JPH09213151A - Electric appliance insulating substance, its manufacture and electric appliance using insulating substance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an insulative material for electric appliance having a high dielectric and a high mechanical strength and offer an electric appliance of a high insulative and mechanical reliability using such insulative material. SOLUTION: A spacer piece 8 installed between windings to support them in the radial direction is made from an insulative material 21 as base material which has a honeycomb structure, and the base material is impregnated with a synthetic resin having a weight smaller than the base material, and the resin is left hardening. The insulative material 21 of honeycomb structure is made in a sheet form from natural fiber, synthetic paper, non-woven cloth, cloth, synthetic resin film, or the like. The synthetic resin should be of thermosetting type of epoxy, polyester, or polyimide series which excel in the heat resistance, insulativeness, and mechanical characteristics, and should particularly have a glass transition temp. higher than the max. service temp. of the spacer piece 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a static induction electric device having windings such as a transformer, an insulating bus bar, a switchgear and the like, and more particularly to a static induction electric device. The present invention relates to a constituent insulator of an insulating support structure that supports the main body structure.

[0002]

2. Description of the Related Art Various electric devices used in an electric power system, that is, electric devices such as a static induction electric device, an insulating busbar, and a switchgear, have a main body structure such as a winding in a container in which an insulating medium is enclosed. Are housed in an insulated supporting state. The main body structures such as windings are insulated and supported by an insulating support structure composed of constituent insulators arranged between the main body structures or between the container and the main body structure.

With the recent increase in the capacity and voltage of electric power systems, the body structure of electric equipment has become larger, heavier and higher in voltage, but due to reasons such as difficulty in land acquisition, the entire electric equipment is Since miniaturization is required, as a result, high insulation strength and mechanical strength are required for the constituent insulators of the insulation support structure that insulate and support such a main body structure.
In particular, the windings of static induction electrical equipment have a much higher voltage and heavier weight than the main body structures of other electrical equipment, so a structure for insulating and supporting such high voltage and heavy weight windings. Insulators are required to have extremely high insulation strength and mechanical strength. A transformer will be described below as an example of the configuration of such a static induction electric device.

First, in the conventional transformer, as the insulating support structure between the high and low voltage windings, the gap between the windings is divided into two insulating cylinders arranged inside and outside, and the gap between the two insulating cylinders is divided. In order to maintain the dimension, a configuration in which the spacing pieces are distributed and arranged in a uniform distribution over the entire circumference of the insulating cylinder is generally adopted.

FIG. 6 is a horizontal view showing a part of the insulating support structure between windings in the circumferential direction of a disk winding of an inner iron type transformer among transformers having such an insulating support structure. FIG. As shown in FIG. 6, between the low voltage winding 1 and the high voltage winding 2 arranged inside and outside, the first and second insulating cylinders 3 and 4 are arranged inside and outside. That is, the low voltage winding 1
The first insulating cylinder 3 is arranged at a close position on the outer side of, and the second insulating cylinder 4 is arranged at a close position on the inner side of the high-voltage winding 2.

Between the low-voltage winding 1 and the first insulating cylinder 3, spacers 5 are distributed and arranged in a uniform distribution over the entire circumference thereof. Similarly, between the high-voltage winding 2 and the second insulating cylinder 4, the spacers 6 are arranged in a uniform distribution over the entire circumference thereof. In this case, the spacers 5 and 6 on the low voltage side and the high voltage side have the windings 1 and 2 and the insulating cylinder 3 at the same position in the circumferential direction.
4 are arranged so as to overlap in the radial direction.
Of these, the spacer 5 on the high voltage side is fitted to the rail 7 attached to the outer peripheral surface of the second insulating cylinder 4. The conductor of the high voltage winding 2 is wound around the outside of the rail 7.

Between the first insulating cylinder 3 and the second insulating cylinder 4, a spacing piece 8 for maintaining a gap between the two insulating cylinders 3 and 4 is provided all around the insulating cylinders 3 and 4. They are distributed and evenly distributed. In this case, the spacing piece 8 is
The spacers 5 and 6 on the low voltage side and the high voltage side are arranged at the same positions so as to overlap the windings 1 and 2 and the insulating cylinders 3 and 4 in the radial direction.

In addition, between the insulating cylinders 3 and 4 and the inner and outer peripheral surfaces of the windings 1 and 2, and between the insulating cylinders 3 and 4, which are formed by the spacers 5 and 6, the rail 7, and the spacing piece 8. Through each gap, transformer oil or SF ₆ gas flows as a fluid that functions as an insulating medium and a cooling medium.

FIG. 7 is a longitudinal sectional view showing an axial end portion of the inner iron type transformer of FIG. 6 having the above-described insulating support structure. As shown in FIG. 7, the low voltage winding 1 and the high voltage winding 2
Are arranged concentrically around the main landing gear core 11, and each of the windings 1 and 2 is arranged with respect to the yoke core 12 which is a ground insulator.
Tightening ring 13 made of solid insulator and supporting insulator 1
It is insulated and supported by 4 in the axial direction.

[0010]

By the way, in a transformer, between windings, between windings and an iron core, or between axial end portions of windings and upper and lower yoke iron cores or a grounding object such as a tank. The approximate electric field applied to the insulating medium (that is, the transformer oil or SF ₆ gas as described above) is obtained by dividing the voltage applied between the windings or between the winding and the grounded object by the gap length. On the other hand, the spacing piece 8 shown in FIG.
In the portion where the solid insulator for insulating support is arranged, such as the spacers 5, 6, the rail 7, etc., the solid insulator is completely filled between the windings or between the winding and the grounded object. Since there is no insulating medium such as transformer oil or SF ₆ gas in the part, it is not necessary to consider the electric field applied to these.

However, generally, the end faces of the spacing pieces (various spacing pieces including the spacing pieces 8, the spacers 5, 6 and the rail 7 in FIG. 6) provided between the windings or between the windings and the grounded object are flat. On the other hand, since the inner and outer peripheral surfaces of the winding and the insulating cylinder are curved surfaces, it is difficult to avoid the generation of a minute gap between the insulating cylinder and the spacing piece. In this case, the dielectric constant of the distance piece consisting of solid insulating material, transformer oil or SF ₆
Since the dielectric constant is higher than that of the gas, a high electric field inversely proportional to the dielectric constant is applied to the transformer oil and SF ₆ gas existing in the micro gap as described above.

On the other hand, since the insulation strength of transformer oil or SF ₆ gas is generally lower than that of the spacing piece made of a solid insulating material, a minute gap generated in the portion where the spacing piece is arranged causes a gap in the insulation. It becomes a weak point. The problem of the generation of such a minute gap and the generation of a weak point in insulation due to the same also exists between the winding and the grounding object such as the iron core.

