JPH0644116U - Gas insulated current transformer - Google Patents

Abstract

(57) [Abstract] [Purpose] To prevent the insulating spacers provided to support the secondary coil unit of the current transformer from being damaged by the hot gas generated during an internal arc accident. [Structure] A spacer fitting 21 is interposed between a flange portion 14a of an insulating spacer 14 that supports a secondary coil unit 10 and a flange plate 4 that fixes the flange portion 14a.
The insulating spacer 14 is floated from the flange plate 4 to form a gas flow path between the insulating spacer and the flange plate. The valve body 25 is slidably inserted into the gas flow path, and the valve body 25 is biased radially inward by a return spring. Due to the valve body 25 and the return spring, the pressure in the porcelain insulator 2 is adjusted to the head container 3
A check valve device 26 that opens only when the internal pressure is higher than the internal pressure is configured.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a gas-insulated transformer in which a transformer main body is housed in a container in which insulating gas is sealed.

[0002]

[Prior art]

The gas-insulated current transformer includes a primary conductor, a ring-shaped iron core surrounding the primary conductor, and a secondary coil unit including a secondary coil wound around the iron core, and an insulating gas such as SF ₆ gas. It is stored in an enclosed container. Usually, the secondary coil is arranged in the shield case, and the potential of the shield case is fixed to the ground potential.

FIG. 8 shows a conventional current transformer of this type. In FIG. 8, 1 is a base metal fitting, 2 is a resin porcelain tube whose lower end is fixed to the base metal fitting, and 3 is an upper end of the porcelain insulation tube 2. A bell-shaped conductive head container mounted in a state of lying down on a fixed conductive flange plate 4. An insulator shell 2, a head container 3, and a flange plate 4 constitute an outer shell container 5. ing. A conductive secondary lead storage pipe 6 extending along the axial direction of the porcelain bushing is arranged at the center of the porcelain bushing 2, and the lower end of this pipe is connected to the base metal fitting 1 to maintain the ground potential. Is dripping

Reference numeral 7 denotes a primary conductor provided so as to cross the inside of the pressure vessel 3 along a direction orthogonal to the central axis of the porcelain bushing. The primary conductor 7 is provided in a state of penetrating a hole provided in the side wall of the head container 3, and one end of the primary conductor is connected to the head container 3 via an annular support ring 8 made of a conductor. It is supported so that the potential of the head vessel 3 is fixed to the potential of the primary conductor 7. The other end of the primary conductor 7 is supported by the head container 3 via an insulating spacer 9. External terminal fittings 7A and 7B are attached to both ends of the primary conductor 7.

Reference numeral 10 denotes a secondary coil unit. In this secondary coil unit, a secondary coil 12 wound around a ring-shaped iron core 11 surrounding the primary conductor 7 is housed in a shield case 13 together with the iron core 11. It has a known structure. This secondary coil unit is supported by a penetrating conductor 15 of a cone-shaped insulating spacer 14 arranged at the boundary between the gas space in the porcelain tube 2 and the gas space in the head container 3.

The insulating spacer 14 has a flange portion 14 a fixed to the flange plate 4 in the head container 3. A gap is formed between the flange portion 14a of the insulating spacer 14 and the flange plate 4, and the gas space in the head container 3 and the gas space in the porcelain tube 2 are communicated with each other through the gap.

The through conductor 15 of the insulating spacer 14 is formed in a cylindrical shape, and the upper end of the secondary lead storage pipe 6 is inserted and connected inside the through conductor 15. The secondary lead pulled out from the secondary coil 12 of the secondary coil unit 10 is introduced into the secondary terminal box 17 provided inside the base metal fitting 1 through the secondary lead storage pipe 6. . The base metal fitting 1 is connected to the ground potential portion through the ground terminal 18.

An electric field mitigating shield cylinder 19 is provided so as to concentrically surround the vicinity of the upper end of the secondary lead storage pipe 6 inside the insulator tube 2. This electric field mitigating shield cylinder electrically connects to the head container 3. It is connected.

SF ₆ gas is sealed in the porcelain insulator 2 and the head container 3 at a predetermined pressure, and the gas causes a space between the primary conductor 7 and the secondary coil unit 10 and between the head container 3 and the secondary container. The coil unit 10 is insulated from the coil unit 10. The head container 3 and the primary conductor 7 are insulated from the ground by the insulator 2 in the air.

A pressure relief plate 20 is attached to the upper part of the head container 3, and when a rated overcurrent (fault current) flows for a prescribed time and the pressure in the head container 3 exceeds a predetermined value, the pressure release plate 20 is released. The pressure plate 20 is broken to release the pressure in the head container.

