JPH04127631U - gas insulated current transformer - Google Patents

Abstract

(57) [Summary] [Purpose] To prevent dielectric breakdown that occurs between the shield case housing the secondary coil and the primary conductor from spreading to the secondary coil. [Structure] The shield case 4 that houses the secondary coil 2,
A protective shield plate 2 is placed inside the part facing the primary conductor 1.
2 to fix the potential of the protective shield plate 22 to the potential of the shield case 4. The protective shield plate 22 is made of a nonmagnetic metal material that has a lower conductivity and a higher melting point than the metal that constitutes the shield case 4.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

The present invention is a gas-insulated transformer in which the main body of the current transformer is housed in a container filled with insulating gas. It is related to water vessels.

0002

[Conventional technology]

A gas-insulated current transformer is a current transformer body containing a primary conductor and a secondary coil wound around a ring-shaped core surrounding the primary conductor, which is placed inside a container filled with an insulating gas such as _SF6 gas. It is stored in. A shield case is provided around the secondary coil, and the potential of the shield case is fixed to ground potential. The shield case is made of a non-magnetic metal with high electrical conductivity, such as aluminum.

0003 Figure 3 shows the primary conductor, secondary coil, and shield case of a conventional current transformer of this type. In the figure, 1 is the primary conductor, and 2 is the ring-shaped iron surrounding the primary conductor 1. A secondary coil is evenly distributed around the core 3, and 4 constitutes a case surrounding the secondary coil 2. This is a shield case designed to In this example, shield case 4 is , consists of a resin case 4a and a conductive layer 4b covering the surface of the resin case.

0004 FIG. 4 shows another conventional example, in which the shield case 4 is a secondary coil. It consists of a single aluminum case that surrounds the main body.

[0005]

[Problem that the idea aims to solve]

In the gas insulated current transformer as described above, the shield case 4 and the primary conductor 1 are There is a weak point X in the insulation in the gap between may occur. If dielectric breakdown occurs in this part, the heat from the arc current will cause the As a result, the shield case melts and a hole opens, causing dielectric breakdown to the secondary coil. The secondary coil is damaged, and the system maintenance such as the relay connected to the secondary coil is There was a problem that the protection device could be damaged.

[0006] The purpose of this invention is to prevent dielectric breakdown that occurs in the gap between the shield case and the primary conductor. An object of the present invention is to provide a gas-insulated current transformer that prevents the current from spreading to the secondary coil. Ru.

[0007]

[Means to solve the problem]

The present invention consists of a primary conductor and a secondary conductor wound around an iron core surrounding the primary conductor. A gas comprising a secondary coil and a shield case provided to surround the secondary coil. It is related to an isolated current transformer, and in this invention, it is applied to the primary conductor of the shield case. The metal that makes up the shield case is placed on the inside of the facing part (the side facing the secondary coil). A protective shield plate made of non-magnetic metal with lower conductivity and higher melting point than metal is installed. However, the potential of the protective shield plate is fixed to the potential of the shield case.

[0008] Provide a gap between the above shield case and the protective shield plate, and fill the gap with quartz sand. It is also possible to fill with an arc extinguishing agent such as.

[0009]

[Effect]

In the above gas insulated current transformer, the gap between the shield case and the primary conductor When edge fracture occurs and an arc occurs, the shield case melts due to the heat of the arc. do. At this time, the energy of the arc is consumed by melting the shield case, and The protective shield plate placed inside the shield case is similar to the shield case. Because the melting point is high, the protective shield plate will melt in a very short time when the fault current flows. It never happens. Also, most of the ground fault current flows through the shield case, which has high conductivity. Therefore, the protective shield plate does not generate a large amount of heat. Therefore, as a protective shield plate Eliminates the risk of holes forming and the risk of dielectric breakdown spreading to the secondary coil. It can be eliminated.

0010 In addition, a gap is provided between the shield case and the protective shield plate, and an arc extinguisher is applied to the gap. When filled with arc extinguishing agent, the arc energy can be absorbed, so the arc can be maintained. This prevents the protective shield plate from melting and prevents the protective shield plate from melting. can be stopped.

[0011]

【Example】

1 and 2 show an embodiment of the present invention, in which 10 is a base; 11 is an insulator tube whose lower end is fixed on the base 10, and the inside of the insulator tube 11 is made of FRP. A cylindrical body 12 consisting of: 13 is a metal container fixed to the upper end of the insulator tube 11 An insulating spacer 14 is installed to partition the space inside the metal container 13 and the space inside the insulator tube 11. is provided. There is a gap between the flange of the insulating spacer 14 and the bottom of the container 13. A gap is formed to form a gas flow path, and the gas inside the container 13 is The space and the gas space within the insulator tube 11 are communicated with each other.

0012 A secondary lead storage pipe 15 made of aluminum or the like is arranged inside the insulator pipe 11. The lower end of the pipe is fixed to the base. The upper end of the pipe 15 has an insulating space. It is connected to the through conductor 16 of the sensor 14.

[0013] Inside the metal container 13, a hollow annular shield case 4 is arranged with its axis in the horizontal direction. The shield case 4 has a tubular through conductor of the insulating spacer 14. It is fixed to the body 16.

[0014] Inside the shield case 4, a ring-shaped iron core 3 is wound evenly in a toroidal manner. A plurality of secondary coils 2 (three in the illustrated example) are arranged side by side in the horizontal direction, The secondary lead wires drawn out from these secondary coils pass through the insulating spacer 14. It is provided in the base 10 through the hollow part of the conductor and the inside of the secondary lead storage pipe 15. It is led to the terminal board.

