JPH07262854A - Suspension insulator - Google Patents

Abstract

PURPOSE:To increase dielectric breakdown strength without degrading mechanical strength by providing specified layers in the suspension insulator where both the inner and outer circumferential surfaces of the head section of a specified porcelain main body are coated with glaze. CONSTITUTION:In the suspension insulator 10 provided with first coating layers 12 which are coated with glaze at both the inner and outer circumferential surfaces of the head section of a porcelain main body 11 where a cylindrical head section 11b closed at its upper end section, is provided at its apex section, the surface side of the first coating layer 12 in the inner circumferential surface of the head section 11b is provided with a second coating layer 13 which is higher in dielectric breakdown strength than the first coating layer 12. The second coating layer 13 is desirably formed at least in the inner circumferential surface of a corner section 11b3 which is a boundary section between an upper end horizontal section 11b2 and a side upright section in the head section of the porcelain main body 11.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a suspended porcelain having a porcelain body glazed, and more particularly to a suspended porcelain having a high dielectric breakdown strength.

[0002]

2. Description of the Related Art Currently, suspension insulators are required to have mechanical characteristics such as high mechanical strength and electrical characteristics such as high dielectric breakdown strength as the capacity and voltage of transmission lines increase. Among these, as a means for improving the mechanical strength of the suspension insulator, a glaze layer is formed by applying a glaze having a smaller thermal expansion coefficient than that on the peripheral surface of the porcelain body so that the compressive stress due to the compression grace is internally contained. A means for increasing mechanical strength is generally adopted. Further, as means for increasing the dielectric breakdown strength and improving electric characteristics such as steep wave characteristics, there are known means disclosed in JP-A-63-212525 and JP-A-4-141917. Among these publications, the means for improving the dielectric breakdown strength disclosed in the former publication uses a glaze having a special composition, and the means for improving the dielectric breakdown strength disclosed in the latter publication is a glazed porcelain body. By firing under reduced pressure,
Each is intended to reduce the amount of bubbles present in the fine structure in the glaze layer and prevent the breakdown voltage of the suspended insulator from being lowered due to the bubbles.

[0003]

However, since the glaze layer functions to improve the mechanical strength of the porcelain body by allowing the porcelain body to have a compressive stress, the composition of the conventional glaze is changed. There is a limit, the former means is not a good means in this respect, and the low pressure firing is difficult because the firing method itself is difficult to fire a large amount of the porcelain body, and the latter means is also good. Not a means. Therefore, an object of the present invention is to improve the dielectric breakdown strength of the suspended insulator without reducing the mechanical strength by adopting a means different from the reduction of bubbles in the glaze layer such as these means. .

[0004]

According to the present invention, a glaze is formed on both the inner and outer circumferences of the head of a porcelain body having a cylindrical head with its upper end closed and the outer circumference of the head. Is a suspension insulator provided with a first coating layer formed by coating with, the suspension insulator being on the surface side of the first coating layer on the inner peripheral surface of the head of the porcelain body, or on the head. The inner peripheral surface itself of the part is provided with a second coating layer having a higher dielectric breakdown strength than the first coating layer. In the suspension insulator, the second coating layer is formed at least on an inner peripheral surface of a corner portion which is a boundary portion between a horizontal upper end portion and a side upright portion of the head of the porcelain body. When the porcelain body is a porcelain body having a corrugated hooking portion on which the cement mortar is hooked on the inner peripheral surface of the standing portion of the head, the second coating layer is the head. The mortar extends from the inner peripheral surface of the corner to at least a part of the hooking portion, and the porcelain body is cement mortar on the surface of the first coating layer on the inner peripheral surface of the standing portion of the head. In the case of a porcelain body having a hooking portion to which a large number of sands to which the
It is preferable that the coating layer of (1) extends from the inner peripheral surface of the corner of the head portion to the boundary of the hooking portion.

The coating material for the second coating layer of the suspension insulator according to the present invention is preferably a raw material for porcelain containing cordierite, mullite, etc., and these are the first coating layer, the glaze layer and the heat of the porcelain body. It is preferable to select it appropriately in relation to the expansion coefficient.

[0006]

When a voltage is applied to the suspension insulator having such a structure, an electric field is generated at the corner on the inner peripheral side, which is the boundary between the upper end horizontal portion and the side rising portion of the head of the porcelain body. concentrate. However, in the suspension insulator, since the second coating layer having a higher dielectric breakdown strength than the first coating layer which is a glaze layer is formed on the inner peripheral surface of the above-mentioned corner, only the conventional glaze layer is formed. Dielectric breakdown strength is greatly improved compared to the suspension insulator provided.

