JP2006166672A - Arrestor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To give a specified surface pressure between arrestor elements and easily remove an arrestor mold body in the voltage resistance test or the like of equipment. <P>SOLUTION: An arrestor mold body 6 including an arrestor element stack 61 is mounted detachably on a bushing 2 arranged airtightly in the opening 1a of an equipment case 1. This arrestor is provided with a rubber mold body 67 molded integrally astride a connecting conductor 62 and a push metal fitting 65, around an arrestor element stack 61 being constituted by stacking arrestor elements 61a. A first spring (spring on high-voltage side) 63 is arranged, with its upper half projected from a cylinder 62b, on the cylinder 62b of the connecting conductor 62, and also a second spring (spring on low-voltage side) 66 is arranged, with its lower half projected from a pit 65c, in the pit 65c of the push metal fitting 65. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an arrester, and more particularly, to an arrester that can easily remove an arrester mold body that is detachably mounted in a bushing.

  In general, gas insulated switchgear installed in power plants, substations, etc. are provided with arresters to protect electrical equipment such as switchgears and transformers from abnormal voltages entering from the track during lightning strikes. Yes.

  Conventionally, as such an arrester, as shown in FIG. 7, an arrester element laminated body 100 formed by laminating a plurality of non-linear resistance elements (hereinafter referred to as “arrestor elements”) mainly composed of zinc oxide. An insulating wall that is erected on the bottom 110a of the tank 110 and supported through an insulating support cylinder 120 (for example, Non-Patent Document 1), or as shown in FIG. It is known that a bushing 220 is attached airtightly and an arrester element laminate 230 is detachably attached to the bushing 220 (for example, Patent Document 1).

  However, in the former arrester, in order to equalize the voltage sharing of the arrester elements constituting the arrester element stack 100, a large shield 130 must be disposed on the high voltage side of the arrester element stack 100. For this reason, there exists a difficulty that apparatus itself enlarges, and when carrying out the withstand voltage test of the gas insulated switchgear which has the arrester element laminated body 100, the arrester element laminated body 100 is made from a main circuit conductor (not shown). Since it has to be separated, it is necessary to provide a separation device (not shown), which causes a problem that the structure of the device becomes complicated.

  In the latter arrester, the structure is simplified because it is not necessary to provide a separation device, and there is no need to collect or fill the insulating gas in the device case 210 when performing a withstand voltage test. However, there were the following difficulties.

  First, in the arrester having such a configuration, the inner peripheral surface of the bushing 220 is formed by bringing the outer peripheral surface of the insulating resin mold body 240 provided on the outer periphery of the arrester element stack 230 into close contact with the inner peripheral surface of the bushing 220. It is necessary to prevent a gap from being generated at the interface between the surface and the outer peripheral surface of the mold body 240. However, if the outer peripheral surface of the mold body 240 is brought into close contact with the inner peripheral surface of the bushing 220, the mold body 240 is greatly removed. Axial force is required.

  Second, in order to ensure contact between the plurality of arrester elements, when the pressing force toward the tip of the bushing 220 is applied to the mold body 240, the outer peripheral surface of the mold body 240 is more closely attached to the inner peripheral surface of the bushing 220. However, when the mold body 240 is removed, a larger axial force is required.

  Third, since the number of stacked arrester elements corresponding to the system voltage is determined in consideration of a predetermined varistor voltage, the number of stacked arrester elements increases as the arrester is applied to the high-voltage line. As a result, the total length of the arrester element stack 230 is inevitably increased. When the total length of the arrester element stack 230 is increased, the interface length between the mold body 240 and the bushing provided on the outer periphery of the arrester element stack 230 is increased. Therefore, when removing the mold body 240, a larger axial force is required.

  Fourth, since the device case 210 as a ground layer exists on the outer periphery of a part of the arrester element laminate 230, it is difficult to make the voltage sharing of the arrester element 230a uniform. It is limited to a medium-voltage line of about 22/33 kV.

