KR101254664B1 - Gas insulated switchgear and connecting structure of oil filled transformer - Google Patents

Abstract

The present invention provides a connection structure between the gas insulated switchgear 16 and the inlet transformer 17 in which the shaft length is reduced and the weight is reduced.

To this end, the present invention provides insulating gas and insulating oil between the connection container 1 on the side of the gas insulated switchgear 16 insulated with insulating gas and the connection container 2 on the side of the inlet transformer 17 insulated with insulating oil. At the same time, one cone insulating spacer 3 to be divided is arranged, and the cone insulating spacer 3 has a conical shape or a similar cross-sectional shape, with one convex surface and the other concave surface. The main circuit conductor 8 on the gas insulated switchgear 16 side is disposed so that the gas insulated switch 16 side and the concave surface are on the inlet transformer 17 side. And a buried conductor 4 connected to the flexible conductor 6 which is the main circuit conductor of the inflow transformer 17.

Description

GAS INSULATED SWITCHGEAR AND CONNECTING STRUCTURE OF OIL FILLED TRANSFORMER}

1 is a cross-sectional view of an essential part showing a connection structure between a gas insulated switchgear and an inlet transformer according to an embodiment of the present invention;

FIG. 2 is a sectional view of principal parts showing a usage form in the connection structure shown in FIG. 1; FIG.

3 is an electric field distribution characteristic diagram showing an electric field analysis result of the convex surface side of the cone-shaped insulating spacer shown in FIG. 2;

4 is an electric field distribution characteristic diagram showing the electric field analysis results on the concave surface side of the cone-shaped insulating spacer shown in FIG. 2;

Fig. 5 is a sectional view of principal parts showing another use form in the connection structure shown in Fig. 1;

6 is an electric field distribution characteristic diagram showing an electric field analysis result on the convex surface side of the cone-shaped insulating spacer shown in FIG. 5;

7 is an electric field distribution characteristic diagram showing an electric field analysis result on the concave surface side of the cone-shaped insulating spacer shown in FIG. 5;

FIG. 8 is a sectional view of principal parts showing still another form of use in the connection structure shown in FIG. 1; FIG.

9 is an electric field distribution characteristic diagram showing an electric field analysis result on the convex surface side of the cone-shaped insulating spacer shown in FIG. 8;

10 is an electric field distribution characteristic diagram showing an electric field analysis result on the concave surface side of the cone-shaped insulating spacer shown in FIG. 8;

11 is a cross-sectional view of an essential part showing a connection structure of a gas insulated switchgear and an inlet transformer according to another embodiment of the present invention;

12 is a cross-sectional view of an essential part showing a connection structure between a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

13 is a sectional view of the essential parts showing a connection structure of a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

14 is a cross-sectional view of an essential part showing a connection structure between a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

15 is a sectional view of the essential parts showing a connection structure of a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

16 is a sectional view of the essential parts showing a connection structure of a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

17 is a breakdown voltage characteristic diagram showing a relationship between an insulating oil gap length and breakdown voltage in the connection structure shown in FIG. 16;

18 is a plan view showing a substation configuration employing the connection structure shown in FIG. 1;

19 is a front view of the substation configuration shown in FIG. 18;

20 is a plan view showing a substation configuration employing a conventional connection structure;

21 is a front view of the substation configuration shown in FIG. 20;

Fig. 22 is a sectional view of principal parts showing a connection structure of a gas insulated switchgear and an inlet transformer according to still another embodiment of the present invention;

23 is a characteristic diagram showing foreign matter adhesion phenomenon in the connection structure shown in FIG. 22;

FIG. 24 is a characteristic diagram showing the relationship between the length and the diameter of the branch pipe of the connection structure shown in FIG. 22. FIG.

[Description of Drawings]

1, 2: connection container 3: cone type spacer

4: landfill conductor 5: intermediate conductor

6: flexible conductor 7: electric field relaxation shield

13: airtight container 14a: flange portion

16 gas insulated switchgear 17 inlet transformer

20: recess 27: insulation barrier

The present invention relates to a connection structure between an insulated transformer and a gas insulated switchgear installed in a substation.

The gas insulated switchgear installed in the substation is constructed by arranging the main circuit conductor in the hermetically sealed container 13 enclosed with insulating gas, while the inlet transformer is constituted in the hermetically sealed container 13 enclosed with insulating oil. As a structure, for example, the high voltage output side of the inlet transformer 17 is connected to a gas insulated switchgear using a gas oil bushing provided horizontally on the side of the inlet transformer 17. However, the use of this gas type bushing has resulted in an increase in the shaft length, which hinders the reduction of the land area and the miniaturization and weight of the equipment. Therefore, as the connection structure between the gas insulated switchgear 16 and the inlet transformer 17, two sheets of insulation between the gas insulated switchgear 16 and the inlet transformer are prevented from leaking due to the pressure difference between the insulating gas and the insulating oil. Forming intermediate chambers separated by spacers (see, for example, Patent Document 1, Patent Document 2, and Patent Document 3), or separating insulating gas and insulating oil using a cone-shaped insulation spacer (for example, Patent Document 4) is known.

