in the same structure.

Embodiment 4

Next, Embodiment 4 will be described with reference to the drawings. As can be seen by comparing FIG. 4 with FIG. 1, the single-phase bushing 39 at the bottom of the tank is attached to the back side, and the power cable 17 is connected to the single-phase bushing 39 from the back side of the gas insulated switchgear. It is. In the figure, although the electric power cable 17 is led in from the upper side of the gas insulated switchgear, it can be connected also when the electric power cable 17 is led in from the lower side.

As described above, according to the gas insulated switchgear of the present invention, by making the insulator containing the main circuit portion of the circuit breaker circular or elliptical, the stress in the insulator can be dispersed and the thickness of the insulator can be realized. In addition, by providing a projecting portion in the insulator, it is possible to shorten the assembly time without needing an extra bracket for attaching each terminal of the disconnecting device having a grounding switch, and by providing a through hole in a part of the insulated tube, Heat generated inside can be easily radiated out of the insulated tube, and a large current can be supplied even with the same conductor size.

The gas insulated switchgear of the present invention is an annular cylindrical body having a cross-sectional shape of a surface in which the insulating frame is perpendicular to the axial direction, and has an opening for connecting the movable terminal of the vacuum circuit breaker to the disconnecting device. It is possible to disperse the internal stress and to reduce the thickness of the insulating frame, to attach a disconnecting device having a grounding switch to the insulating frame, and to provide a through hole in a part of the insulating frame, thereby facilitating heat generated in the insulating frame. The heat can be radiated to the outside, and a large current can be supplied even with the same conductor size.

Claims (20)

A metal container sealed with an insulating gas, A bus side bushing supported by the metal container and to be connected to an external circuit; An insulating frame supported at one end on the container wall in the metal container; A vacuum circuit breaker having a movable side terminal supported by the insulating frame and connected to an insulating rod extending through the one end of the insulating frame and a fixed side terminal supported at the other end of the insulating cylinder; A disconnecting unit having a rotatable blade provided in the insulating frame, and connected between the bus bar side bushing and the vacuum breaker; A cable connected to the vacuum breaker and connectable to a power cable; In the gas insulated switchgear having a current transformer for measuring the current flowing through the cable head, The said insulating frame is a cylindrical body, The gas insulation switchgear provided with the opening part for connecting the movable terminal of the said vacuum circuit breaker to the said disconnector. The method of claim 1, A gas insulated switchgear, further comprising a flexible conductor that penetrates the insulating cylinder and connects the movable terminal to the blade. The method of claim 1, And a main circuit conductor comprising said busbar side bushing and said disconnector is in a substantially vertical plane comprising an axis of said vacuum breaker. The method of claim 1, The bus bar side bushing is shifted from phase to phase in the depth direction and the width direction of the gas insulated switchgear. The method of claim 1, And the current transformer is a separate part from the cable head. The method of claim 1, And a flexible conductor for connecting said movable terminal to said blade through said insulating cylinder, wherein said main circuit conductor comprising said busbar side bushing and said disconnector is in a substantially vertical plane including an axis of said vacuum circuit breaker. Featured gas insulated switchgear. The method of claim 1, And a flexible conductor for connecting the movable terminal to the blade through the insulating cylinder, wherein the busbar side bushing is shifted from phase to phase in the depth direction and the width direction of the gas insulated switchgear. Switch gear. The method of claim 1, And a flexible conductor connecting the movable terminal to the blade through the insulating cylinder, wherein the current transformer is a separate part from the cable head. The method of claim 1, And a main circuit conductor comprising the busbar side bushing and the shortener is in a substantially vertical plane comprising an axis of the vacuum circuit breaker, wherein the current transformer is a separate part from the cable head. The method of claim 1, And a flexible conductor for penetrating the insulated cylinder and connecting the movable terminal to the blade, wherein a main circuit conductor including the busbar side bushing and the disconnector is in a substantially vertical plane including an axis of the vacuum circuit breaker, And the current transformer is a separate part from the cable head. The method of claim 1, The bus bar side bushing is shifted from phase to phase in the depth direction and the width direction of the gas insulated switch gear, and the current transformer is a separate part from the cable. The method of claim 1, And a flexible conductor for connecting the movable terminal to the blade through the insulating cylinder, wherein the busbar side bushing is shifted phase by phase in the depth direction and the width direction of the gas insulated switchgear, and the current transformer is connected to the cable. A gas insulated switchgear, which is a separate part from the head. A metal container sealed with an insulating gas, A bus side bushing supported by the metal container and to be connected to an external circuit; An insulating frame supported at one end on the container wall in the metal container; A vacuum circuit breaker having a movable side terminal supported by the insulating frame and connected to an insulating rod extending through the one end of the insulating frame and a fixed side terminal supported at the other end of the insulating cylinder; A disconnecting unit having a rotatable blade provided in the insulating frame, and connected between the bus bar side bushing and the vacuum breaker; A cable head connected to the vacuum breaker and connectable to a power cable; In the gas insulated switchgear having a current transformer for measuring the current flowing through the cable head, And a main circuit conductor comprising said busbar side bushing and said disconnector is in a substantially vertical plane comprising an axis of said vacuum breaker. The method of claim 13, A gas insulated switchgear, further comprising a flexible conductor that penetrates the insulating cylinder and connects the movable terminal to the blade. The method of claim 13, And the current transformer is a separate part from the cable. The method of claim 13, And a flexible conductor connecting the movable terminal to the blade through the insulating cylinder, wherein the current transformer is a separate part from the cable head. A metal container sealed with an insulating gas, A bus side bushing supported by the metal container and to be connected to an external circuit; An insulating frame supported at one end on the container wall in the metal container; A vacuum circuit breaker having a movable side terminal supported by the insulating frame and connected to an insulating rod extending through the one end of the insulating frame and a fixed side terminal supported at the other end of the insulating cylinder; A disconnecting unit having a rotatable blade provided in the insulating frame, and connected between the bus bar side bushing and the vacuum breaker; A cable head connected to the vacuum breaker and connectable to a power cable; In the gas insulated switchgear having a current transformer for measuring the current flowing through the cable head, The bus bar side bushing is shifted from phase to phase in the depth direction and the width direction of the gas insulated switchgear. The method of claim 17, A gas insulated switchgear, further comprising a flexible conductor that penetrates the insulating cylinder and connects the movable terminal to the blade. The method of claim 17, And a flexible conductor connecting the movable terminal to the blade through the insulating cylinder, wherein the current transformer is a separate part from the cable head. The method of claim 17, And the current transformer is a separate part from the cable.