[0011]

[Problems to be solved by the device]

 In the above gas-insulated current transformer, when an internal arc accident occurs, if the fault current is smaller than the rated overcurrent and the accident duration is shorter than the specified time, the energy is insufficient and the pressure relief plate A situation occurs in which 20 does not operate. When such a situation occurs, the gas heated to a high temperature comes into contact with the synthetic resin insulator for a long time, and the resin having a low melting point is softened or melted, so that the head container 3 can be supported. There was a risk that the head container would fall out.

An object of the present invention is to provide a gas-insulated current transformer in which the porcelain insulator is not exposed to high temperatures for a long time when an internal arc accident occurs.

[0013]

[Means for Solving the Problems]

 The present invention comprises an insulator tube, a head container fixed to the upper end of the insulator tube, an insulating spacer provided at the boundary between the gas space inside the head container and the gas space inside the insulator tube, and inside the head container. The present invention relates to a gas-insulated current transformer equipped with a secondary coil unit supported by a through conductor of an insulating spacer. In the present invention, a gas space in a porcelain tube and a gas space in a head container are provided. , It was made to communicate via a check valve device that opens only when the pressure of the gas space in the insulator tube is higher than the pressure of the gas space in the head vessel.

[0014]

[Action]

 In the above gas-insulated current transformer, when an internal arc accident occurs on the porcelain insulator side, the pressure inside the porcelain insulator rises, so the check valve device opens, causing a high temperature gas to flow from the porcelain insulator into the head vessel. . The high temperature gas flowing into the head vessel is blocked by the check valve device, so it does not flow back into the insulator. Therefore, the porcelain insulator is not exposed to the high temperature gas for a long time.

When an internal arc accident occurs in the head container, high-temperature gas is generated in the head container, but this high-temperature gas is blocked by the check valve device and flows into the porcelain tube. There is no such thing.

As described above, according to the present invention, when an internal arc accident occurs, the porcelain insulator is not exposed to high temperature hot gas for a long time. It is possible to prevent the support strength of the head container from being lowered by softening or melting of the porcelain tube.

[0017]

【Example】

 FIG. 1 shows the overall construction of an embodiment of the present invention. In FIG. 1, parts that are the same as the parts of the conventional current transformer shown in FIG. 8 are given the same reference numerals.

In this embodiment, as shown in FIG. 2, the lower surface of the flange portion 14 a of the insulating spacer 14 and the flange plate 4 fixed to the upper end of the porcelain insulator 2 are arranged at equal angular intervals. A plurality of strip plate-shaped spacer fittings 21 are inserted, and a gap is formed between the insulating spacer 14 and the flange plate 4 by these spacer fittings. At the position corresponding to each spacer metal fitting 21 on the upper surface of the flange portion 14a of the insulating spacer, a strip-shaped pressing metal fitting 22 is brought into contact, and as shown in FIG. A bolt 23 penetrating through and is screwed into a screw hole 4a provided in the flange plate 4. A collar 24 is fitted to a portion of the bolt 23 located between the holding metal fitting 22 and the spacer metal fitting 21, and the collar 24 holds the space between the holding metal fitting 22 and the spacer metal fitting 21. The pressing fitting 22 and the spacer fitting 21 are fastened together by the bolts 23 and fastened to the flange plate 4, whereby the insulating spacer 4 is fixed to the flange plate 4.

The gap between the flange portion 14a of the insulating spacer 14 and the flange plate 4 is divided into a plurality of fan-shaped gas flow paths 30, 30, ... (See FIG. 5) by a plurality of spacer fittings 21, 21 ,. A fan-shaped plate-shaped valve element 25 is inserted into each fan-shaped gas flow path so as to fit in the gas flow path without a gap and is slidable in the radial direction. Each valve body 25 is urged inward in the radial direction by a return spring (not shown), and normally the urging force of the return spring causes each valve body 25 to move between the flange portion of the insulating spacer 14 and the flange plate 4. The gas flow path 30 is held at a position (closed position). A check valve device 26 is configured by each valve element 25 and a return spring (not shown) that returns each valve element to the closed position.

The return spring may be a tension spring arranged on the inner peripheral side of each valve element or a compression spring provided on the outer peripheral side of each valve element.

Although not particularly shown in the drawings, it is preferable to provide a stopper that regulates the amount of radial displacement of each valve element. This stopper can be provided, for example, on a part of the spacer fitting 21.

Other points are the same as the conventional gas-insulated current transformer shown in FIG.