IEEJ Technical Report No. 851 7 (Fig. 2.10) Japanese Patent Laid-Open No. 1-232681 (FIG. 1)

  The present invention has been made to solve the above-described problems, and can provide a predetermined surface pressure between the arrester elements when the arrester mold body is mounted. The purpose of the present invention is to provide an arrester from which the body can be easily removed.

  An arrester according to a first aspect of the present invention includes a bushing disposed in an opening of a device case that houses an electric device so as to cover the opening in an airtight manner, and an insertion hole of the bushing in the insertion hole of the bushing. The arrester mold body is detachably mounted from the outside, and the arrester mold body includes an arrester element laminate formed by laminating a plurality of arrester elements, and a rubber mold body provided on the outer periphery of the arrester element laminate. And a first spring that is biased by a spring force by pressing in the axial direction is disposed at the tip of the arrester mold body.

  According to a second aspect of the present invention, in the arrester according to the first aspect, the rear end portion of the arrester mold body is provided with a second spring to which a spring force is urged by pressing in the axial direction. It is what.

  According to a third aspect of the present invention, in the arrester according to the second aspect, the spring constant of the first spring is set lower than the whole spring constant of the second spring.

  According to a fourth aspect of the present invention, in the arrester according to any one of the first to third aspects, a main circuit connector connected to a main circuit conductor of an electrical device is provided at the top of the bushing. The connection conductor connected to the main circuit connector is provided integrally with the arrester mold body at the tip of the arrester mold body.

  According to a fifth aspect of the present invention, in the arrester according to the fourth aspect, the connection conductor includes a cylindrical portion for disposing the first spring.

  According to a sixth aspect of the present invention, in the arrester according to the fifth aspect, the main circuit connector includes a connection conductor insertion portion, and the cylindrical portion of the connection conductor is plug-in connected to the connection conductor insertion portion. .

  The arrester according to the first to sixth aspects of the present invention has the following effects.

  First, the arrester mold body is constituted by the synergistic effect of the spring force of the first spring disposed at the tip end portion of the arrester mold body and the spring force of the second spring disposed at the rear end portion of the arrester mold body. A predetermined surface pressure can be applied between the arrester elements.

  Second, by setting the spring constant of the first spring to be lower than the whole spring constant of the second spring, when the arrester mold body is mounted, the arrester mold body is moved by the entire pressing force of the second spring. The bushing can be pressed toward the tip of the bushing, and when removing the arrester mold body, the arrester mold body is released by the spring force of the first spring by releasing the pressing of the second spring. Can be pushed out to the rear end side.

  Third, by providing a cylindrical portion on the connection conductor provided integrally at the tip of the arrester mold body, the first spring can be easily disposed in the cylindrical portion, and the main circuit connection By providing the connection conductor insertion portion in the child, the cylindrical portion in which the first spring is disposed in the connection conductor insertion portion can be easily plug-in connected.

Hereinafter, preferred embodiments to which the arrester of the present invention is applied will be described with reference to the drawings. Here, the “tip portion” of the arrester mold body refers to an end portion on the high-pressure side of the arrester mold body, and corresponds to the upward direction in the drawing. In addition, the “rear end” of the arrester mold body refers to an end opposite to the front end, and corresponds to the downward direction in the figure.
[Example 1]
FIG. 1 is a partial cross-sectional view showing an example of a 66/77 kV class arrester of the present invention.

In the figure, an electric device having an arrester according to the present invention includes a device case 1 that hermetically accommodates an electric device (not shown) such as a switch, and the device case 1 includes, for example, SF _6. Insulating gas such as gas is filled. Also, an opening 1a is provided at the bottom of the device case 1, and the opening 1a has its own front end located in the device case 1, and the opening 1a is formed at the rear end of itself. A bushing 2 is disposed so as to be hermetically covered, and an arrester mold body 6 including an arrester element stack 61 described later is detachably mounted in the bushing 2.