[0015] Inside the metal container 13, there is also a hole extending horizontally through the axial center of the shield case 4. A primary conductor 1 is housed therein. One end 1a of the primary conductor 1 is attached to the side wall of the container 13. The other end 1b of the primary conductor 1 is led out through the attached airtight lead-out part 17, and the other end 1b of the primary conductor 1 is It airtightly penetrates the insulating spacer 18 attached to the side wall of the container 13 and is led to the outside. has been done. The airtight lead-out portion 17 has conductivity, and one end 1a of the primary conductor 1 is connected to the airtight lead-out portion 17. It is electrically connected to the container 13 through the outlet 17. This causes the container 13 to become electrically charged. The potential of the primary conductor 1 is fixed. At one end 1a and the other end 1b of the primary conductor 1 are attached with primary terminals 19 and 20, respectively. At the top of the metal container 13 , a pressure relief device 21 is installed, and a predetermined amount of SF6 gas is installed in the container 13 and the insulator tube 11. sealed under pressure.

[0016] The shield case 4 is made of aluminum (melting point approximately 660°C), and in this example, As shown in FIG. 2, the inner side (2 An annular protective shield plate 22 along the inner surface of the shield case is arranged on the next coil side). It is placed. The protective shield plate 22 is made of metal that constitutes the shield case 4. The shield case 4 is made of a non-magnetic metal material with low conductivity and high melting point. are arranged concentrically with the shield case 4 and the protective shield plate 22. A gap g is formed. Both ends of the protective shield plate 22 in the axial direction are covered with a shield case. electrically and mechanically connected to the inner surface of the shield case 4 and the protective shield. Both plates 22 are held at ground potential. In this embodiment, the protective shield plate 22 is Made of stainless steel (melting point 1400℃).

[0017] In addition, in order to prevent the shield case from forming one turn surrounding the iron core, the seal An insulator 23 is provided in the middle of the shield case 4, and the insulator protects the shield case. Electrically isolated.

[0018] Further, an annular electric field mitigation shield 24 is provided inside the upper end of the insulator tube 11. The potential of this electric field mitigation shield 24 is the potential of the metal container 13 (the potential of the primary conductor 1). Fixed.

[0019] In the above embodiment, the insulation breaks in the gap between the shield case 4 and the primary conductor 1. When a break occurs and an arc occurs, the shield case 4 melts due to the arc heat. At this time, the energy of the arc is consumed by melting the shield case 4. Also The protective shield plate 22 arranged inside the shield case is the shield case 4. Since the melting point is higher than that of the protective shield plate 22, the protective shield plate 22 is It will not melt. Most of the ground fault current flows through the shield case 4, which has high conductivity. Therefore, no large amount of heat is generated in the protective shield plate 22. Therefore the protective sheet This eliminates the risk of holes forming in the lead plate 22, and prevents dielectric breakdown from spreading to the secondary coil. This eliminates the risk of

[0020] In the above embodiment, the gap between the shield case 4 and the protective shield plate 22 An arc extinguishing agent such as quartz sand can also be filled in g. Fill the gap g with arc extinguishing agent. If the shield case is melted by the arc, the arc extinguisher will cause the arc to melt. Since energy can be absorbed, the heat applied to the protective shield plate 22 can be reduced. This makes it possible to further ensure protection of the secondary coil.

[0021] In the gas-insulated current transformer shown in Figure 2, the electric field relaxing sheet is at the same potential as the primary conductor 1. The gap between the lead 24 and the secondary lead storage pipe 15, which is at ground potential, This can become the weakest point in the insulation next to the gap between the case 4 and the primary conductor. electric field relaxation The insulation between the Japanese shield 24 and the pipe 15 breaks down, creating a hole in the pipe 15. This may cause dielectric breakdown to spread to the secondary lead inside the pipe. prevent this In order to A protective shield plate similar to the above can be provided inside as well.

[0022]

[Effect of the idea]

As described above, according to the present invention, the primary coil of the shield case housing the secondary coil The inside of the part facing the conductor has a lower conductivity and a higher melting point than the shield case. A protective shield plate made of a thin metal material is installed, so the shield case and primary conductor This is an advantage that can eliminate the risk of the dielectric breakdown that occurs between the There is a point.

[0023] In particular, according to the invention described in claim 2, the shield case and the protective shield plate are connected together. Since the arc-extinguishing agent is filled in the gap between the It can absorb the energy of the generated arc, and the arc heat creates a protective shield. It is possible to eliminate the risk of the plate being damaged and ensure protection of the secondary coil.

[Brief explanation of drawings]

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

FIG. 2 is an enlarged sectional view showing a main part of the embodiment of FIG. 1;

FIG. 3 is an enlarged sectional view of a main part of a conventional gas-insulated current transformer.

FIG. 4 is an enlarged cross-sectional view of a main part of another conventional gas-insulated current transformer.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1... Primary conductor, 2... Secondary coil, 3... Iron core, 4... Shield case, 11... Insulator tube, 13... Metal container, 14... Insulating spacer, 15... Secondary lead storage pipe, 22... Protective shield plate.

Claims (2)

[Scope of utility model registration request] Claim 1: A gas insulated device comprising a primary conductor, a secondary coil wound around an iron core provided to surround the primary conductor, and a shield case provided to surround the secondary coil. In the current transformer, a protective shield plate made of a non-magnetic metal having a lower conductivity and a higher melting point than the metal constituting the shield case is disposed inside a portion of the shield case that faces the primary conductor. A gas insulated current transformer, characterized in that the potential of the protective shield plate is fixed to the potential of the shield case. 2. The gas insulated current transformer according to claim 1, wherein a gap is provided between the shield case and the protective shield plate, and the gap is filled with an arc extinguisher.