[Patent Document 1]

Japanese Patent Application Laid-Open No. 57-97306

[Patent Document 2]

Japanese Patent Application Laid-Open No. 57-97307

[Patent Document 3]

Japanese Patent Application Laid-Open No. 57-97308

[Patent Document 4]

Japanese Patent Application Laid-Open No. 11-215630

However, the connection structure of the conventional gas insulated switchgear 16 and the inlet transformer 17 requires two insulating spacers to form an intermediate chamber therebetween. The shaft length between 16) and the inlet transformer was increased, making it difficult to reduce the land area and reduce the size and weight of equipment. On the other hand, in the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 using the cone type insulation spacer, the shaft length can be reduced. However, since the allowable electric field of the insulating oil is lower than SF ₆ gas of about 0.5 MPa, the insulating property The diameter of the cone-shaped spacer used for the partition of the gas and the insulating oil must be larger than that of the insulating spacer used in the ordinary insulating gas. Consequently, there is a limit to the weight reduction of the cone-shaped spacer.

SUMMARY OF THE INVENTION An object of the present invention is to provide a connection structure between the gas insulated switchgear 16 and the inlet transformer 17 in which the shaft length is reduced and the weight is reduced.

In order to achieve the above object, the present invention provides a connection part container on the side of the gas insulated switchgear 16 formed by encapsulating insulating gas in the sealed container 13 and an inlet transformer side formed by encapsulating insulating oil in the other closed container 13. In the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 provided with the insulating spacer which distinguishes insulating gas and insulating oil between the container of the connection part of the connection part, the said insulating spacer is convex on one side, and on the other side. A cone-shaped insulating spacer having a concave surface, wherein only one sheet is provided between the two connection part containers, the insulating gas is divided on the convex side of the cone-shaped insulating spacer, and the insulating oil is divided on the concave side.

EMBODIMENT OF THE INVENTION Hereinafter, the best embodiment of this invention is described based on drawing.

18 and 19 are a plan view and a front view showing a connection structure of the gas insulated switchgear 16 and the inlet transformer 17 according to the present invention.

The gas insulated switchgear 16 containing the main circuit conductors in the sealed container 13 in which the insulating gas is sealed is connected to one end of the breaker 22 via a disconnector through the double main buses 21a and 21b, respectively. And a bushing 23 connected to the power transmission line via a disconnector at the other end of the breaker 22, and one end of the transformer side breaker 24 is connected to the line-side unit and the double main bus lines 21a and 21b, It consists of a transformer-side unit, etc., which has an arrester 25 installed on the other end as necessary, and each part connects the main circuit conductor of each device to an insulation spacer or other insulating support in a sealed container filled with insulating gas. It supports by the state electrically insulated from the airtight container 13 by this. As the insulating gas enclosed in the sealed container 13, SF ₆ gas, air, nitrogen, fluorine-based gas, N ₂ / O ₂ mixed gas, mixed gas containing a negative gas, and the like are used. On the other hand, the inlet transformer 17 is formed by encapsulating vegetable oil such as mineral oil, silicone oil, rapeseed oil, synthetic ester oil, PFC, pure water, liquid nitrogen, liquid helium, and the like in a sealed container 13 having a coil or the like. . The other end side of the transformer side breaker 24 is connected with a connection container 1, a connection container 1 on the side of the gas insulated switch 16, and a connection container 2 on the inlet transformer 17 side. ) Is connected via a cone-shaped insulating spacer 3 described in detail later. The connection part container 1 and the connection part container 2 are formed with substantially the same outer diameter, and the insulating gas and the inflow transformer 17 of the gas insulation switchgear 16 side are formed by the cone-shaped insulating spacer 3 arrange | positioned between them. The insulating oil on the side is divided.

1 is a cross-sectional view of an essential part of the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 described above.

The cone-shaped insulating spacer 3 that separates the insulating gas and the insulating oil has a conical shape or a similar cross-sectional shape, one of which has a convex surface and the other of which has a concave surface, and the convex surface side has a gas insulating switch 16. On the side, the concave surface side faces the inflow transformer 17 side. A buried conductor 4 is integrally provided at the center of the cone-shaped insulating spacer 3, and one end of the buried conductor 4 is connected to the main circuit conductor on the gas insulation switchgear 16 side via a contactor 9 ( 8), and the other end thereof is connected to the flexible conductor 6, which is the main circuit conductor of the inlet transformer 17.