  The bushing 2 includes a hard and insulating bushing body 3 made of an epoxy resin molded body and the like, and a high-pressure shield body 4 embedded concentrically with the bushing body 3 at the tip of the bushing body 3.

  The bushing body 3 includes an upper end closed cylindrical portion (hereinafter referred to as “upper cylindrical portion”) 51 having an insertion hole (hereinafter referred to as “upper insertion hole”) 51 a for accommodating the upper half portion of the arrester mold body 6. A cylindrical portion (hereinafter referred to as “lower cylindrical portion 52”) 52 having an insertion hole (hereinafter referred to as “lower insertion hole”) 52a for accommodating the lower half portion of the arrester mold body 6; A cylindrical portion (hereinafter referred to as “intermediate cylindrical portion”) 53 having an insertion hole (hereinafter referred to as “tapered insertion hole”) 53a for accommodating a conical portion 67b described later. An annular mounting flange 52b projecting in the radial direction is continuously provided on the outer periphery of the upper position of. Here, the diameter of the lower insertion hole 52a is larger than the diameter of the upper insertion hole 51a, and the tapered insertion hole 53a extends from the lower end of the upper insertion hole 51a to the upper end of the lower insertion hole 52a. The upper insertion hole 51a and the lower insertion hole 52a are communicated with each other through the tapered insertion hole 53a. Further, the outer diameter of the lower cylindrical portion 52 is substantially the same as or slightly smaller than the diameter of the opening 1a of the device case 1, and the outer diameter of the mounting flange 52b is larger than the diameter of the opening 1a of the device case 1. It is said that.

  The high-pressure shield body 4 includes a bell-shaped shield body 41 concentrically embedded in the upper cylindrical portion 51 from the closed portion 51 b to the lower end portion of the upper cylindrical portion 51, and the horizontal direction of the shield main body 41. A cylindrical portion (hereinafter referred to as “connection conductor insertion portion”) 42 protruding above the closing portion 51b at the center of the portion, and connected to a main circuit conductor (not shown) connected to the upper portion of the connection conductor insertion portion 42. Main circuit connector 43. Here, the side wall portion 41 a of the shield body 41 is formed so as to expand in a conical shape from the upper end portion toward the lower end portion, and the axial length thereof is from the closing portion 51 b of the upper cylindrical portion 51 to the intermediate cylindrical portion 53. It is set as the length which reaches the upper end part vicinity. The connection conductor insertion portion 42 functions as an insertion hole for a connection conductor 62 (described later) of the arrester mold body 6, and the main circuit connector 43 provided at the upper end of the connection conductor insertion portion 42 is the arrester mold body 6. It also has a function as a stopper of a coil-shaped first spring 63 described later.

  As shown in the drawing, the high-voltage shield body 4 having such a configuration projects the main circuit connector 43 from the closed portion 51 b of the upper cylindrical portion 51, and the side wall portion 41 a is positioned within the side wall portion 51 b of the upper cylindrical portion 51. In this way, it is buried concentrically with the upper cylindrical portion 51.

  In the bushing 2 having such a configuration, the upper cylindrical portion 51 and the intermediate cylindrical portion 53 of the bushing 2 are positioned in the device case 1, and the lower cylindrical portion 52 is led out of the device case 1 through the opening 1a. Thus, the upper surface of the mounting flange 52b is brought into contact with the lower surface of the peripheral edge portion of the opening 1a of the device case 1. Therefore, the bushing 2 is attached to the device case 1 by interposing an O-ring 1c in an annular groove 1b provided at the peripheral edge of the opening 1a of the device case 1 and fastening a bolt 52c disposed on the mounting flange 52b. It can attach to the opening part 1a of this.