In order to reduce the electric field applied to the transformer oil or SF ₆ gas in the minute gap generated in the space piece as described above, it is effective to reduce the dielectric constant of the space piece. Conventionally, from such a viewpoint, JP-A-5-29105
As disclosed in Japanese Unexamined Patent Publication No. 5 (1994), a method of forming the spacing piece with a hollow pipe, and a method of forming the spacing piece with a honeycomb material as disclosed in JP-A-6-267767 have been proposed. ing. Furthermore, the actual Kaihei 5-7
As disclosed in Japanese Patent No. 6018, in a sheet winding transformer, by forming a winding support piece for axially supporting a winding with an assembly of hollow pipes, it is possible to increase insulation strength. Proposed.

However, when a hollow material such as a honeycomb material or a hollow pipe as described above is used as a constituent of a transformer, there arises a problem that the hollow material portion becomes a weak point of mechanical strength. That is, since the mechanical strength of the hollow material is inferior to that of the solid insulator, when the spacing piece is formed by using such a hollow material having low mechanical strength, the short-circuit mechanical force of the winding is It becomes a mechanical weak point against the force applied in the radial direction of the winding. Further, when a hollow material is used as a supporting insulator at the end of the winding in the axial direction, it becomes impossible to obtain a sufficient mechanical force for the vertical tightening force of the winding.

On the other hand, conventionally, a honeycomb material obtained by impregnating the above-mentioned honeycomb material with a phenol resin to improve mechanical strength is also commercially available. It is therefore conceivable to use this type of honeycomb material in place of the previously mentioned honeycomb material. However, such a honeycomb material impregnated with a phenolic resin is mainly used for a structure such as a building material, and this type of honeycomb material has a mechanical strength , Especially the compression force is insufficient. In particular, this type of honeycomb material has a large decrease in mechanical force at high temperatures, and therefore it is difficult to apply it to a constituent insulator of a transformer, which has a temperature of about 100 ° C. if locally applied.

The present invention has been proposed in order to solve the above-mentioned problems of the prior art, and the first object thereof is to construct an insulating support structure for electric equipment, particularly for static induction electric equipment. A honeycomb material is used as a constituent insulator to provide an insulator having high insulation strength and mechanical strength. Further, a second object of the present invention is to use an insulator having such high insulation strength and mechanical strength as a constituent insulator of various electric devices to obtain high insulation reliability and mechanical reliability. It is an object of the present invention to provide an electric device having the above-mentioned characteristics, and particularly to provide a static induction electric device having high insulation reliability and mechanical reliability. Further, a third object of the present invention is to provide an insulator for electric equipment which has high heat resistance in addition to high insulation strength and mechanical strength, thereby providing high insulation reliability and mechanical reliability. An object of the present invention is to provide an electric device having high thermal reliability.

[0017]

In order to achieve the above-mentioned object, in the present invention, an insulator for electric equipment, which is obtained by impregnating an insulator having a honeycomb structure with a synthetic resin and curing the same.
The present invention proposes a manufacturing method for manufacturing such an insulator for electric devices, and various electric devices using such an insulator for electric devices. That is, claim 1
To 12 are inventions of insulators for electric devices, and
3 and 14 are inventions of the manufacturing method. Further, claims 15 to 22 are inventions of electric equipment, and particularly, claim 1
6 to 20 are inventions of a static induction electric device.

[1. Invention according to Claims 1 to 12: Insulator for electrical equipment] The invention according to Claims 1 to 4 is a constituent insulator for accommodating the main body structure in a container and insulatingly supporting the main body structure. In an insulator for an electric device used for the constituent insulator of an electric device in which an insulating medium is enclosed in the container, an insulator having a honeycomb structure is used as a base material. The feature is that some element is added to the material.

The insulator for electric equipment according to claim 1 is formed by using an insulator having a honeycomb structure as a base material, impregnating the base material with a synthetic resin and curing the base material, and impregnating the synthetic resin. The amount is set to be equal to or less than the weight of the base material. According to the invention as set forth in claim 1 having the above structure, the gap between the honeycomb base material (insulator for electric equipment) made of the base material of the insulator having the honeycomb structure and the synthetic resin is transformer oil. Since it is replaced by an insulating medium such as SF6 gas or SF ₆ gas, the dielectric constant of this honeycomb material is reduced and approaches the dielectric constant of the insulating medium. Therefore, the electric field concentration on the insulating medium, which has been a problem in the past, can be suppressed in the minute gap generated in the portion where the honeycomb material is arranged. Further, when the impregnated amount of the synthetic resin on the base material exceeds the weight of the base material, the dielectric constant of the honeycomb material increases, but in the present invention, the impregnated amount of the synthetic resin on the base material is not more than the weight of the base material. Therefore, the dielectric constant can be suppressed and sufficient insulation strength can be obtained. Further, the mechanical strength of the honeycomb material is sufficiently increased by the synthetic resin impregnated with the weight of the base material or less, so that sufficient strength can be secured against external mechanical force.

According to a second aspect of the present invention, there is provided an insulator for electric equipment, which comprises an insulator having a honeycomb structure as a base material, and at least a part of one surface of the base material is made of a fibrous material. The fiber directions of are arranged in the axial direction of the cell columns. According to the invention of claim 2 having the above-mentioned structure, since the honeycomb material uses the base material of the insulator having the honeycomb structure,
Similar to the invention described in claim 1, high insulation strength can be obtained. Further, by using a fibrous material for a part of the base material forming the honeycomb material, and by arranging the fiber direction of the fibrous material in the axial direction of the cell pillars of the base material, which is the thickness direction of the honeycomb material. The mechanical strength in the thickness direction of the honeycomb material can be improved.

According to a third aspect of the present invention, there is provided an insulator for electric equipment, which comprises an insulator having a honeycomb structure as a base material, and a solid insulating material is bonded to a part of at least one surface of the base material. I am trying. The insulator for electric equipment according to claim 4 is formed by using an insulator having a honeycomb structure as a base material, and at least a part of at least one surface of the base material is made of a fibrous material, and a fiber direction of the fibrous material is formed. Are arranged in the axial direction of the cell columns, and a solid insulating material is bonded to a part of at least one surface of the base material. The insulator for electrical equipment according to claim 5,
In the insulator for electric equipment according to claim 3 or 4, the friction coefficient of the solid insulating material is small. According to a sixth aspect of the present invention, in the electrical equipment insulator according to any one of the third to fifth aspects, a coating material is applied to a surface of the solid insulating material.