However, in the suspension insulator, a glaze having a low coefficient of thermal expansion is generally used as the glaze in order to impart compressive stress to the porcelain body to impart mechanical strength. In this case, the coating material forming the second coating layer (referred to as the second coating material) may have a thermal expansion coefficient similar to that of the porcelain body when the thermal expansion coefficient of the glaze is sufficiently low. When the thermal expansion coefficient of the glaze is not so low, it is preferable that the thermal expansion coefficient thereof is sufficiently lower than that of the porcelain body, so that the effect of the compressive stress by the first coating layer which is the glaze layer is maintained. In this case, since the difference in the coefficient of thermal expansion between the porcelain body and the coating material with respect to the intended mechanical strength changes depending on the composition of the porcelain body and the glaze, it is not possible to determine this difference in coefficient of thermal expansion to a predetermined value. Can not. When the coefficient of thermal expansion of the second coating material is too low as compared with the coefficient of thermal expansion of the porcelain body,
A peeling phenomenon may occur in the second coating layer. Therefore, while using a porcelain raw material containing cordierite, mullite, etc., having a low coefficient of thermal expansion as the second coating material, it is possible to balance the coefficients of thermal expansion among the second coating layer, the first coating layer and the porcelain body. It is preferable to take.

[0008]

【Example】

(First Suspension Insulator) FIGS. 1 and 2 show a first suspension insulator according to a first embodiment of the present invention. The suspension insulator 10 includes a porcelain body 11, a first coating layer 12 and a second coating layer 13. And a cap 14 and a pin 15. The porcelain body 11 is an umbrella portion 11a
And a head portion 11b, and the head portion 11b has a cylindrical shape having a top portion. The suspension insulator 10 is referred to as a sundress suspension insulator, and the inner and outer surfaces of the side upright portions forming the head portion 11b are formed into corrugated portions 11b1 having a corrugated uneven shape. The corrugation portion 11b1 hooks the cement mortar 16a that fixes the cap 14 that is fitted to the outer circumference of the head 11b, and the cement mortar 16b that fixes the pin 15 that fits to the inner circumference of the head 11b. Then, the porcelain body 11
, Which functions to firmly connect the cap 14 and the pin 15 to each other.

In such a porcelain body 11, as shown in FIG. 2, the first coating layer 1 is formed on both inner and outer peripheral surfaces of the head.
2 is formed, and the second coating layer 13 is formed on the surface of the first coating layer 12 on the inner peripheral surface of the head portion 11b. The first coating layer 12 is formed by coating the glaze, and the glaze is the porcelain body 11
With a lower coefficient of thermal expansion, the porcelain body 1
1 is given a compressive stress to improve the mechanical strength.
Note that the inner and outer peripheral surfaces of the umbrella portion 11a of the porcelain body 11 are coated with a glaze of a different type from the glaze of the first coating layer 12.

The second coating layer 13 is a glaze layer
It is a layer having a higher dielectric breakdown strength than the coating layer 12,
As the coating material, a porcelain raw material powder having a thermal expansion coefficient equal to or lower than that of the porcelain main body 11, for example, a porcelain raw material powder containing components such as cordierite and mullite is adopted. The second coating layer 13 is the head 11 of the porcelain body 11.
It extends to a predetermined portion of the upper end horizontal portion 11b2 in b, the annular corner portion 11b3, which is the boundary portion, and the corrugation portion 11b1.

(First Destruction Experiment of Suspended Insulator) In this experiment, a suspended insulator having a changed length in the corrugation portion 11b1 of the second coating layer 13 of the sandless suspended insulator 10 shown in FIGS. 1 and 2 was used. A voltage is applied in insulating oil, and the tip of the corner 11b3 of the head 11b of the suspension insulator 10 is used as a reference point P. The distance from the reference point P of the second coating layer 13 to the corrugated portion 11b1 and the breakdown voltage The relationship was examined and the obtained results are shown in the graph of FIG. For each suspension insulator, the dried green body of the porcelain body is coated with glaze on both the inner and outer peripheral surfaces of the head portion 11b to form a first portion.
Under the condition that the coating layer is formed, the second coating material is coated on a predetermined portion to form the second coating layer, and the green body of the porcelain body, the first coating layer and the second coating layer are sufficiently sintered. The porcelain porcelain obtained by firing was formed by bonding the cap 14 and the pin 15 via cement mortar. The composition of the green body of the porcelain body, the glaze and the second coating material,
The shape of the porcelain body 11 and the thicknesses of the first coating layer 12 and the second coating layer 13 are as follows.