  As shown in FIG. 2, the arrester mold body 6 includes an arrester element laminated body 61 formed by laminating a plurality of arrester elements 61a mainly composed of zinc oxide, and the upper end side (high-pressure side) of the arrester element laminated body 61. ), A coil-shaped first spring (hereinafter referred to as “high-pressure side spring”) 63 disposed on the upper end side (high voltage side) of the connection conductor 62, and an arrester element stack. A second spring (hereinafter referred to as “a spring”) composed of a pressing metal 65 disposed on the rear end side (low pressure side) of the body 61 and a plurality of coiled springs concentrically disposed on the lower surface side of the pressing metal 65. 66) and a rubber mold body 67 made of silicone rubber or the like that is integrally molded across the connection conductor 62 and the push fitting 65 on the outer periphery of the arrester element laminate 61. Here, the outer surface shape of the rubber mold 67 is formed to correspond to the inner peripheral surface shape of the insertion hole (the upper insertion hole 51a, the lower insertion hole 52a, and the tapered insertion hole 53a) of the bushing 2. Specifically, a small-diameter portion 67a that contacts the inner peripheral surface of the upper insertion hole 51a is formed on the upper end side (high pressure side) side of the rubber mold body 67, and an inner peripheral surface of the tapered insertion hole 53a is formed on the intermediate portion. The conical portion 67b that abuts is provided with a large-diameter portion 67c that abuts against the inner peripheral surface of the lower insertion hole 52a on the lower end side (low pressure side). The spring constant of the high-pressure side spring 63 is set lower than the overall spring constant of the low-pressure side spring 66 (the total spring constant of the plurality of low-pressure side springs). The number of arrester elements 61a corresponding to the system voltage is determined in consideration of a predetermined varistor voltage. This embodiment is applied to a 66 kV high-voltage line.

  The connection conductor 62 includes a disk portion 62a that is substantially the same shape as the arrester element 61a that is in contact with the high-voltage side of the arrester element stack 61, and a cylinder that protrudes upward from the center of the upper surface of the disk portion 62a. 62b, and an annular groove 62c for fitting a tape-shaped conductor connector (multi-contact) (not shown) is provided on the outer periphery of the cylindrical portion 62b. A coiled high-pressure spring 63 having the same diameter as that of the cylindrical portion 62b is mounted so as to protrude from the upper half.

  The pressing member 65 includes an annular member 65a having a diameter slightly smaller than the outer diameter of the rear end portion side (low pressure side) of the rubber mold body 67. The arrester element 61a is substantially at the center of the upper surface of the annular member 65a. The disk-shaped pressing part 65b of the same shape is provided, and, for example, twelve recessed parts 65c are provided in the vicinity of the outer peripheral edge on the lower surface side so as to be equally distributed along the circumferential direction. In the figure, 65d is, for example, four screw holes provided so as to be equally distributed along the circumferential direction on the inner peripheral side of the annular member, and 65e is a large-diameter recessed portion provided in the lower central portion. Show.

  A state in which the lower surface of the disk portion of the connection conductor 62 is in contact with the upper end of the arrester element laminate 61 having such a configuration, and the rear end is in contact with the pressing member 65b through the pressing portion 65b. Then, a rubber mold body 67 such as silicone rubber is provided across the upper surface of the disk portion 62 a of the connection conductor 62 and the outer periphery of the pressing metal 65, and the arrester element laminate 61 is connected to the connection conductor 62 by the rubber mold body 67. And it is integrated with the press fitting 65.

  Next, a method for detachably mounting the arrester mold body 6 having the arrester element stack 61 in the bushing 2 will be described.