After installing the cone-shaped insulating spacer 3 in the connection container 2, an operator enters the connection container 2 to electrically and mechanically connect the flexible conductor 6 of the inlet transformer 17 to the buried conductor 4. After that, the insulating paper 10 is wound several times on the outer circumferential side of the buried conductor 4 and the flexible conductor 6. After this winding operation, the inside of the connection container 2 side is vacuumed, and then insulating oil is sealed in the sealed container 13 and the connection container 2 of the inlet transformer 17, whereby the insulating paper is not bubbled. Insulating oil is effectively impregnated in (10) to improve the dielectric strength. An insulating film may be used instead of the insulating paper 10.

In the above connection structure, as shown in FIG. 2, the convex surface side of the cone-shaped insulating spacer 3 when the SF ₆ gas as the insulating gas is sealed in the connection part container 1 and the mineral oil as the insulating oil is sealed in the connection part container 2. And the electric field distribution of the concave-side surface are shown in Figs. 3 and 4, and in both figures, the vertical axis is normalized to the maximum value of the electric field of the convex-side surface of the cone-shaped insulating spacer 3.

As for the electric field distribution shown by the solid line, the maximum value of the electric field distribution characteristic 14b on the concave side shown in Fig. 4 is 0.85, and is about 15% more than the maximum value 1.00 of the electric field distribution characteristic 14e on the convex side shown in Fig. 3. low. On the other hand, with respect to the electric field distribution of the creeping component shown by the dotted line, the maximum value of the creeping component electric field distribution characteristic 15f on the concave side shown in Fig. 4 is 0.81, and the creeping component electric field distribution on the convex side shown in Fig. 3. It is about 60% higher than the maximum value 0.56 of the characteristic 15e.

Therefore, when the surface of the cone-shaped insulating spacer 3 is clean, the dielectric strength depends on the maximum value of the electric field, and the convex side is about 15% lower than the concave side. On the other hand, when minute foreign matter adheres to the surface of the cone-shaped insulating spacer 3, the dielectric strength depends on the electric field value of the creeper component, and the concave side is about 60% lower than the convex side, but the value is 0.81. to be. However, it is difficult to completely remove foreign substances in the insulating gas and the insulating oil in the actual gas insulation switchgear and the inlet transformer 17, and it is realistic to determine the size and insulation reliability of the device by the insulation strength at the time of attaching minute foreign substances. Therefore, if the electric field of the creeping component of the cone-shaped insulating spacer 3 can be reduced, the device can be miniaturized. Here, the maximum value of the electric field of the creeping direction component is explained in comparison with the case where the convex side is 0.56 while the concave side is 0.81 compared with the case where the insulation medium encapsulated in the junction container 1 and the junction container 2 is variously changed.

First, as shown in FIG. 5 in the above-described connection structure, the convex side and the concave side surfaces of the cone-shaped insulating spacer 3 in the case where SF ₆ gas is enclosed in the connection container 1 and the connection container 2 as insulating gas, respectively. 6 and 7, the vertical axis is normalized to the maximum value of the electric field on the surface of the convex surface of the cone-shaped insulation spacer 3 as before.

As for the electric field distribution on the surface of the cone-shaped insulating spacer 3, as in the previous case, the maximum electric field distribution characteristic 14f on the concave side shown in Fig. 7 is 0.90, and the electric field distribution on the convex side shown in Fig. 6 is shown. It is about 10% lower than the maximum value 1.00 of the characteristic 14e. On the other hand, the electric field distribution of the creeping component is the maximum value 0.83 near the concave portion having the smallest curvature at the concave side shown in Fig. 7 as in the creeping component electric field distribution characteristic 15f shown by the dotted line, and the convex shown in Fig. 6 It is about 40% higher than the maximum value 0.59 of the creeping component electric field distribution characteristic 15e on the surface side. However, comparing this with the maximum value of the creeping component electric field distribution characteristics 15e and 15f shown in Figs. 2 to 4, it was 0.83 on the concave side shown in Fig. 7, while it was 0.81 on the concave side shown in Fig. There is approximately 5% of tea. That is, as shown in FIG. 2, SF ₆ gas as insulating gas is enclosed in the connection part container 1, and mineral oil as insulating oil is enclosed in the connection part container 2 in the creeping direction in the cone type spacer 3. It turns out that the maximum value of the electric field of a component becomes low.

Moreover, as shown in FIG. 8, the convex side and concave side surface of the cone-shaped insulating spacer 3 when the mineral oil is enclosed in the connection part container 1 as insulating oil, and SF ₆ gas is enclosed in the connection part container 2 as insulating gas. The electric field distribution of is shown in FIG. 9 and FIG.