According to the inventions of claims 3 to 6 having the above-mentioned constitutions, the solid insulating material is bonded to a part of the base material constituting the honeycomb material so that the solid insulating material is adhered. It is possible to reduce the coefficient of friction of the attached surface and obtain sufficient mechanical strength. Further, in particular, in the invention described in claim 4, the mechanical strength can be improved by the synergistic effect of the fibrous material and the solid insulating material. Therefore, in particular, this honeycomb material,
When inserting into the gap between the main body structures or between the container and the main body structure, it is possible to reduce the frictional force generated between the main body structure and the container and the honeycomb material,
The honeycomb material can be easily inserted with a small compressive force.

According to a seventh aspect of the present invention, there is provided an electrical equipment insulator according to the third aspect of the present invention.
The width of the solid insulating material is larger than that of the base material. According to the invention of claim 7 having the above-mentioned configuration, the solid insulating material attached to a part of the base material forming the honeycomb material has a width larger than that of the base material, so that the mechanical strength is increased. Can be improved.

An insulator for electric equipment according to claim 8 is the insulator for electric equipment according to any one of claims 2 to 7, wherein a composite material is formed on a base material of the insulator having the honeycomb structure. It is characterized in that it is constituted by impregnating a resin and curing it, and the impregnated amount of the synthetic resin is set to be equal to or less than the weight of the base material. According to the invention described in claim 8 having the above-mentioned structure, the same operation and effect as the invention described in claim 1 can be obtained by impregnating the synthetic resin. That is, compared with the case where only the solid insulating material is used, or the case where only the solid insulating material and the fibrous material are used, the mechanical strength of the honeycomb material is further improved by the synergistic effect of these materials and the synthetic resin. be able to.

According to a ninth aspect of the present invention, in the electrical equipment insulator of the first or eighth aspect, the synthetic resin is selected from the group consisting of epoxy resin, polyester resin, and polyimide resin. It is characterized by that. According to the invention of claim 9 having the above-mentioned structure, by using a synthetic resin having excellent insulating properties, mechanical properties, and heat resistance as the synthetic resin, the insulating strength and mechanical properties of the honeycomb material can be improved. The mechanical strength and heat resistance can be improved.

The insulator for electric equipment according to claim 10 is
The invention according to claim 1, 8 or 9 is characterized in that the synthetic resin is a thermosetting resin having a glass transition temperature higher than the maximum use temperature of the constituent insulator. According to the invention described in claim 10 having the above-mentioned structure, the heat resistance strength of the honeycomb material can be improved, and the mechanical strength such as the compressive force at high temperature can be improved.

The insulator for electric equipment according to claim 11 is:
In the invention according to any one of claims 1 to 8, the adhesion amount of the synthetic resin to the base material of the insulating material having the honeycomb structure is at an axial end portion of the cell pillar of the base material. It is characterized by more than in the central part. According to the invention of claim 11 having the above configuration, by increasing the amount of synthetic resin adhered at the axial end portion of the cell column of the base material that is the thickness direction of the honeycomb material, In the honeycomb material, it is possible to improve the mechanical strength of the end portion in the thickness direction, which tends to be a weak point in the mechanical strength, and it is possible to suppress the generation of minute gaps in the arrangement portion of the honeycomb material and to concentrate the electric field on the insulating medium. Can be suppressed.

The insulator for electric equipment according to claim 12 is:
In the invention according to any one of claims 1 to 8, the adhesion amount of the synthetic resin to the base material of the insulator having the honeycomb structure is uniform over the surface of the base material. It has a feature. According to the invention as set forth in claim 12 having the above-mentioned structure, the adhesion amount of the synthetic resin is made uniform over the surface of the base material, thereby preventing mechanical weakness in the honeycomb material. Therefore, the mechanical strength of the honeycomb material can be improved, and the electric field concentration on the insulating medium can be suppressed in the minute gap generated in the arrangement portion of the honeycomb material.

[2. Inventions according to claims 13 and 14: Method for producing insulator for electric equipment] The invention according to claim 13 is the method for producing an insulator for electric equipment according to claim 11, wherein the honeycomb is provided. It is characterized in that the axial direction of the cell pillar of the base material of the insulator having the structure is the vertical direction, and the base material is inverted a plurality of times to impregnate the synthetic resin, and the synthetic resin is cured at each inversion. . According to the invention of claim 13 having the above configuration,
By inverting the base material multiple times to impregnate it with synthetic resin, and curing the synthetic resin with each inversion, a large amount of impregnated resin is applied to the axial ends of the cell pillars of the base material, which is the thickness direction of the honeycomb material. Can be attached.

The invention according to claim 14 is the same as claim 1
2. The method for manufacturing an insulator for an electric device according to 2, wherein the base material of the insulator having the honeycomb structure is impregnated with a synthetic resin, and then the synthetic resin is cured while rotating the base material. I am trying. According to the invention having the structure as described above, the impregnation of the entire honeycomb material is achieved by impregnating the base material with the synthetic resin and then curing the synthetic resin while rotating the base material. The resin can be attached uniformly.

[3. The invention according to claims 15 to 22: Electric equipment] The invention according to claim 15 is an insulating support structure comprising a main body structure in a container and comprising a constituent insulator for insulatingly supporting the main body structure. And an electric device in which an insulating medium is enclosed in the container is characterized by having the following configuration. That is, claim 15
In the invention described in claim 1, an insulator for electric equipment selected from the insulators for electric equipment described in claims 1 to 12 is used for a selected portion of the constituent insulators. It is characterized by being.

According to the invention of claim 15 having the above-mentioned constitution, as the constituent insulator, the honeycomb material (insulator for electric equipment) having high insulation strength and mechanical strength as described above is used. By doing so, it is possible to suppress the electric field concentration on the insulating medium, which has been a problem in the past, in the minute gap generated in the portion where the honeycomb material is arranged, and to stably support the main body structure. it can. Therefore, the reliability of the insulating support of the main body structure can be improved.

The invention described in claims 16 to 20 is an invention of a static induction electric device. The invention according to claim 16 is
A main body structure including an iron core and a plurality of windings wound around the core is housed in a container, and an insulating support structure made of constituent insulators is provided to insulate and support the main body structure. A static induction electric device in which an insulating medium is enclosed is characterized by having the following configuration. That is, in the invention described in claim 16, the selected part of the constituent insulator is provided in any one of claims 1 to 12.
It is characterized in that an insulator for electric equipment selected from among the insulators for electric equipment described above is used.