  First, the high-pressure spring 63 is disposed on the cylindrical portion 62b of the connecting conductor 62 so that the upper half protrudes from the cylindrical portion 62b, and the low-pressure spring 66 is disposed on the concave portion 65c of the pressing metal 65. The portion is disposed so as to protrude from the recessed portion 65c. Then, in a state where no spring force is applied to the high-pressure side spring 63 and the low-pressure side spring 66, as shown in FIG. 1, the distal end portion (high-pressure side) of the arrester mold body 6 is inserted into the bushing 2, The side spring 63 is pushed in until the tip of the side spring 63 comes into contact with the inner wall surface of the main circuit connector 43. Accordingly, a tongue piece (not shown) constituting a conductor connector (multi-contact) disposed in the cylindrical portion 62b is in electrical contact with the inner peripheral surface of the connection conductor insertion portion 42, and the rubber mold body 67 has a small diameter. The portion 67a is on the inner peripheral surface of the upper insertion hole 51a of the bushing 2, the conical portion 67b of the rubber mold body 67 is on the inner peripheral surface of the tapered insertion hole 53c, and the large-diameter portion 67c of the rubber mold body 67 is the lower insertion hole. It abuts on the inner peripheral surface of 52a.

  Next, a pressing member F made of a disk-shaped metal fitting is brought into contact with the lower surface of the lower cylindrical portion 52 of the bushing 2, and a plurality of bolts B disposed in the vicinity of the outer peripheral edge of the pressing member F along the circumferential direction. And fasten to the lower surface of the lower cylindrical portion 52. Thereby, the low-pressure side spring 66 is compressed between the inner part of the recessed portion 65 c and the upper surface of the pressing member F, and the low-pressure side spring 66 is biased with an axial spring force. The arrester mold body 6 is further pushed toward the distal end portion of the bushing 2 by the spring force of the low-pressure side spring 66, thereby causing a gap between the conical portion 67 b of the rubber mold body 67 and the inner peripheral surface of the tapered insertion hole 53 c. A predetermined surface pressure is applied, and the high-pressure side spring 63 is compressed between the closed portion of the cylindrical portion 62b (the upper surface of the connection conductor 62) and the inner wall surface of the main circuit connector 43, and the high-pressure side spring 63 is axially compressed. A spring force (reaction force toward the arrester mold body 6) is urged.

  Therefore, in the arrester having such a configuration, due to the synergistic effect of the spring force of the low-pressure side spring 66 and the spring force of the high-pressure side spring 63, the arrester element 61a and the connection conductor 62, between the arrester element 61a, and the arrester element 61a are pressed. A predetermined surface pressure can be applied between the portions 65b, and a predetermined surface pressure can be applied to the interface between the conical portion 67b of the rubber mold 67 and the inner peripheral surface of the tapered insertion hole 53c. The insulation performance at the interface between the two can be improved.

  In addition, by installing the arrester mold body 6 including the arrester element stack 61 in the bushing 2, the shield body 41 in which the upper end portion side (high voltage side) of the arrester element stack 61 is embedded in the upper cylindrical portion 51. As a result, the voltage sharing of the arrester element 61a can be made uniform as will be described later.

  FIG. 3 shows an equipotential distribution diagram of the arrester in this embodiment. From the figure, the upper end portion of the arrester element laminate 61 is shielded by the high-voltage shield body 4 so that the electric field does not concentrate on the upper end portion, and the rear end portion of the arrester element laminate 61 serves as a grounding body. By being arranged outside the device case 1, the electric field is not concentrated on the rear end portion, and the middle part of the arrester element laminate 61 is between the high-voltage shield body 4 and the device case 1 as a grounding body. It can be seen that the electric field is appropriately controlled by adjusting the interval, so that the electric field is not concentrated in the intermediate portion.

  Here, the influence which the shield case 41 and the apparatus case 1 as a grounding body have on the arrester element laminated body 61 will be described. First, when the interval between the lower end portion of the shield body 41 and the upper surface of the device case 1 is shortened, the electric field in the middle portion of the arrester element stack 61 becomes dense due to the influence of the shield body 41 and the device case 1. If the distance between the two is increased, the electric field in the intermediate portion becomes sparse. Accordingly, it is difficult to make the voltage sharing of the arrester element 61a uniform only by simply increasing the distance between the two. In this respect, in the present embodiment, the upper end portion of the arrester element stack 61 (about one third of the length of the arrester element stack 61) and the middle portion (about one third of the length of the arrester element stack 61). Is positioned in the device case 1 and the rear end portion of the arrester element stack 61 (about one third of the length of the arrester element stack 61) is positioned outside the device case 1 so that the high-voltage shield 4 The distance from the device case 1 as the grounding body is appropriately adjusted, the electric field in the middle part of the arrester element stack 61 can be appropriately controlled, and the voltage sharing of the arrester element 61a can be made uniform. .