As for the electric field distribution on the surface of the cone-shaped insulating spacer 3, the maximum value of the electric field distribution characteristic 14d on the concave side shown in Fig. 10 is 1.12, as shown by the solid line as in the previous case, and the convex surface side shown in Fig. 9 is shown. It is about 5% higher than 0.97, and is moving near the buried conductor 4. On the other hand, the electric field distribution of the creeping component is represented by the creeping component electric field distribution characteristic 15d of the dotted line in Fig. 10, and the maximum value at the concave surface side is 1.00 near the concave portion having the smallest curvature. It is about 20% higher than the maximum value 0.81 of the creeping component electric field distribution characteristic 15c on the convex surface side shown.

Comparing this with the maximum value of the electric field of the creeping direction component shown in FIGS. 2-4, it was 0.81 in the concave side shown in FIG. 4, and it is 1.00 in the concave side shown in FIG. That is, as shown in FIG. 2, SF ₆ gas as insulating gas is enclosed in the connection part container 1, and mineral oil as insulating oil is enclosed in the connection part container 2, and the creeping direction component in the cone type spacer 3 is carried out. It can be seen that the maximum value of the electric field is lowered.

Thus, the insulating structure is enclosed in the connection container 1 using the cone-shaped insulating spacer 3 as shown in FIG. 2 in the connection structure of the gas insulated switchgear 16 and the inflow transformer 17, and the connection container ( 2) When insulating oil is enclosed, the maximum value of the electric field is approximately the same on the convex side, while the maximum value of the electric field on the concave side can be made low, and the maximum value of the electric field of the creeping component can be made very low. As a result, the diameters of the connection part containers 1 and 2 of the connection structure connecting the gas insulated switchgear 16 and the inlet transformer 17 can be reduced. On the contrary, when insulating oil is enclosed in the connection part container 1, and insulating gas is enclosed in the connection part container 2, as shown in FIG. 8, when insulating gas is enclosed in both connection part containers 1 and 2, as shown in FIG. In order to ensure equivalent insulation reliability, at least about 20% of the outer diameter of the cone-shaped insulation spacer 3 must be increased from the result of the electric field analysis on the concave surface side.

20 and 21, when the gas oil bushing 26 is used in the connection structure between the gas insulated switchgear 16 and the inlet transformer 17, the gas insulated switchgear is formed by the gas oil bushing 26 ( A large distance is required between 16) and the inlet transformer 17, resulting in a substation configuration having a large installation area. On the other hand, as shown in FIG. 1, when the concave surface side is provided between the connection part containers 1 and 2 toward the inflow transformer 17 side, as shown in FIG. 18 and FIG. It becomes possible to arrange | position between the switchgear 16 and the inflow transformer 17 in close proximity, and the installation area of a substation structure can be reduced significantly. In addition, as described below, the shaft length of the connection part containers 1 and 2 of the connection structure for connecting between the gas insulated switchgear 16 and the inlet transformer 17 can be shortened to further reduce the overall size. have.

Fig. 22 is a sectional view of the essential parts showing the installation position of the cone type insulation spacer 3 in the connection structure between the gas insulated switchgear 16 and the inlet transformer 17 described above.

In the sealed container 13 in which the transformer main body, such as the coil 12, is arrange | positioned, the connection part container 2 which extends substantially horizontally in the side part is branched, and is within dimension L from the branch part in this connection part container 2. The flange 14a is formed in the position of. The same flange 14b is formed also in the connection part container 1 of the side of a gas insulated switchgear, and is connected between the flanges 14a and 14b so that it can be peeled off by the bolt (not shown) through the cone-shaped insulation spacer 3. It is. In order to miniaturize the connection structure between the gas insulated switchgear 16 and the inlet transformer 17, a single cone-shaped insulating spacer 3 is used between the gas insulated switchgear 16 and the inlet transformer 17 to form an insulating gas. In addition to distinguishing the insulating oil, it has been found that the following problems arise especially when the shaft length of the connection part container 2 in the inlet transformer 17 is significantly shortened.

That is, as shown in the figure, the temperature gradient is formed by the heat generation of the coil 12, and convection occurs as indicated by the arrow. Since the cone-shaped insulating spacer 3 is located very close to the sealed container 13 of the inlet transformer 17 in order to shorten the axial length of the connection container 2 in the inlet transformer 17, the convex insulation spacer 3 There is a possibility that micro foreign matter in the ride insulating oil will fly to the surface of the cone-shaped insulating spacer 3 near the buried conductor 4. This is a problem newly created in addition to the inevitable foreign matter mixing in the sealed container 13. Here, if the concave insulating spacer 3 is disposed on the concave side toward the transformer side, there is a risk that the conical insulating spacer 3 will be attached to the portion having the highest electric field in the creeping direction component as described in Figs. Can be drastically reduced, and eventually, the shaft length of the connection structure between the gas insulated switchgear 16 and the inlet transformer 17 cannot be shortened. However, since the conical insulating spacer 3 is provided with its concave side toward the inflow transformer 17 side as shown in Fig. 2, the electric field of the creeping component is suppressed and foreign matter hardly adheres to the creeper surface. Since the shape is reduced, the reduction in the insulation performance can be suppressed, and the shaft length of the connection structure between the gas insulation switchgear 16 and the inlet transformer 17 can be shortened.