According to the sixteenth aspect of the present invention having the above-mentioned structure, the honeycomb material (insulator for electrical equipment) having the above-mentioned high insulation strength and mechanical strength is used as the constituent insulation material. By doing so, it is possible to suppress the electric field concentration on the insulating medium, which has been a problem in the past, in the minute gap generated in the portion where the honeycomb material is arranged, and to stably support the main body structure. it can. Therefore, the reliability of the insulation support of the main body structure such as the iron core and the winding can be improved. In particular, when the honeycomb material of the present invention is used as a constituent insulator for insulating and supporting a winding having a large weight, it has sufficient mechanical strength against a large mechanical force applied in its axial direction and radial direction. Can be secured.

The invention according to claim 17 is the same as claim 1
The static induction electric device described in 6 is characterized by having the following configuration. That is, claim 17
In the invention described in (1), the constituent insulator is provided between the iron core and the winding to provide a spacing piece for supporting the winding in a radial direction and a gap provided between the windings to form the winding. And a spacing piece for supporting in the radial direction. Then, the selected portion of the entire spacing piece provided between the iron core and the winding wire and between the winding wires is provided in the selected portion.
An electrical equipment insulator selected from the electrical equipment insulators described above is used.

According to the invention as set forth in claim 17, which has the above-mentioned structure, it is provided as a part of the spacing piece which is provided between the iron core and the winding or between the windings and radially supports the winding. , By using the honeycomb material having high insulation strength and mechanical strength as described above, the electric field concentration on the insulating medium, which has been a problem in the past, is suppressed in the minute gap generated in the portion where the honeycomb material is arranged. In addition, the winding can be stably supported. Therefore, the reliability of the insulation support of the winding can be improved. Furthermore, by using a honeycomb material formed by joining a solid insulating material to a part of the base material, the frictional force generated between the winding material and the iron core and the honeycomb material is reduced when the honeycomb material is inserted. Therefore, the honeycomb material can be easily inserted with a small compressive force.

The invention according to claim 18 is the same as claim 1.
The static induction electric device described in 6 is characterized by having the following configuration. That is, claim 18
In the invention described in (1), the constituent insulator is provided between the iron core and the winding to provide a spacing piece for supporting the winding in a radial direction and a gap provided between the windings to form the winding. And a spacing piece for supporting in the radial direction. Then, in the selected portion of the entire spacing piece provided between the iron core and the winding wire and between the winding wires, the claim 1 to the claim 1.
Insulators for electrical equipment selected from the insulators for electrical equipment described up to 2 are used. Further, the base material forming the insulator for electric equipment is arranged such that the spreading direction thereof is the same as the circumferential direction of the winding.

According to the eighteenth aspect of the present invention having the above-mentioned structure, it is provided as a part of the spacer provided between the iron core and the windings or between the windings to radially support the windings. , By using the honeycomb material having high insulation strength and mechanical strength as described above, the electric field concentration on the insulating medium, which has been a problem in the past, is suppressed in the minute gap generated in the portion where the honeycomb material is arranged. In addition, the winding can be stably supported. Therefore, the reliability of the insulation support of the winding can be improved. Furthermore, by matching the spreading direction, which is the direction in which the honeycomb material has a weak compression force, with the winding circumferential direction in which the mechanical force applied is the smallest, sufficient mechanical strength that can withstand the compression force during insertion of the honeycomb material is secured. Therefore, when the honeycomb material is inserted, the honeycomb material can be easily inserted.

The invention according to claim 19 is the above-mentioned claim 1.
The static induction electric device according to any one of 6 to 18 is characterized by having the following configuration.
That is, in the invention according to claim 19, an insulating cylinder is arranged between the windings, and the constituent insulator is provided in a gap between the insulating cylinder and the winding, and Includes directional support spacing pieces. Then, the insulator for electric equipment according to claim 7 is used in a selected portion of the entire spacing piece provided between the insulating cylinder and the winding.

According to the invention as set forth in claim 19, which has the above-mentioned structure, the above-mentioned is provided as a part of the spacing piece which is provided between the insulating cylinder and the winding and radially supports the winding. By using a honeycomb material having such high insulation strength and mechanical strength, it is possible to suppress the electric field concentration on the insulating medium, which has been a problem in the past, in the minute gap generated in the portion where the honeycomb material is arranged. In addition, the winding can be stably supported. Therefore, the reliability of the insulation support of the winding can be improved. Furthermore, by using a honeycomb material formed by joining a solid insulating material to a part of the base material as the honeycomb material, friction generated between the winding and the iron core and the honeycomb material when the honeycomb material is inserted. Since the force can be reduced, the honeycomb material can be easily inserted with a small compression force. Also, the mechanical strength can be improved by making the width of the solid insulating material of the honeycomb material larger than that of the base material.

The invention according to claim 20 is the same as claim 1
The static induction electric device according to any one of 6 to 19 is characterized by having the following configuration.
That is, in the invention of claim 20, an insulating cylinder is arranged between the windings, and the constituent insulators are distributed and evenly distributed over the entire circumference of the outer peripheral surface of the insulating cylinder. Includes spacing pieces that radially support the wire. The outer winding of the insulating cylinder is a disk winding composed of a plurality of layers of coil sections arranged in the axial direction, and each coil section is formed of the spacing piece on the outer peripheral surface of the insulating cylinder. It is wound in a disk shape on the outside. The constituent insulator further includes a spacer provided outside the spacing piece between adjacent coil sections of the disc winding to axially support the coil section. And the insulator for electric equipment selected from the insulator for electric equipment described in said Claim 1 to Claim 12 is used for the selected part of this spacer.

According to the invention as set forth in claim 20, which has the structure as described above, it is provided as a part of the spacing piece which is provided between the plurality of coil sections of the disk winding and axially supports the coil sections. , By using the honeycomb material having high insulation strength and mechanical strength as described above, the electric field concentration on the insulating medium, which has been a problem in the past, is suppressed in the minute gap generated in the portion where the honeycomb material is arranged. It is also possible to stably support the coil section. Therefore, the reliability of the insulating support of the disc winding can be improved.

According to a twenty-first aspect of the present invention, a high-voltage conductor is housed in a container, an insulating support structure made of constituent insulators is provided for insulating and supporting the high-voltage conductor, and an insulating medium is enclosed in the container. The insulated bus bar is characterized by having the following configuration. That is, claim 21
In the invention described in claim 1, an insulator for electric equipment selected from the insulators for electric equipment described in claims 1 to 12 is used for a selected portion of the constituent insulators. It is characterized by being. According to the invention of claim 21 having the above-mentioned constitution, by using the honeycomb material (insulator for electric equipment) having high insulation strength and mechanical strength as described above as the constituent insulator The electric field concentration on the insulating medium, which has been a problem in the past, can be suppressed in the minute gap generated in the portion where the honeycomb material is arranged, and the high-voltage conductor can be stably supported. Therefore, the reliability of the insulation support of the high voltage conductor can be improved.