  Next, in the arrester thus configured, when performing a withstand voltage test or the like of the device, the bolt B is first removed, and the pressing member F is removed from the lower cylindrical portion 52 of the bushing 2. Then, the arrester mold body 6 is pushed out to the rear end side of the bushing 2 by the spring force of the high-pressure side spring 63, whereby the arrester mold body 6 can be easily removed.

  As described above, according to the arrester of the present invention, a predetermined surface pressure can be applied between the arrester elements 61a by the synergistic effect of the spring force of the low-pressure side spring 66 and the spring force of the high-pressure side spring 63. Further, since the spring constant of the high-pressure side spring 63 is set lower than the whole spring constant of the low-pressure side spring 66, the gap between the conical portion 67b of the rubber mold 67 and the inner peripheral surface of the tapered insertion hole 53c is set. A predetermined surface pressure can be applied to the interface, and the insulation performance at the interface between the two can be improved.

Furthermore, since the outer periphery of the tip of the arrester element stack 61 is covered with the high-voltage shield body 4, the voltage sharing of the arrester element 61a can be made uniform, and thus also applicable to 66 / 77kV class ultrahigh-voltage lines. A possible arrester can be provided.
[Example 2]
FIG. 4 shows a partial sectional view of the arrester in the second embodiment of the present invention. In the figure, parts common to those in FIG. 1 are denoted by the same reference numerals and detailed description thereof is omitted.

  In this embodiment, a conductive coating layer 75 is provided on the outer peripheral surface of the tip of the bushing 7 as indicated by a dotted line.

  First, the bushing 7 in the second embodiment has an intermediate cylindrical portion 71 provided with an annular recessed portion 71a in the vicinity of the outer peripheral edge of the upper surface thereof, and is concentric with the intermediate cylindrical portion 71 at the upper end portion of the intermediate cylindrical portion 71. An upper cylindrical portion 72 having a tapered conical portion 72a that is smaller than the outer diameter of the intermediate cylindrical portion 71 and closed at the upper end, and an intermediate cylinder near the outer peripheral edge of the lower surface of the intermediate cylindrical portion 71. A lower cylindrical portion 73 concentrically connected to the portion 71 and having a smaller diameter than the outer diameter of the intermediate cylindrical portion 71, and a central portion of the closed portion 72b of the upper cylindrical portion 72 so as to protrude from the closed portion 72b. And a main circuit connector 74 embedded therein. In this embodiment, the bushing 7 has an outer diameter of the lower cylindrical portion 73 larger than that of the opening 1 a of the device case 1, and the lower surface of the outer peripheral edge of the lower cylindrical portion 73 is airtightly placed on the upper surface of the device case 1.・ It is fixed.

  Reference numeral 75 denotes a conductive coating layer (for example, a coating layer made of silver paint) as a high-voltage shield body. The conductive coating layer 75 is formed from the outer surface of the closing portion 72 b of the upper cylindrical portion 72. The outer peripheral surface of the conical portion 72 a and the outer peripheral surface of the semicircular portion 71 b constituting the recessed portion 71 a of the intermediate cylindrical portion 71 are provided.