As described above, the problem that foreign matter adheres to the surface of the cone-shaped insulating spacer 3 due to the convection of the insulating oil in which the temperature gradient is formed by the heat of the coil 12 is the same as that of the present invention. This occurs newly when the shaft length of the connection structure of the inflow transformer 17 is shortened significantly. The sealed container 13 of the inlet transformer 17 is provided with a connection container 2, which is a branch extending in the horizontal direction, and is usually designed to have a diameter approximately equal to that of the connection container 1 on the gas insulated switchgear 16 side. do. Here, as shown in FIG. 22, the connection part container 2 satisfies the relationship of 0.2 <L / 2r <2.0 when the axis length of this connection part container 2 is L and the radius of the connection part container 2 is r. I am making it. As shown in Fig. 24, 0.2 < L / 2r uses one insulating spacer 3 for separating insulating gas and insulating oil in the connection structure between the gas insulating switch 16 and the inlet transformer 17, and the recessed portion thereof is recessed. When arrange | positioning the surface side toward the inflow transformer 17 side, it determines by the magnitude | size of an allowable foreign material. Moreover, L / 2r <2.0 is a cooling effect by the convection of the insulating oil enclosed in the sealed container 13 of the inlet transformer 17 based on the combination which shortens the shaft length compared with the gas oil bushing conventionally used, especially flexible Considering the cooling effect of the free end connection, the restriction of transport, the stress applied to the welded part to the sealed container 13 in the connection container 2, etc., in the side of the gas conductor opening / closing device 16 of the adult conductor 6 are considered. Is decided.

Therefore, when the shaft length of the connection part container 2 of the inlet transformer 17 side is L, and the radius of the connection part container 2 is r, it is set to 0.2 <L / 2r <2.0, and as shown in FIG. By providing the cone-shaped insulating spacer 3 toward the inlet transformer 17 side, the connection structure can be simultaneously reduced in the radial and axial directions. As described above, the shaft length L is equal to or less than the shaft length of the connection part container 2 on the inlet transformer 17 side when the conventional gas oil bushing is used, and is similar to the connection structure shown in FIGS. 18 and 19. 20 and 21, the gas insulation switchgear 16 and the inlet transformer 17 can be arranged in close proximity to each other, and the installation area of the substation structure can be greatly reduced. .

Moreover, when the size of the foreign material flying near the cone-shaped insulating spacer 3 is 0.2 <L / 2r <2.0, as shown in FIG. 23, the size of the foreign material flying can be limited. Therefore, the preferred shaft length L of the connection container 2 of the inlet transformer 17, when used in the range of 0.2 < L / 2r < 2.0, can limit the size of foreign matter flying near the cone-shaped insulation spacer 3. The connection structure between the gas insulated switchgear 16 and the inlet transformer 17 can be miniaturized in the radial direction and the axial direction.

As described above, the connection structure between the gas insulated switchgear 16 and the inflow transformer 17 according to the present embodiment is greatly reduced by shortening the shaft length until the above-mentioned problem occurs as described in FIG. 22. As shown in FIG. 1, the concave side can be solved by providing a cone-shaped insulating spacer 3 toward the inflow transformer 17 side, as shown in FIG. It is possible to reduce the axial direction at the same time.

Moreover, since the length of the connection part container 2 formed in the sealed container 13 of a transformer was restrained so that insulating gas and insulating oil could be distinguished with one insulating spacer 3, the flexibility of the inlet transformer 17 side was carried out. The free end side of the conductor 6 can be supported by the embedded conductor 4 of the insulating spacer 3, so that the structure of the connection portion can be simplified. The gas insulation switchgear 16 having a long shaft length as in the case of using a conventional gas oil bushing is not prevented from adding another insulating support member for supporting the free end side of the flexible conductor 6. In the connection structure between and the inlet transformer 17, it was not possible to support the free end side of the flexible conductor 6 with the buried conductor 4 of the insulating spacer 3 separating the insulating gas and the insulating oil. However, this can be achieved by the reduction of the shaft length of the connection part container 2 and the use of one insulating spacer 3 for distinguishing the insulating gas and the insulating oil, thereby simplifying the structure of the connection structure.