According to a twenty-second aspect of the present invention, a main body structure including an opening / closing portion is housed in a container, and an insulating support structure made of constituent insulators is provided to insulate and support the main body structure.
An opening / closing device in which an insulating medium is enclosed in the container is characterized by having the following configuration. That is, in the invention described in claim 22, the selected portion of the constituent insulator is provided in the above-mentioned claims 1 to 12.
It is characterized in that an insulator for electric equipment selected from among the insulators for electric equipment described above is used. According to the invention of claim 22, which has the above-mentioned structure, by using the honeycomb material (insulator for electrical equipment) having high insulation strength and mechanical strength as described above as the constituent insulator , It is possible to suppress the electric field concentration on the insulating medium, which has been a problem in the past, in the minute gap generated in the portion where the honeycomb material is arranged, and to stably support the main body structure such as the opening / closing part. You can Therefore, the reliability of the insulation support of the main body structure such as the opening / closing part can be improved. In particular, when the honeycomb material of the present invention is used as a constituent insulator for insulatingly supporting the opening / closing portion, sufficient mechanical strength can be secured against a large mechanical force applied during opening / closing.

[0045]

BEST MODE FOR CARRYING OUT THE INVENTION A plurality of embodiments in which the present invention is applied to a static induction electric device such as a transformer will be specifically described below with reference to FIGS. The same parts as those of the prior art shown in FIGS. 6 and 7 are designated by the same reference numerals and the description thereof will be omitted.

[1. First Embodiment] [1-1. Configuration] FIG. 1 shows a first embodiment of a static induction electric device according to the present invention, which is claim 1, 9, 10, 15,
It is a figure which shows one embodiment which applied the invention described in 16 to the spacing piece between windings, and is a perspective view which shows a spacing piece. As shown in FIG. 1, the spacing piece 8 is configured by impregnating an insulating material 21 having a honeycomb (honeycomb state) structure with a synthetic resin and curing the synthetic resin. This spacing piece 8
Is specifically manufactured as follows.

First, a plurality of sheet-shaped insulating materials are prepared, and an adhesive is applied to each of them at a constant interval to form a plurality of adhesive application portions. The position of the adhesive application portion is shifted by half a pitch and stacked to form a block. Then, the block-shaped insulating material is sliced to a predetermined size and then expanded (expanded) in the stacking direction of the sheets, so that a constant width W and a constant cell column as shown in FIG. It is possible to obtain the insulator 21 having a honeycomb structure having a height (axial dimension of cell pillar: thickness of honeycomb material) T and a constant length L. As the sheet-shaped insulating material used for manufacturing the insulator 21 having such a honeycomb structure, natural fiber, synthetic paper, non-woven fabric, cloth, synthetic resin film or the like can be used.

Next, the insulator 21 having the honeycomb structure configured as described above is sufficiently dried to remove the water content thereof, and is left unexpanded or after appropriate expansion, and then the resin-containing Synthetic resin is impregnated and heat-cured as long as the amount does not exceed the weight of the substrate. This impregnation
Upon curing, it is desirable to use a measure such as impregnation in a vacuum state so that no bubbles remain. Further, as the synthetic resin, a thermosetting resin such as an epoxy resin, a polyester resin, and a polyimide resin, which has excellent heat resistance characteristics, insulation characteristics, and mechanical characteristics, is used. A thermosetting resin having a high glass transition temperature is selected.

[1-2. Action / Effect] According to the first embodiment having the above configuration, the following action / effect is obtained.
The effect is obtained. First, FIG. 2 shows the relationship between the compressive strength (ratio) and the dielectric constant of the honeycomb material with respect to the synthetic resin impregnation amount (%) when the weight of the insulator having the honeycomb structure as the base material is 100. Is. Here, the compressive strength and the dielectric constant of the manufactured honeycomb material are different depending on the type of the insulating material forming the base material, the cell size of the honeycomb structure, and the type of the synthetic resin to be impregnated. There is a relationship as shown in FIG. That is, as is clear from FIG. 2, when the compressive strength of the honeycomb material not impregnated (not impregnated with the synthetic resin) is 1, the compressive strength of the honeycomb material impregnated with the synthetic resin is It increases as the amount of impregnation increases. Further, the dielectric constant of the honeycomb material also increases as the synthetic resin impregnation amount increases.

As is clear from FIG. 2, when the synthetic resin impregnation amount exceeds the base material weight, the compressive strength of the honeycomb material approaches saturation, and therefore the strength is increased even if the synthetic resin impregnation amount is further increased. The increase is not so desirable, but rather the dielectric constant is unnecessarily increased. Therefore, when the synthetic resin impregnation amount exceeds the base material weight in this way, the electric field relaxation effect of the honeycomb material is weakened, and the merit also decreases from the price increase due to the increase in the synthetic resin amount, and a sufficient effect can be obtained. It's gone.

On the other hand, in the present invention, since the synthetic resin impregnation amount is set to be equal to or less than the weight of the base material, the mechanical strength of the honeycomb material is increased as much as possible and the dielectric constant is lowered as much as possible. Can be suppressed. Then, in the spacing piece 8 which is the honeycomb material of the present embodiment, as described above, the synthetic resin impregnation amount is set to be equal to or less than the weight of the insulator 21 having the honeycomb structure which is the base material. Thus, both the insulating strength and the mechanical strength of the spacing piece 8 can be improved.

That is, in this embodiment, the insulator 21 having a honeycomb structure is used as the base material, and the interval piece 8 is formed by impregnating the synthetic resin with a weight equal to or less than the weight of the base material. The permittivity of the strip 8 can be reduced to approach that of the insulating medium. Therefore, in particular, in the minute gap generated in the disposing portion of the spacing piece 8, it is possible to suppress the electric field concentration on the insulating medium made of a liquid or gas having a small dielectric constant, and to significantly increase the insulating strength of the disposing portion of the spacing piece 8. Can be improved. By impregnating the insulator 21 having the honeycomb structure with the synthetic resin in this manner, the mechanical strength of the spacing piece 8 can be sufficiently improved. Therefore, by using such a spacing piece 8 as a spacing piece between windings, it is possible to improve the insulation reliability and mechanical reliability of the static induction electric device.

Further, the insulator 21 having a honeycomb structure is impregnated with a thermosetting resin such as epoxy resin, polyester resin, and polyimide resin having excellent heat resistance, insulation, and mechanical characteristics. In addition to the insulation strength and mechanical strength of the spacing piece 8, the heat resistance strength can be improved. Therefore, by using such a spacing piece 8 as a spacing piece between windings, decomposed gas or the like is not generated even when the temperature of the windings rises, and the thermal reliability of the static induction electric device is improved. Can be improved.

