JPH1012409A - Lightning arrester - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting arrester having an excellent responsiveness to pressure rise, by dispersing pressure rise generated by inner arc, with a simple structure. SOLUTION: In a lightning arrester, current-limiting elements 11 having non-linear voltage-current characteristics are coaxially arranged, in the state that the current-limiting elements 11 are sandwiched between a pair of terminal electrodes 12, 13, and inserted in an insulating tube 14. The terminal electrodes 12, 13 are fixed with pins 15 at both the ends of the insulating tube 14, and an insulating outer covering member 19 is stuck on the outer peripheral surface of the insulating tube 14 and the terminal electrodes 12, 13. A penetrating hole 18 which makes bursting easy is formed on the side wall surface of the insulating tube 14, and an inner space existing between the insulating tube 14 and the current-limiting elements 11 and the penetrating hole 18 which is interconnected to the inner space are filled with an organic, insulator 20 in the state of gel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lightning arrester, and more particularly to a lightning arrester for protecting peripheral equipment of a transmission and distribution line from a lightning surge when an abnormal voltage occurs due to a lightning surge or the like.

[0002]

2. Description of the Related Art Generally, when a lightning strike occurs near a high-voltage or extra-high power transmission / distribution line or when an abnormal voltage is generated due to a lightning surge or the like, a power transmission / distribution line peripheral device is protected from lightning surge or the like. A lightning arrester is installed between the ground side of the distribution line and the electric wire side.

As shown in FIG. 3, this lightning arrester has a non-linear current-voltage characteristic having a low resistance to a surge voltage and a high resistance to a normal ground voltage of a transmission and distribution line.
A structure including a current limiting element 1 made of nO or the like is provided. Specifically, a pair of metal block-shaped terminal electrodes 3 and 4 on the ground side and the electric wire side are fitted to both ends of the FRP insulating cylinder 2 in the axial direction (vertical direction) and fixed by pins 5. The current limiting element 1 described above is housed and arranged between the two terminal electrodes 3 and 4 in the insulating tube 2. Further, an insulating jacket 6 made of an insulating material is attached to the outer peripheral surfaces of the insulating cylinder 2 and the terminal electrodes 3 and 4 described above.

[0004] A compression spring 7 is inserted between the current limiting element 1 and the terminal electrode 3 on the electric wire side, and a pressing force acts on the current limiting element 1 by the elastic force of the compression spring 7. The current limiting element 1 and the two terminal electrodes 3 and 4 are joined in close contact with a predetermined pressing force to obtain a good joint state, and the electrical connection between the current limiting element 1 and the two terminal electrodes 3 and 4 is obtained. The connection is secure.

In this lightning arrester, when an abnormal voltage is generated due to a lightning surge or the like, the current limiting element 1 has a low resistance value and instantaneously escapes to the ground. If the abnormal voltage disappears, the current limiting element 1 is activated. High resistance value cuts off normal ground voltage. By this valve action, the peripheral equipment of the transmission and distribution line is protected from lightning surge and the like.

[0006]

However, when a surge voltage exceeding the rating, such as a direct lightning strike, occurs, the current limiting element 1 may be broken down. An internal arc is generated in the interposed internal space, and a large amount of gas is generated by the heat of the arc, so that the internal pressure is rapidly increased. Due to the rapid increase in the internal pressure, the current limiting element 1, the insulating tube 2, and the like are explosively destroyed together with the insulating jacket 6, and the fragments are scattered around. If such explosive destruction of the lightning arrester occurs and its fragments are scattered, it is very dangerous to cause personal injury,
It becomes a serious problem.

Therefore, in order to prevent explosive destruction of the lightning arrester, a lightning arrester having a structure in which gas generated inside is released to the outside when the internal pressure rises to some extent is disclosed in Japanese Utility Model Laid-Open Publication No. 1-140719. No., JP-A-5
Japanese Unexamined Patent Publication No. -29061 and Japanese Patent Publication No. Hei 2-3241 are examples.

The lightning arresters disclosed in the former Japanese Utility Model Application Laid-Open No. 1-140719 and Japanese Patent Application Laid-Open No. 5-29061 are destroyed by disposing a thin film member such as a metal foil at an end on the ground side or the electric wire side. Has a structure in which an easy part is formed. In this lightning arrester, when the internal pressure rises to some extent, the thin-film member is destroyed and gas is released from that part to generate an external arc, thereby extinguishing the internal arc and causing an explosion due to a sudden increase in internal pressure. To prevent any destruction.