FIG. 11 is a sectional view of an essential part showing the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 according to another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in FIG.

The insulating gas is enclosed in the connection part container 1 in which the convex surface side of the cone type spacer 3 is arranged, and insulating oil is enclosed in the connection part container 2 in which the concave surface side is arranged. An intermediate conductor 5 of approximately the same diameter is electrically and mechanically connected to the inlet transformer 17 side of the buried conductor 4, and a connection portion with the flexible conductor 6 from the transformer is recessed in the cone-shaped insulating spacer 3. It is closer to the transformer side than the flange 14a of the connection part container 2 located in the surface side. After the connecting operation of the intermediate conductor 5 and the flexible conductor 6, an electric field relaxation shield 7 is provided so as to cover the connection portion, thereby reducing the electric field of the connection portion. The outer surface of the field relaxation shield 7 is molded with an insulator 18 such as epoxy resin or fluorine resin to improve the breakdown voltage. In addition, as the insulator 18 provided on the outer surface of the buried conductor 4, the intermediate conductor 5, and the flexible conductor 6, as in the case of the previous embodiment, an insulating paper or an insulating film wound around the outer peripheral portion thereof is used. Alternatively, it is also possible to increase the voltage by covering all metal paper surfaces in the insulating oil with the same insulating material 18. In addition, if the intermediate connection conductor 5 and the field relaxation shield 7 and between the field relaxation shield 7 and the flexible conductor 6 are covered with a press board or insulating paper, insulation reliability will last for a long time. Can improve.

Fig. 12 is a sectional view of essential parts showing a connection structure between the gas insulated switchgear 16 and the inlet transformer 17 according to still another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in Fig. 1. Insulating gas is enclosed in the connection part container 1 located in the convex surface side of the cone type spacer 3, and insulating oil is enclosed in the connection part container 2 located in the concave surface side. The intermediate connecting conductor 5 is connected to the inlet transformer 17 side of the buried conductor 4 embedded in the center of the cone-shaped insulating spacer 3 using a contactor 19, and the intermediate connecting conductor 5 and the flexible conductor are connected. An electric field relaxation shield 7 is provided on the connection outer periphery of (6).

Thus, when the contactor 19 is used for the connection part in the inlet transformer 17 side, after connecting the intermediate | middle connection conductor 5 and the flexible conductor 6, and the installation of the electric field relaxation shield 7, the flexible conductor ( By using 6), it is possible to insert the connecting portion into the connecting portion container 2, thereby improving workability. When a contactor 19 is used at the connecting portion on the inlet transformer 17 side, a hand hole (not shown) is formed in the sealed container 13 of the inlet transformer 17 shown in Fig. 22, and the intermediate conductor ( 5) By installing the cone-shaped insulating spacer 3 in the connection container 2 while supporting the connection, the connection work between the intermediate conductor 5 and the buried conductor 4 can be easily performed. The work of entering can be omitted. Thereby, the length of the connection part container 2 in the longitudinal direction can be made shorter, and the installation area in a connection structure can be reduced. In addition, the connection of the intermediate conductor 5 and the buried conductor 4 becomes the operation | work which only inserts the intermediate conductor 5 in the contactor 19, and leads to reduction of human error. As in the case of Fig. 13, an outer surface of the contactor 19 and the electric field relaxation shield 7 may be covered with an insulator 18 such as an epoxy resin or a fluorine resin filled with a filler.

FIG. 13 is a sectional view of an essential part showing a connection structure between the gas insulated switchgear 16 and the inlet transformer 17 according to another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in FIG. Insulating gas is enclosed in the connection part container 1 located in the convex surface side of the cone type spacer 3, and insulating oil is enclosed in the connection part container 2 located in the concave surface side. On the inlet transformer 17 side of the buried conductor 4 embedded in the center of the cone-shaped insulating spacer 3, a concave portion 20 that does not penetrate the connection container 1 side is formed, and the intermediate conductor 5 described above is provided. Or in the recessed part 20 of the buried conductor 4, the contact 11 for connections, such as a multicontact, is arrange | positioned. A part of the intermediate conductor 5 can be inserted in the recess 20, and in this insertion state, the electrical contact between the buried conductor 4 and the intermediate conductor 5 is completed by the connecting contact 11. Doing.