In the gas insulated current transformer of the present embodiment, as shown in FIG. 4, if an internal arc accident occurs at the portion A between the electric field mitigation shield 19 and the secondary lead storage pipe 6, the arc is generated. As a result, the gas inside the porcelain insulator 2 is heated and its pressure rises. Since this pressure acts on each valve element 25 from the inside, each valve element 25 is displaced radially outward as shown by the chain line in FIG. Are allowed to flow into the head container 3. When the gas flows into the head container 3, the valve body 25 returns to the closed position, so that the high-temperature gas once flowing into the head container does not return to the insulator tube 2. Therefore, it is possible to prevent the porcelain insulator 2 from being exposed to the high temperature gas for a long time, and it is possible to eliminate the possibility that the porcelain insulator made of resin is softened or melted and the head container is dropped.

Further, as shown in FIG. 6, when an internal arc accident occurs in, for example, the part B between the shield case 13 and the primary conductor 7 in the head container 3, the gas in the head container 3 is discharged. The pressure rises due to heating, but at this time, the pressure acts on each valve element 25 from the outside in the radial direction as shown by the arrow in FIG. 7, so that each valve element 25 is held in the closed position. There is up to. Therefore, the hot gas in the head container 3 is prevented from flowing into the porcelain bushing 2, and the porcelain bushing is prevented from being exposed to the hot gas.

As described above, the gas space in the porcelain insulator 2 and the gas space in the head container 3 are opened only when the pressure of the gas space in the insulator pipe is higher than the pressure of the gas space in the head container. If the check valve device 26 is used for communication, the arc energy at the time of an internal arc accident is not large until the pressure relief plate 20 is operated, so that high temperature gas heated by the arc may occur inside. When this occurs, the high-temperature gas will remain in the head container having sufficient heat resistance, not in the resin-made insulator tube, so it is possible to prevent the insulator tube from softening or melting. .

The way of providing the check valve device is not limited to that shown in the above embodiment, but the pressure of the gas space in the porcelain tube is higher than the pressure of the gas space in the head vessel. It may be opened occasionally to allow the gas in the porcelain tube to flow into the head vessel. For example, a hole may be provided in the insulating spacer 14 and a check valve may be attached so as to close the hole.

In the above embodiments, the cone-shaped (cone-shaped) insulating spacer is used, but the present invention can be similarly applied to the case where the disk-shaped insulating spacer is used.

[0028]

[Effect of device]

 As described above, according to the present invention, when an internal arc accident occurs, it is possible to prevent the insulator tube from being exposed to high temperature gas for a long time. There is an advantage that the supporting strength of the head container can be prevented from being deteriorated by softening or melting.

[Brief description of drawings]

FIG. 1 is a vertical sectional view showing an embodiment of the present invention.

FIG. 2 is a perspective view showing an insulating spacer used in an embodiment of the present invention and a valve body of a check valve device interposed between the insulating spacer and a flange plate.

FIG. 3 is a cross-sectional view showing a mounting structure of an insulating spacer according to an embodiment of the present invention.

FIG. 4 is a cross-sectional view of an essential part for explaining the operation when an internal arc accident occurs in the porcelain bushing in the embodiment of the present invention.

FIG. 5 is an explanatory view for explaining the operation of the check valve device when an internal arc accident occurs in the porcelain bushing in the embodiment of the present invention.

FIG. 6 is a sectional view of relevant parts for explaining the operation when an internal arc accident occurs in the head container in the embodiment of the present invention.

FIG. 7 is an explanatory view illustrating the operation of the check valve device when an internal arc accident occurs in the head container in the embodiment of the present invention.

FIG. 8 is a cross-sectional view showing a conventional gas-insulated current transformer.

[Explanation of symbols]

 1 Base Metal Fitting 2 Insulator Pipe 3 Head Container 4 Flange Plate 6 Secondary Lead Storage Pipe 7 Primary Conductor 10 Secondary Coil Unit 14 Insulating Spacer 15 Through Conductor 21 Spacer Metal Fitting 22 Pressing Metal Fitting 23 Bolt 24 Color 25 Valve Body 26 Check Valve apparatus

Claims (1)

[Scope of utility model registration request] 1. A porcelain insulator, a head container fixed to an upper end of the porcelain insulator, an insulating spacer provided at a boundary portion between a gas space in the head container and a gas space in the porcelain insulator, and the head. A gas-insulated current transformer having a secondary coil unit supported by a penetrating conductor of the insulating spacer in a container, wherein the gas space in the porcelain pipe and the gas space in the head container are The gas-insulated current transformer is characterized in that it is connected through a check valve device that opens only when the pressure in the container is higher than the pressure in the gas space in the head vessel.