Also in this embodiment, similarly to the arrester in the first embodiment, the upper end portion of the arrester element stack 61 is shielded by the conductive coating layer 75 as a high voltage shield body, so that an electric field is applied to the upper end portion. In addition, the rear end portion of the arrester element stack 61 is disposed outside the device case 1 as a grounding body, so that the electric field is not concentrated on the rear end portion. Since the electric field is controlled by adjusting the distance between the conductive coating layer 75 and the device case 1 as the grounding body in the intermediate part of the body 61, the electric field is not concentrated in the intermediate part. The voltage sharing can be made uniform. In the arrester in this embodiment, a conductive coating layer 75 is provided instead of the high-voltage shield body 4 made of the metal fitting in the first embodiment, so that it is lighter than the arrester in the first embodiment. And cost reduction can be achieved. Note that the arrester in this embodiment is suitable for gas-insulated or air-insulated type electrical equipment.
[Example 3]
FIG. 5 shows a partial cross-sectional view of the arrester in the third embodiment of the present invention. In the figure, parts common to those in FIG. 1 are denoted by the same reference numerals and detailed description thereof is omitted.

  In this embodiment, a separate high-voltage shield body 10 is placed and fixed at the tip of the bushing 8.

  First, the bushing 8 in the third embodiment includes a tapered intermediate cylindrical portion 81 and an upper portion having a diameter smaller than the outer diameter of the intermediate cylindrical portion 81 connected to the upper end portion of the intermediate cylindrical portion 81 concentrically with the intermediate cylindrical portion 81. A cylindrical portion 82, and a lower cylindrical portion 83 that is concentrically connected to the lower end portion of the intermediate cylindrical portion 81 and concentrically with the intermediate cylindrical portion 81. An annular mounting flange 83 a is continuously provided on the outer periphery of the upper position of 83.

  The high-voltage shield body 10 includes a cylindrical metal fitting 11 whose upper end is closed, and a main circuit connector 13 erected upward from the closing portion 12 at the center of the closing portion 12 of the metal fitting 11.

  In the high-voltage shield body 10 having such a configuration, as shown in the figure, the main circuit connector 13 is disposed above the upper cylindrical portion 82, and the side wall portion 14 of the metal fitting 11 is connected to the side wall portion 82 a of the upper cylindrical portion 82. It is placed and fixed concentrically with the upper cylindrical portion 82 at the tip of the upper cylindrical portion 82 so as to be positioned around.

Also in this embodiment, like the arrester in the first embodiment, the upper end portion of the arrester element laminated body 61 is shielded by the cylindrical metal fitting 11 constituting the high-voltage shield body 10, so that an electric field is applied to the upper end portion. Is not concentrated, and the rear end portion of the arrester element stack 61 is disposed outside the device case 1 as a grounding body, so that the electric field does not concentrate on the rear end portion. Since the electric field is controlled at the intermediate part of the laminated body 61 by adjusting the distance between the cylindrical metal fitting 11 and the device case 1 as the grounding body, the electric field is not concentrated on the intermediate part. The voltage sharing of 61a can be made uniform. Note that the arrester in this embodiment is suitable for oil-insulated, gas-insulated, or air-insulated type electrical equipment.
[Example 4]
FIG. 6 shows a partial sectional view of an arrester in the fourth embodiment of the present invention. In the figure, the same reference numerals are given to the same parts as those in FIGS. 1 and 5 and the detailed description is omitted.

  In this embodiment, the high-voltage shield body 10 shown in FIG. 5 is placed and fixed at the tip of the bushing 9, and the periphery of the high-voltage shield body 10 is covered with an insulating barrier 91b as follows. ing.

  First, the bushing 9 according to the fourth embodiment has an upper cylindrical portion 91 provided with an annular recessed portion 91a in the vicinity of the outer peripheral edge of the upper surface of the bushing 9 and a lower cylindrical portion of the upper cylindrical portion 91 concentric with the upper cylindrical portion 91. And a lower cylindrical part 92 having a diameter smaller than the outer diameter of the upper cylindrical part 91. The high-pressure shield body 10 having the same configuration as that shown in FIG. 5 is disposed concentrically with the upper cylindrical portion 91 so that the side wall portion 14 is located in the recessed portion 91a of the upper cylindrical portion 91. . In this embodiment, the bushing 9 has an outer diameter of the upper cylindrical portion 91 larger than that of the opening 1a of the device case 1, and the lower surface of the outer peripheral edge of the upper cylindrical portion 91 is airtightly placed on the upper surface of the device case 1.・ It is fixed.