In the lightning arrester disclosed in Japanese Patent Publication No. 2-3241, a pressure-release hole is provided in a side wall of an insulating cylinder accommodating a current-limiting element and a terminal electrode, and communicates with the pressure-release hole. It has a structure in which a solid organic insulating material is filled in the inner space of the insulating cylinder. In this lightning arrester, when the internal pressure rises to some extent, the internal arc is extinguished by releasing gas from the pressure release hole of the insulating cylinder to generate an external arc,
It is designed to prevent explosive destruction due to a sudden increase in internal pressure.

[0010] However, the former lightning arrester [Jpn.
-140719 and JP-A-5-29061]
Therefore, it is necessary to have a mounting structure of a thin film member to release the gas generated inside in the vertical direction and a gas ejection structure to release the gas and generate an external arc, etc. In addition, the wall must be thickened so that the side wall including the insulating jacket is not damaged until the gas is released to the outside. Therefore, there is a problem that the entire lightning arrester becomes large.

In addition, the latter lightning arrester [JP-B 2-324]
No. 1] has a simpler structure for discharging gas generated inside as compared with the lightning arrester described above, but the organic insulating material filled in the internal space communicating with the pressure release hole of the insulating cylinder is a solid material. Therefore, it takes time for the organic insulating material to be softened or melted by the arc heat generated by the internal arc, making it difficult to release the gas instantaneously to the outside, and smooth pressure release. If not done,
Poor response to pressure rise and risk of explosive destruction. In addition, when the organic insulating material is solid, the pressure rise at the place where the internal arc is generated is large, and the current limiting element and the like are destroyed due to unevenness due to local concentration of the internal pressure. There is a problem that the risk of scattering is very large.

In view of the above, the present invention has been proposed in view of the above-mentioned problems, and an object of the present invention is to disperse a pressure rise generated by an internal arc with a simple structure, and to respond to the pressure rise. It is to provide a good lightning arrester.

[0013]

As a technical means for achieving the above object, the present invention provides a current limiting element having a non-linear voltage / current characteristic, which is sandwiched between a pair of terminal electrodes and is connected to the current limiting element. In a lightning arrester in which the terminal electrodes are fixed to both ends of the insulating cylinder, and the outer peripheral surface of the insulating cylinder is covered with an insulating jacket, In addition, a through hole communicating with the internal space of the insulating cylinder to facilitate pressure release is formed, and the internal space of the insulating cylinder is filled with a gel-like organic insulating material.

Further, according to the present invention, a current limiting element having a non-linear voltage-current characteristic is sandwiched between a pair of terminal electrodes, and they are arranged coaxially and inserted into an insulating cylinder. In the lightning arrester having the terminal electrodes fixed to both ends and an insulating jacket attached to the outer peripheral surface of the insulating cylinder, a thin wall contacting the inner space of the insulating cylinder on the side wall surface of the insulating cylinder to facilitate pressure release. A lightning arrester characterized by forming a portion and filling an internal space of the insulating cylinder with a gel-like organic insulating material.

In the present invention, it is preferable that the through hole or the thin portion is formed at a position on the inner end of the terminal electrode fixed to both ends of the insulating cylinder or at a position near the inner end. Further, it is preferable that a bottomed cylindrical terminal fitting electrically connected to the terminal electrode is fitted to an end of the insulating jacket, and a thick portion is formed at least on an opening periphery of the terminal fitting. .

[0016]

1 and 2 show an embodiment of the present invention.
And will be described.

As shown in FIG. 1, the lightning arrester in the embodiment of FIG. 1 has a non-linear current voltage having a low resistance to a surge voltage and a high resistance to a normal ground voltage of a transmission and distribution line. Plural current limiting elements 1 made of ZnO or the like having characteristics
1 and a pair of metal block-shaped terminal electrodes 12 and 13 on both ends of the current limiting element 11 on the ground side and on the electric wire side, respectively, are laminated coaxially. These plurality of current limiting elements 11 and a pair of terminal electrodes 12 located at both ends thereof,
13 are inserted into an insulating tube 14 made of FRP, and both terminal electrodes 12 and 13 are fixed to both ends of the insulating tube 14 by pins 15.
Is sandwiched. The above-described pins 15 may be provided at, for example, three locations at 120 ° circumferential intervals with respect to the axial center of the insulating cylinder 14.