Further, since the thermosetting resin having a glass transition temperature higher than the maximum operating temperature of the spacing piece 8 is used as the synthetic resin, the heat resistant temperature of the spacing piece 8 is set to the insulating material which is the base material thereof. It becomes higher than the heat resistant temperature. for that reason,
Even when heat is applied to the spacing piece 8 at a temperature equal to or higher than the heat resistant temperature of the base material, the spacing piece 8 is not deteriorated or damaged, and the heat resistance strength of the spacing piece 8 can be improved. it can. In addition, mechanical strength such as compressive force at high temperature can be improved.

[1-3. Modified Example] As a modified example of the first embodiment, for example, a form to which the inventions of claims 11 and 13 are applied can be considered. That is, the axial direction of the cell columns, which is the thickness direction of the insulator 21 having the honeycomb structure, is the vertical direction, and the synthetic resin is impregnated by inverting the vertical direction a plurality of times, and the synthetic resin is cured at each inversion. It is possible to obtain the spacing piece 8 in which more synthetic resin is attached to the axial end portions of the cell columns than to the central portion.

When the spacing piece 8 is constructed in this way,
In addition to obtaining the same action and effect as the first embodiment, it is possible to improve the weakness of the end portion, which tends to be the starting point of the mechanical strength destruction, and further improve the mechanical strength. In addition, a minute gap is less likely to occur in the portion where the spacing piece 8 is arranged, and electric field concentration on the insulating medium can be suppressed.

As another modified example of the first embodiment, a form to which the invention described in claims 12 and 14 is applied can be considered. That is, by curing the synthetic resin while rotating the insulator 21 having a honeycomb structure impregnated with the synthetic resin in a drying oven, the interval piece 8 to which the synthetic resin is evenly adhered can be obtained.

When the spacing piece 8 is constructed in this way,
In addition to the same operation and effect as those of the first embodiment, it is possible to prevent mechanical weak points from occurring in the spacing piece 8 and further improve the mechanical strength of the spacing piece 8. it can. In addition, electric field concentration on the insulating medium can be suppressed in the minute gap generated in the portion in which the constituent insulator having the minute gap honeycomb structure is generated in the portion in which the spacing piece 8 is arranged.

[2. Second Embodiment] [2-1. Configuration] FIG. 3 shows an embodiment in which the invention according to claims 2, 15 and 16 is applied to a spacing piece between windings as a second embodiment of a static induction electric device according to the present invention. It is a figure shown, and is a perspective view showing a part of interval piece. Like the first embodiment, the second embodiment uses an insulator having a honeycomb structure as a base material, but unlike the first embodiment, a synthetic resin is used. Instead of impregnation, a fibrous material is used as a part of the insulator having a honeycomb structure.

That is, as shown in FIG. 3, in the insulator 21 having the honeycomb structure which constitutes the spacing piece 8, at least all or part of one surface thereof has an elastic modulus of ceramic fiber, glass fiber, synthetic fiber or the like. Of the large fibrous material 31. The fiber directions of the fibrous material 31 are arranged in the axial direction of the cell columns. The insulator 21 having the honeycomb structure is manufactured by replacing a part of the plurality of sheet-shaped insulating materials with a sheet-shaped fibrous material by the method described in the first embodiment.

[2-2. Action / Effect] According to the second embodiment having the above-described configuration, the insulator 21 having the honeycomb structure is used as the base material of the spacing piece 8 as in the first embodiment. Therefore, the electric field concentration on the insulating medium can be suppressed in the minute gap generated in the disposition portion of the spacing piece 8, and the insulation strength of the disposition portion of the spacing piece 8 can be significantly improved. Furthermore, in the present embodiment, the fiber direction of the fibrous material 31 is arranged in the axial direction of the cell pillars, which is the thickness direction of the spacing piece 8, so that the mechanical strength of the spacing piece 8 in the thickness direction is increased. Can be improved. Therefore, by using such a spacing piece 8 as a spacing piece between windings, it is possible to improve the insulation reliability and mechanical reliability of the static induction electric device.

[2-3. Modification] As a modification of the second embodiment, for example, claims 3, 5, 6,
A form to which the invention described in 17 is applied can be considered. That is, a solid insulating material having a small friction coefficient, such as a fluorine-based synthetic resin such as polytetrafluoroethylene, is bonded to all or part of at least one surface of the insulator 21 having a honeycomb structure, or a solid insulating material. It is also possible to form the spacing piece 8 by applying a paint to and joining them.

When the spacing piece 8 is constructed in this way,
Similar to the second embodiment, the use of the insulator 21 having the honeycomb structure can improve the insulation strength of the spacing piece 8. Further, in this modified example, the spacing piece 8
The mechanical strength of is improved by the solid insulating material. That is, since the solid insulating material of the spacing piece 8 or the coated surface of the spacing piece 8 has a small friction coefficient, the spacing piece 8 is not used during the assembly work.
When inserting into the gap between the windings, it is possible to reduce the frictional force generated between the spacing piece 8 and a member such as the winding or the insulating cylinder, and the spacing piece can be easily compressed with a small compression force. 8 can be inserted.

As another modification of the second embodiment, for example, a form to which the invention described in claim 18 is applied can be considered. That is, the insulator 2 having a honeycomb structure
It is possible to configure the spacing piece 8 by using No. 1 and arrange the spacing piece 8 so that the spreading direction of the honeycomb structure is the same as the circumferential direction of the winding. When the spacing pieces 8 are arranged in this manner, the insulating strength of the spacing pieces 8 can be improved by using the insulator 21 having the honeycomb structure, as in the second embodiment. In addition, in this modified example, the spreading direction, which is the direction in which the compressive force of the honeycomb structure of the spacing piece 8 is weak, can be matched with the winding circumferential direction in which the mechanical force applied is the smallest, so that when the spacing piece 8 is inserted. It is possible to ensure sufficient mechanical strength to withstand the compressive force.
Therefore, when the spacing piece 8 is inserted into the gap between the windings during the assembly work, the spacing piece 8 can be easily inserted.

[3. Third Embodiment] [3-1. Configuration] FIG. 4 shows a third embodiment of the static induction electric device according to the present invention, wherein
It is a figure which shows one embodiment which applied the invention of 5,16,19 to the insulation support structure between windings, and is a horizontal cross section which shows some insulation support structures. In the third embodiment, among the spacing pieces between the windings, the spacing piece according to the second embodiment or its modification is used as the spacing piece between the inner and outer insulating cylinders as shown in FIG. In addition, the rail, which is a spacing piece between the insulating cylinder and the high-voltage winding, is made of an insulating material having a honeycomb structure and a bonding material.