Thus, the recess 20 which does not penetrate in the connection part container 1 of the gas insulation switchgear 16 side in the inflow transformer 17 side of the embedding conductor 4 embedded in the cone type spacer 3 is formed, When the electrical connection between the buried conductor 4 and the intermediate conductor 5 is made in the recess 20, the shaft of the connection part container 2 corresponds to the shaft length of the recess 20. Since the length can be further shortened, the connection structure can be further reduced. At this time, if the surface of the contact 11 is made of a metal surface or zinc plated, it is possible to achieve long-term stability of contact resistance. Also in the case of such a structure, since the connection work from the hand hole formed in the vicinity can be performed as demonstrated in FIG. 12, the worker enters into the connection part container 2, and there is no work. As in the case of the previous embodiment, the outer surface of the field relaxation shield 7 is covered with an insulator 18 such as an epoxy resin or a fluorine resin to improve the breakdown voltage so as to increase the axial length and the inner diameter of the connection container 2. Can be made small.

Fig. 14 is a sectional view of an essential part showing a connection structure between the insulation switchgear 16 and the inflow transformer 17 according to still another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in Fig. 1. As in the previous embodiment, insulating gas is encapsulated in the connection part container 1 located on the convex surface side of the cone-shaped insulating spacer 3 and in the connection part container 2 located on the concave surface side. The buried conductor 4, which is embedded in the center of the cone-shaped insulating spacer 3, is characterized by a portion exposed from the surface of the cone-shaped insulating spacer 3 on the side of the gas insulated switchgear 16 in the buried conductor 4. The diameter of the inlet transformer 17 is made small by changing the diameter of the inlet transformer 17 and the diameter of the portion exposed from the surface of the cone-shaped insulating spacer 3 on the inlet transformer 17 side.

Thus, the buried conductor 4 is connected to the inlet transformer 17 side by reducing the outer diameter on the gas insulated switchgear 16 side and the inlet transformer 17 side to reduce the outer diameter of the inlet transformer 17 side. The creepage insulation distance of the cone-shaped insulating spacer 3 insulated by the insulating oil in the inside of the tube can be increased, and the dielectric strength can be improved. Since the cooling performance of the insulating oil is generally higher than that of the insulating gas, even if the outer diameter of the buried conductor 4 located on the insulating oil side is thinner than the insulating gas side, there is no problem of heat generation. In addition, since the outer diameter of the buried conductor 4 located on the inlet transformer 17 side is made small, the diameter of the electric field relaxation shield 7 disposed on the outer circumferential portion of the connecting portion can be made small, and the connection portion container 2 The diameter of can be made small. Usually, the diameter of the connection part container 2 is determined by the insulation distance of the electric field relaxation shield 7, etc., and the diameter of the connection part container 1 on the side of the gas insulation switchgear 16 is determined accordingly. As the diameters of the mitigating shield 7 and the connecting portion container 2 become smaller, the connection structure between the gas insulated switchgear 16 and the inlet transformer 17 can be reduced in size. As described above, in particular, the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 can be made smaller in accordance with the definition of the axial length L of the connection part container 2, thereby reducing the installation area. have.

Fig. 15 is a sectional view of essential parts showing a connection structure between a gas insulated switchgear 16 and an inlet transformer 17 according to still another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in Fig. 1. The cone-shaped insulating spacer 3 is a three-phase package, and has three-phase buried conductors 4a and 4b at a central side thereof with a predetermined inter-phase insulating distance. Each phase is of substantially the same configuration, for example, the configuration described in Fig. 13 is adopted to form a three-phase package, but the configuration described in the other embodiments can also be adopted to form a three-phase package. The cone-shaped insulating spacer 3 has a convex surface on one side and a concave surface on the other side, and the insulating gas and the concave surface side are positioned in the convex surface on the other side, similarly to the single phase. Insulating oil is enclosed in the connection part container 2 mentioned above, and the effect similar to the case of the previous embodiment can be acquired. In addition, the embedding conductors 4a and 4b for the three phases in the cone-shaped insulating spacer 3 may be arranged at each vertex of the triangle or may be arranged in parallel with the three phases on the horizontal plane.

FIG. 16 is a sectional view of an essential part showing a connection structure between the gas insulated switchgear 16 and the inlet transformer 17 according to another embodiment of the present invention, and the same reference numerals are given to the equivalents to those shown in FIG. The cone-shaped insulating spacer 3 has the same configuration as that shown in FIG. 1, and has an insulating gas in the connection container 1 located on the convex surface side of the cone-shaped insulating spacer 3 and a connection container 2 located on the concave surface side. Encapsulates insulating oil. In addition, at least one substantially cylindrical insulating barrier 27 disposed substantially concentrically with the buried conductor 4 is provided on the inflow transformer 17 side, which is the concave surface side of the cone-shaped insulating spacer 3. Here, the gap length by the insulating oil between the flexible conductor 6 and the insulating barrier 27 is d1, and the gap length by the insulating oil between the insulating barrier 27 and the connection part container 2 is d2.