Greenware of porcelain body: Alumina-containing feldspar ordinary porcelain material (feldspar 30%, porcelain 5%, clay 40%, alumina 10%, silica 15%), glaze: soda lime glass (feldspar 40%, dolomite) 5%, talc 8%, clay 12
%, Quartz 35%), second coating material: cordierite porcelain (10% feldspar, 15% porcelain stone, 65% clay, 10% magnesite).

Shape of porcelain body 11: As shown in FIG. 1, the thickness of the first coating layer 12 is 0.3 mm and the thickness of the second coating layer 13 is 0.5 mm.

Referring to the graph of FIG. 3, the site where the second coating layer 13 is formed is largely related to the breakdown voltage, and when the tip of the corner 11b3 of the head 11b of the suspension insulator 10 is taken as the reference point P, When the second coating layer 13 extends from the reference point P to the corrugation portion 11b1 (tip distance +), the breakdown voltage increases as the tip distance increases, and conversely, the second coating layer When 13 is retracted from the reference point P with respect to the corrugation portion 11b1 (tip distance −), the breakdown voltage tends to decrease as the tip distance recedes. Therefore, it is necessary to form the second coating layer 13 at least on the corner 11b3 of the head portion 11b of the suspension insulator 10, and it is understood that the effect is higher as the tip of the second coating layer 13 is extended.

(Fracture Experiment 2 of First Suspended Insulator) In this experiment, the corrugation portion 11b1 of the second coating layer 13 of the sandless suspended insulator 10 shown in FIGS. A suspension insulator having a coating layer 13 formed of various second coating materials having different dielectric breakdown strengths, and a second coating layer 13 having the first coating layer 12 formed of various glazes having different dielectric breakdown strengths.
In the same manner as in the destruction experiment 1, a voltage is applied in insulating oil by adopting a conventional suspension insulator that does not include a second coating layer 13 made of a second coating material and a first coating layer 12 made of a glaze. The relationship between the dielectric breakdown strength and the breakdown voltage of each suspended insulator was examined, and the results shown in the graph of FIG. 4 were obtained. However, in the same graph, the dielectric breakdown strength A
The value is the limit value of the conventional dielectric breakdown strength of the glaze layer, B of the breakdown voltage
The value indicates the limit value of the breakdown voltage of the conventional suspension insulator. Referring to the graph, in the suspension insulator (white circle) having the second coating layer 13, the breakdown voltage of the suspension insulator can be significantly improved by selecting a coating material having high dielectric breakdown strength. On the other hand, in the conventional suspension insulator (black circle) not provided with the second coating layer 13, it can be seen that there is a limit to the improvement of the breakdown voltage of the suspension insulator even by selecting the glaze having high dielectric breakdown strength. Therefore, in the suspension insulator 10, its head 11
When the inner peripheral surface of b is provided with the second coating layer 13, as compared with the case where only the first coating layer 12 is provided,
The breakdown voltage of the suspension insulator can be significantly increased.

(Second Suspension Insulator) FIGS. 5 and 6 show a second suspension insulator according to a second embodiment of the present invention. The suspension insulator 20 includes a porcelain body 21, a first coating layer 22 and a second suspension insulator. The coating layer 23 is provided, and the cap 24 and the pin 25 are provided. Porcelain body 21
Is composed of an umbrella portion 21a and a head portion 21b.
b has a cylindrical shape having a top. The suspension insulator 2
0 is what is called a suspended insulator with sand, and head 2
Innumerable sands are adhered to the surface of the first coating layer 22 on both the inner and outer surfaces of the side upright portions constituting 1b to form the sanded hook portions 22a. Like the corrugation portion 11b1 of the first suspension insulator 10, the sanded hook portion 22a hooks the cement mortar 26a for fixing the cap 24 fitted to the outer circumference of the head portion 21b, and the inner circumference of the head portion 21b. The cement mortar 26b for fixing the pin 25 to be fitted is hooked to the porcelain body 21.
, And functions to firmly connect the cap 24 and the pin 25.

The suspension insulator 20 has a structure similar to that of the first suspension insulator 10 except for the structure of the sanded hook portion 22a of the porcelain body 21, and as shown in FIG. The first coating layer 22 is formed on the inner surface of the head 21b.
The second coating layer 23 is formed on the surface of the. The glaze forming the first coating layer 22 and the coating material forming the second coating layer 23 are similar to the glaze and the coating material of the first suspension insulator 10. The second coating layer 23 is the head 2 of the porcelain body 21.
1b, it extends to the upper end horizontal portion 21b2, the annular corner portion 21b3 that is the boundary portion, and the tip of the sanding hook portion 22a.

Although the above-mentioned respective breaking tests are also attempted for the sanded suspension insulator 20, the same results as the sandless suspension insulator 10 have been confirmed. In addition, in the suspension insulator 20, the second coating layer 22 is extended only to the sand fixing boundary portion, because the reason why when the second coating layer 22 covers the sand portion, the effect of retaining cement mortar is impaired. Is.