  Also in this embodiment, like the arrester in the first embodiment, the upper end portion of the arrester element laminated body 61 is shielded by the cylindrical metal fitting 11 as the high-pressure shield body, so that the electric field is concentrated on the upper end portion. In addition, the rear end portion of the arrester element laminate 61 is disposed outside the device case 1 as a grounding body so that the electric field is not concentrated on the rear end portion. Since the electric field is controlled by adjusting the distance between the cylindrical metal fitting 11 and the equipment case 1 as the grounding body, the middle part of 61 is not concentrated on the middle part. The voltage sharing of 61 can be made uniform. Further, in the arrester in this embodiment, the insulating barrier member 91b is provided around the cylindrical metal fitting 11 by arranging the side wall portion 14 of the high-pressure shield body 10 in the recessed portion 91a of the upper cylindrical portion 91. Therefore, the insulation distance between the phases or the insulation distance from the device case 1 can be shortened, and the device can be reduced in size. Note that the arrester in this embodiment is suitable for oil-insulated, gas-insulated, or air-insulated type electrical equipment.

  The present invention can be changed and modified as follows within the scope of the claims.

  1stly, in the above-mentioned Example, although the case where a bushing was arrange | positioned in the bottom part of the apparatus case 1 was demonstrated, you may arrange | position a bushing in the side wall of the apparatus case 1. FIG.

  Secondly, in the above-described embodiment, the case where the arrester of the present invention is applied to a 66/77 kV high-voltage line is described. May be.

The partial sectional view of the arrester in the 1st example of the present invention. The partial sectional view of the arrester mold object in the 1st example of the present invention. The equipotential distribution map of the arrester in the first embodiment of the present invention. The partial sectional view of the arrester in the 2nd example of the present invention. The partial sectional view of the arrester in the 3rd example of the present invention. The partial sectional view of the arrester in the 4th example of the present invention. The partial cross section figure of the conventional arrester. The partial cross section figure of the conventional arrester.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Equipment case 1a ... Opening part 2 ... Bushing 4 ... High voltage shield body 6 ... Arresta mold body 61 ... Arrester element laminated body 63 ... 1st spring (high pressure side spring)
66 ... 2nd spring (low pressure side spring)
67 ... Rubber mold body 75 ... Conductive coating layer 91b ... Insulating barrier F ... Pressing part goods S1 ... Cylindrical metal fitting

Claims (6)

A bushing disposed in an opening of a device case accommodating an electric device so as to cover the opening in an airtight manner, and an arrester mold body detachably mounted from the outside of the device case in an insertion hole of the bushing; Prepared,
The arrester mold body includes an arrester element laminate formed by laminating a plurality of arrester elements, and a rubber mold body provided on the outer periphery of the arrester element laminate,
The arrester is characterized in that a first spring that is biased with a spring force by pressing in the axial direction is disposed at the tip of the arrester mold body.   2. The arrester according to claim 1, wherein a second spring to which a spring force is urged by pressing in the axial direction is disposed at a rear end portion of the arrester mold body.   3. The arrester according to claim 2, wherein a spring constant of the first spring is set lower than a whole spring constant of the second spring. The top of the bushing is provided with a main circuit connector that is connected to the main circuit conductor of the electrical device,
The connection conductor connected to the main circuit connector is provided integrally with the arrester mold body at the tip of the arrester mold body. The described arrester.   The arrester according to claim 4, wherein the connection conductor includes a cylindrical portion for disposing the first spring. The main circuit connector includes a connection conductor insertion portion,
The arrester according to claim 5, wherein the cylindrical portion of the connection conductor is plug-in connected to the connection conductor insertion portion.

Images