The breakdown voltage of the gap length d in the insulating oil increases in proportion to the gap length d when the gap length d is short, but when the gap length d becomes equal to or greater than a predetermined value, the breakdown voltage V As shown by the characteristic line 28 shown in FIG. 17, the saturation tendency is shown, and even if the gap length d is increased, the breakdown voltage V rises slightly. However, if the insulating oil in the connection part container 2 is divided by the gap length d1 by the insulating barrier 27, the relationship between the breakdown voltage V and the total oil gap becomes like the characteristic line 29, and the insulating barrier ( The breakdown voltage V is higher than that of the characteristic line 28 in the case where 27) is not provided. Therefore, the relationship between the total oil gap length and the breakdown voltage V when the gap of the insulating oil is subdivided into the gap length d1 is represented by the characteristic line 28 of the single-dot chain line, and the plurality of insulating barriers 27 The breakdown voltage (V) increases as the insulating oil is further subdivided using. In addition, in the case of the substantially cylindrical connection part container 2, as shown in FIG. 16, since the potential gradient becomes large as it approaches the flexible conductor 6 side which is a main circuit conductor, it is preferable to set d1 <d2.

In this way, when at least one cylindrical insulating barrier 27 is arranged on the inflow transformer 17 side, which is the concave side of the cone-shaped insulating spacer 3, the insulation breakdown voltage on the concave side of the cone-shaped insulating spacer 3 becomes high and is insulated. The cone-shaped insulating spacer 3 can be made smaller or the insulation margin can be made larger than when there is no barrier.

The connection structure of the gas insulated switchgear 16 and the inflow transformer 17 which concerns on this invention is not limited to the concave side and convex side in the cone type insulation spacer 3 shown in FIG. The present invention can be applied to the connection structure of the gas insulated switchgear 16 and the inlet transformer 17 using the cone-shaped insulating spacer 3 employing the same.

The connection structure between the gas insulated switchgear 16 and the inlet transformer 17 according to the present invention can reduce the maximum value of the electric field on the concave side and make the maximum value of the electric field of the creeping component very low. As a result, the diameter of the connection part container of the connection structure which connects between the gas insulation switchgear 16 and an inflow transformer can be made small. In addition, since there is only one cone-shaped insulating spacer between the connection container on the gas insulated switchgear 16 side and the connection container on the inlet transformer side, the axial length of the connection structure is determined using a conventional gas oil bushing. Compared to the case can be significantly reduced.

Claims (6)

An insulating spacer for separating insulating gas and insulating oil is provided between the connecting portion container on the gas insulated switchgear configured by enclosing the insulating gas in the sealed container and the connecting portion container on the inlet transformer side formed by encapsulating the insulating oil in the other closed container. In the connection structure of a gas insulated switchgear and an inlet transformer, The insulating spacer is a cone-shaped insulating spacer having a convex surface on one side and a concave surface on the other side, provided with only one cone-shaped insulating space between the connection container and the insulating gas separated from the convex surface side of the cone-shaped spacer. A connection structure between a gas insulated switchgear and an inlet transformer, characterized by dividing the insulating oil on the concave side. The method of claim 1, The cone insulation spacer has a buried conductor electrically connected between a main circuit conductor on the gas insulated switch side and a main circuit conductor on the inlet transformer side at its center portion, and the buried conductor is exposed to the concave surface side. A gas insulated switchgear and an inlet transformer, characterized in that the diameter of the portion to be smaller than the diameter of the portion exposed to the convex surface side. The method of claim 1, The cone-shaped insulating spacer has a buried conductor electrically connected between a main circuit conductor on the gas insulated switch side and a main circuit conductor on the inlet transformer side at a central portion thereof, and on the concave surface side of the buried conductor A gas insulated portion is formed which does not penetrate the convex surface side, and at least a part of an intermediate conductor which connects between the buried conductor and the main circuit conductor on the inlet transformer side is inserted into the concave portion. Connection structure of switchgear and inlet transformer. The method of claim 3, A connection structure of a gas insulated switchgear and an inlet transformer, characterized in that a contact for electrically connecting the buried conductor and the intermediate conductor is disposed in the recess. The method of claim 1, A connecting structure of a gas insulated switchgear and an inlet transformer, characterized in that when the axial length of the connecting portion container on the inlet transformer side is L and the radius is r, 0.2 <L / 2r <2.0. The method of claim 1, The inlet transformer has a flexible conductor connected to the main circuit conductor on the gas insulated switchgear side, and the cone insulation spacer has a main circuit conductor on the gas disconnection switch side in the center and the inlet transformer side. And a buried conductor electrically connecting between flexible conductors of the flexible conductor, wherein the end of the gas insulated switchgear side of the flexible conductor is electrically connected to the buried conductor and mechanically supported. Connection structure of gas insulated switchgear and inlet transformer.

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