(Third Suspension Insulator) FIG. 7 shows a third suspension insulator according to a third embodiment of the present invention. The suspension insulator is a modification of the first suspension insulator 10 according to the first embodiment, and the head has a first coating layer that is a glaze layer only on its outer peripheral surface. The suspension insulator 10A includes a porcelain body 11, a first coating layer 12 and a second coating layer 13, and a cap 14 and a pin 15. The porcelain body 11 is composed of an umbrella portion 11a and a head portion 11b, and has a first coating layer 12 on the outer peripheral surface of the head portion 11b and a second coating layer 13 on the inner peripheral surface of the head portion 11b. ing. Since the other structure of the suspension insulator 10A is the same as that of the first suspension insulator 10, the other structures are given the same reference numerals as those of the first suspension insulator 10 and their detailed description is omitted. The part indicated by the chain double-dashed line in the figure shows a glaze layer formed by coating a glaze of a different type from the glaze of the first coating layer 12.

In the suspension insulator 10A, however, the second coating material forming the second coating layer 13 has a composition of 13% feldspar, 10% magnesite, 32% clay, and 45% quartz. Has been done,
When a destruction test similar to the destruction test 1 of the first suspension insulator was tried, the breakdown voltage was 750 kV. As a comparative example, when a similar breaking test was attempted for a conventional suspended insulator having no second coating layer 13, the breaking voltage was 6
It was 30 kV, and it was confirmed that the suspension insulator 10A had a significantly increased dielectric breakdown strength as compared with the conventional suspension insulator.

[Brief description of drawings]

FIG. 1 is a partial vertical sectional view of a suspension insulator according to a first embodiment of the present invention.

FIG. 2 is an enlarged vertical cross-sectional view of a main part of the suspension insulator.

FIG. 3 is a graph showing the relationship between the length of the second coating layer and the breakdown voltage in the suspension insulator according to the first embodiment of the present invention.

FIG. 4 is a graph showing the relationship between the dielectric breakdown strength of the second coating layer made of the second coating material of the suspension insulator and the glaze layer of the conventional suspension insulator and the breakdown voltage of the suspension insulator.

FIG. 5 is a partial longitudinal sectional view of a suspension insulator according to a second embodiment of the present invention.

FIG. 6 is an enlarged vertical sectional view of a main part of the suspension insulator.

FIG. 7 is an enlarged vertical sectional view of a main part corresponding to FIG. 2 of a suspension insulator according to a third embodiment of the present invention.

[Explanation of symbols]

10, 10A, 20 ... Suspended insulators 11, 21 ... Porcelain body, 11b, 21b ... Head, 11b1 ... Corrugation part, 11b2, 21b2 ... Top horizontal part, 11b3, 21b3
... Corners and 12,22 ... First coating layer, 22a
... Sanding hooks, 13, 23 ... Second coating layers, 14, 24 ... Caps, 15, 25 ... Pins.

Claims (5)

[Claims] 1. A first coating layer formed by coating a glaze on both inner and outer peripheries of the head of a porcelain body having a closed cylindrical head at the top. In the suspension insulator, a second coating layer having a higher dielectric breakdown strength than the first coating layer is provided on the surface side of the first coating layer on the inner peripheral surface of the head of the porcelain body. Suspended insulator. 2. A suspension insulator having a first coating layer formed by coating a glaze on the outer peripheral surface of a head of a porcelain body having a cylindrical head with a closed top at the top. A suspended insulator characterized in that a second coating layer having a higher dielectric breakdown strength than the first coating layer is provided on the inner peripheral surface of the head of the porcelain body. 3. The suspension insulator according to claim 1, wherein the second coating layer is at least a corner portion which is a boundary portion between a horizontal upper end portion and a side upright portion of the head of the porcelain body. A suspended insulator characterized by being formed on the inner peripheral surface. 4. The suspension member according to claim 1, 2 or 3, wherein the porcelain body is formed in a corrugated shape in which cement mortar is retained on the inner peripheral surface of the upright portion of the head portion. A porcelain body including: a suspension insulator, wherein the second coating layer extends from an inner peripheral surface of a corner portion of the head to at least a part of the hooking portion. 5. The suspension insulator according to claim 1 or 3, wherein the porcelain body has a sand in which cement mortar is hooked on the surface of the first coating layer on the inner peripheral surface of the standing portion of the head. It is a porcelain body in which a fixed hooking portion is formed, wherein the second coating layer extends from an inner peripheral surface of a corner of the head portion to a boundary portion of the hooking portion. Suspended insulator.