That is, as shown in FIG.
The rail 7 attached between the second insulating cylinder 4 and the second insulating cylinder 4 has a bonding material (solid insulating material) 41 having a width larger than that of the base material on all or part of one surface of the insulator 21 having a honeycomb structure. It is constructed by joining. The surface of the rail 7 having the bonding material 41 is the high voltage winding 2
It is arranged to be on the side. It should be noted that the second insulating cylinder 4 that supports the high-voltage winding 2 and the first insulating cylinder 3 (not shown)
As the space piece 8 between them, the space piece of the second embodiment or its modification is used.

[3-2. Action and Effect] According to the third embodiment having the above-described configuration, the insulating strength of the rail 7 can be improved by using the insulator 21 having the honeycomb structure. In the present embodiment,
By constructing the rail 7 by bonding the bonding material 41 to the insulator 21 having a honeycomb structure, the rail 7 can be made to have sufficient mechanical strength. Further, by using the spacing piece 8 having high insulation strength and mechanical strength in combination with the rail 7 having high insulation strength and mechanical strength as well, the insulation strength and mechanical strength of the entire insulation supporting structure between the windings can be improved. Strength can be improved.

[4. Fourth Embodiment] FIG. 5 shows the invention of claims 3, 5, 6, 15, 16 and 20 as the fourth embodiment of the static induction electrical equipment according to the present invention. It is a figure showing one embodiment applied to a direction insulating support structure, and is a perspective view showing a part of insulating support structure. In the fourth embodiment, a spacer between a plurality of high-voltage windings arranged in the axial direction is composed of an insulator having a honeycomb structure and a solid insulator.

That is, as shown in FIG. 5, a spacer 9 is provided between a plurality of high-voltage windings 2 arranged in the axial direction via a rail 7 attached to the outer peripheral surface of the second insulating cylinder 4. The spacers 9 are arranged so that a pair of solid insulators (solid insulating material) 51 and an insulator 21 having a honeycomb structure arranged therebetween are integrally joined.

According to the fourth embodiment having such a structure, the insulating strength of the spacer 9 can be improved by using the insulator 21 having the honeycomb structure. Further, in the present embodiment, since the spacer 9 is configured by joining the solid insulator 51 and the insulator 21 having the honeycomb structure, the spacer 9 can retain sufficient mechanical strength. . Therefore, the high voltage winding 2
It is possible to improve the insulation strength and mechanical strength of the entire insulation support structure in the axial direction.

Further, in FIG. 5, the spacer 9 includes an insulator 21 having a honeycomb structure between a pair of solid insulators 51 in the thickness direction (the axial direction of the cell column) having high mechanical strength. Although it is configured to be aligned in the axial direction of the winding, as a modification, a part thereof can be changed in the radial direction of the winding. When configured in this way, the flow of the insulating medium in the arrangement portion of the spacer 9 can be improved,
A cooling effect of the high voltage winding 2 can also be expected.

[5. Other Embodiments] The present invention
The present invention is not limited to the above-described embodiments and modifications thereof, and various other forms such as a combination of the forms can be implemented. For example, in the second to fourth embodiments, as in the first embodiment, it is possible to impregnate the insulator 21 having the honeycomb structure with the synthetic resin. The mechanical strength of the obtained honeycomb material can be further improved. Further, the present invention is not limited to the spacing piece between the windings, but is similarly applicable to various constituent insulators used in the insulating support structure provided in the static induction electric device such as the spacing piece between the winding and the iron core. Applicable. Furthermore, the insulator for electric equipment of the present invention is not limited to a static induction electric equipment, and
By applying the invention described in No. 22, it is also possible to use it as a constituent insulator used in other electric devices such as an insulating busbar and a switchgear. Even when used in these electric devices, it is possible to obtain the same actions and effects as the actions and effects described in each of the above-described embodiments relating to the static induction electric device.

[0073]

As described above, according to the present invention, an insulating material having a honeycomb structure is used as a base material, and the base material is impregnated with a synthetic resin. By using a solid insulating material or the like, it is possible to provide an insulator for electric equipment having high insulation strength and mechanical strength. Then, by using such an insulator for electric equipment having high insulation strength and mechanical strength as a constituent insulator, it is possible to provide an electric equipment having high insulation reliability and mechanical reliability. Furthermore, by using a resin having excellent heat resistance as the synthetic resin, it is possible to provide an insulator for electric equipment having high heat resistance in addition to high insulation strength and mechanical strength, thereby,
It is possible to provide an electric device having high thermal reliability in addition to high insulation reliability and mechanical reliability.

[Brief description of drawings]

FIG. 1 is a perspective view showing a spacing piece between windings in a first embodiment of a static induction electric device according to the present invention.

FIG. 2 is a graph showing the relationship between the compressive strength and the dielectric constant of the honeycomb material with respect to the synthetic resin impregnation amount.

FIG. 3 is a perspective view showing a part of a spacing piece between windings in the second embodiment of the static induction electrical apparatus according to the present invention.

FIG. 4 is a horizontal sectional view showing a part of the insulating support structure between the windings in the third embodiment of the static induction electric device according to the present invention.

FIG. 5 is a perspective view showing a part of an insulating support structure in the axial direction of the winding in the fourth embodiment of the static induction electric device according to the present invention.

FIG. 6 is a horizontal cross-sectional view showing an example of an insulating support structure between windings of a conventional static induction electric device.

FIG. 7 is a vertical sectional view showing an example of an insulating support structure of an axial end portion of a conventional static induction electric device.

[Explanation of symbols]

 1: Low-voltage winding 2: High-voltage winding 3: First insulating cylinder 4: Second insulating cylinder 5, 6, 9: Spacer 7: Rail 8: Spacing piece 11: Main landing iron core 12: Yoke iron core 13: Ring 14: Supporting insulator 21: Insulator having honeycomb structure 31: Fibrous material 41: Laminating material 51: Solid insulator

Continued Front Page (72) Inventor Tsuneji Teranishi 2-1, Ukishima-cho, Kawasaki-ku, Kawasaki-shi, Kanagawa Stock Company Toshiba Hamakawasaki Factory

Claims (22)

[Claims] 1. An electric device comprising a main body structure housed in a container, an insulating support structure made of constituent insulators for insulating and supporting the main body structure, and an insulating medium sealed in the container. In an insulator for electric equipment used for the constituent insulator, the insulator having a honeycomb structure is used as a base material, and the base material is impregnated with a synthetic resin and cured, and the impregnation amount of the synthetic resin. Is set to be less than or equal to the weight of the base material. 2. An electric device comprising a main body structure housed in a container, an insulating support structure made of constituent insulators for insulating and supporting the main body structure, and an insulating medium enclosed in the container. In the insulator for electric equipment used for the constituent insulator, the insulator having a honeycomb structure is used as a base material, and at least a part of at least one surface of the base material is made of a fibrous material. An insulator for electric equipment, wherein the fiber direction is arranged in the axial direction of the cell pillar. 3. An electric device comprising a main body structure housed in a container, an insulating support structure made of constituent insulators for insulating and supporting the main body structure, and an insulating medium sealed in the container. In the insulator for electric equipment used for the constituent insulator, an insulator having a honeycomb structure is used as a base material, and a solid insulating material is bonded to a part of at least one surface of the base material. Insulators for electrical equipment. 4. An electric device comprising a main body structure housed in a container, an insulating support structure made of constituent insulators for insulating and supporting the main body structure, and an insulating medium sealed in the container. In the insulator for electric equipment used for the constituent insulator, the insulator having a honeycomb structure is used as a base material, and at least a part of at least one surface of the base material is made of a fibrous material. An insulator for an electric device, wherein fiber directions are arranged in an axial direction of cell columns, and a solid insulating material is joined to a part of at least one surface of the base material. 5. The insulator for electric equipment according to claim 3, wherein the solid insulating material has a small friction coefficient. 6. The solid insulating material has a surface coated with a coating material.
Insulator for electrical equipment according to any one of items 1 to 3. 7. The insulator for electric equipment according to claim 3, wherein the solid insulating material has a width larger than that of the base material. 8. An insulating base material having the honeycomb structure is impregnated with a synthetic resin and cured, and the impregnated amount of the synthetic resin is set to be equal to or less than the weight of the base material. The insulator for electric equipment according to any one of claims 2 to 7, which is characterized. 9. The insulator for electric equipment according to claim 1, wherein the synthetic resin is selected from an epoxy resin, a polyester resin, and a polyimide resin. 10. The synthetic resin is a thermosetting resin having a glass transition temperature higher than the maximum operating temperature of the constituent insulator, and the synthetic resin is a thermosetting resin. Insulator for electrical equipment. 11. The adhesion amount of the synthetic resin to the base material of the insulator having the honeycomb structure is larger than that of the central portion at the axial end portion of the cell pillar of the base material. The insulator for an electric device according to claim 8. 12. The adhesion amount of the synthetic resin to the base material of an insulator having the honeycomb structure is uniform over the entire base material.
11. The insulator for electric equipment according to any one of claims 1 to 10. 13. The method for producing an insulator for an electric device according to claim 11, wherein the axial direction of the cell pillars of the base material of the insulator having the honeycomb structure is the vertical direction, and the upper and lower sides of the base material. The method for producing an insulator for an electric device is characterized in that the synthetic resin is impregnated by reversing a plurality of times, and the synthetic resin is hardened every time it is reversed. 14. The method for manufacturing an insulator for an electric device according to claim 12, wherein a base material of the insulator having the honeycomb structure is impregnated with a synthetic resin, and then the base material is synthesized while being rotated. A method for producing an insulator for an electric device, which comprises curing a resin. 15. An electric device in which a main body structure is housed in a container, an insulating support structure made of constituent insulators is provided to insulate and support the main body structure, and an insulating medium is enclosed in the container. And that an insulator for electric equipment selected from the insulator for electric equipment described in any one of claims 1 to 12 is used for a selected portion of the constituent insulator. Characteristic electrical equipment. 16. A main body structure including an iron core and a plurality of windings wound around the core is housed in a container, and an insulating support structure made of constituent insulators is provided to insulate and support the main body structure. In a static induction electric device in which an insulating medium is enclosed in the container, an insulator for electric devices according to any one of claims 1 to 12 is provided in a selected portion of the constituent insulators. A static induction electric device, characterized in that an insulator for electric devices selected from the inside is used. 17. The spacing insulator, which is provided between the iron core and the winding and supports the winding in a radial direction,
A spacing piece provided in a gap between the windings to support the winding in a radial direction, of the entire spacing pieces provided between the iron core and the winding and between the windings. The insulator for electric equipment selected from the insulators for electric equipment described in the above claims 3 to 7 is used in the selected portion. Stationary induction electrical equipment. 18. The spacing insulator, which is provided between the iron core and the winding and supports the winding in a radial direction,
A spacing piece provided in a gap between the windings and supporting the winding in a radial direction, of the entire spacing pieces provided between the iron core and the winding and between the windings. An insulator for electric equipment selected from the insulators for electric equipment according to any one of claims 1 to 12 is used for the selected portion, and the base constituting the insulator for electric equipment is used. 17. The static induction electric device according to claim 16, wherein the material is arranged such that a spreading direction thereof is the same as a circumferential direction of the winding. 19. An insulating cylinder is arranged between the windings, and the constituent insulator is a spacing piece provided in a gap between the insulating cylinder and the winding to support the winding in a radial direction. The insulating material for electric equipment according to claim 7 is used in a selected portion of the entire spacing piece provided between the insulating cylinder and the winding. The static induction electric device according to any one of claims 16 to 18. 20. An insulating cylinder is arranged between the windings, and the constituent insulators are distributed evenly over the entire circumference of the outer peripheral surface of the insulating cylinder to support the winding in the radial direction. A winding including an interval piece, the winding outside the insulating cylinder is a disk winding constituted by a plurality of layers of coil sections arranged in the axial direction, and each coil section is the outer peripheral surface of the insulating cylinder. A spacer wound around the spacing piece in a disk shape, wherein the constituent insulator is further provided outside the spacing piece between adjacent coil sections of the disk winding and axially supporting the coil section. Wherein an insulator for electric equipment selected from among the insulators for electric equipment according to any one of claims 1 to 12 is used in a selected portion of the spacer. Claims 16 to 19 Stationary induction electrical apparatus according to any one of the at. 21. An insulating busbar in which a high-voltage conductor is housed in a container, an insulating support structure made of a constituent insulator is provided to insulate and support the high-voltage conductor, and an insulating medium is sealed in the container. An insulator for electric equipment selected from the insulator for electric equipment according to any one of claims 1 to 12 is used for a selected portion of the constituent insulators. Insulation busbar to do. 22. A main body structure including an opening / closing portion is housed in a container, an insulating support structure made of constituent insulators is provided to insulate and support the main body structure, and an insulating medium is enclosed in the container. In the switchgear, the insulating material for electrical equipment selected from the insulating material for electrical equipment according to any one of claims 1 to 12 is used for a selected part of the insulating material. Switchgear characterized by having.