In the above description, a plurality of current limiting elements 11 are arranged in the axial direction, but a cooling metal block is interposed between the joining surfaces of the plurality of current limiting elements 11. It is also possible to adopt a structure in which it is performed. Further, a structure in which one current limiting element 11 is simply housed in the insulating cylinder 14 is also possible.

Here, the one terminal electrode 12 (on the electric wire side) located at the upper side in the figure is arranged so as to be directly joined to the current limiting element 11, but the other terminal electrode 13 located at the lower side in the figure. On the [ground side], a compression spring 16 is interposed between the current limiting element 11 and the current limiting element 11. A predetermined pressing force is applied by the elastic force of the compression spring 16 to secure the bonding state between the terminal electrodes 12 and 13 and the current limiting element 11 and between the current limiting elements 11. 11 to improve the electrical characteristics.

Further, a compression spring 16 is interposed between the current limiting element 11 and the terminal electrode 13, and the connection conductor 1 having a curved shape is provided.
7, the current limiting element 11 and the terminal electrode 13
Is more securely connected than the compression spring 16 alone. The compression spring 16 and the connection conductor 17 are not always necessary, and the current limiting element 11 and the terminal electrode 1 are not required.
3 may be directly joined.

In the lightning arrester of this embodiment, a through hole 18 (pressure release hole) communicating with the internal space of the insulating cylinder 14 is formed on the side wall surface of the insulating cylinder 14 described above. In the circumferential direction of the insulating cylinder 14, the through hole 18 is, for example, 120 ° shifted from the above-described pin position by 60 ° with respect to the axial center of the insulating cylinder 14.
It is provided at three locations at equal circumferential intervals. Insulating tube 1
4 may be formed at an appropriate location in accordance with the axial dimension of the insulating cylinder 14. For example, when the axial dimension of the insulating cylinder 14 is long as shown in the drawing, the current limiting element 11 In the case where the axial dimension of the insulating tube 14 is short, the insulating tube 14 is formed at two positions corresponding to the current limiting element 11. In addition, the terminal electrodes 1 correspond to both end positions corresponding to the current limiting element 11.
It is desirable to set the position to the inner end of the second or 13 or a position near the inner end.

A cylindrical insulating jacket 19 made of an elastic polymer, EPDM, or the like is attached to the outer periphery of the insulating cylinder 14 having the through hole 18. This insulating jacket 19 is
It is fitted on the outer circumference of the insulating cylinder 14 while expanding itself, and then closely adhered by heat shrinkage. Alternatively, the above-described insulating cylinder 14 is set in a mold, and an insulating material is injected into the mold and molded to form an insulating jacket 19.
Can be produced. Then, an adhesive gel-like organic insulating material 20 is filled into the space between the insulating tube 14 and the current limiting element 11 and the internal space formed by the through hole 18. As the gel-like organic insulating material 20, for example, a silicon-based resin is suitable.

Further, cylindrical terminal fittings 21 and 22 with bottoms are attached to both ends of the insulating jacket 19. This terminal fitting 21,
22 is screwed to the terminal electrodes 12 and 13 at the center of the bottom thereof and is electrically connected thereto, and is fitted so that the cylindrical portion surrounds the outer periphery of the end of the insulating jacket 19. A thick portion 23 is formed on the periphery of the opening of the cylindrical portion of the terminal fittings 21, 22, and the insulating jacket 1 is formed.
The filling material 24 is embedded in the gap between the first and second filling materials 9.

In this lightning arrester, similarly to the conventional case, when an abnormal voltage is generated due to a lightning surge or the like, the current limiting element 11 has a low resistance value and instantaneously escapes to the ground, and if the abnormal voltage disappears, The current limiting element 11 has a high resistance value and cuts off the normal ground voltage. This valve action protects the peripheral equipment of the transmission and distribution line from lightning surges and the like.

On the other hand, if a surge voltage exceeding the rating such as a direct lightning strike occurs and the current limiting element 11 fails,
An internal arc is generated in an internal space sandwiched between the two terminal electrodes 12 and 13, and a large amount of gas is generated by the arc heat, so that the internal pressure tends to increase rapidly.

At this time, a through hole 18 is formed in the side wall surface of the insulating cylinder 14.
Is provided, when the internal pressure rises to some extent, the portion corresponding to the through-hole 18 of the insulating jacket 19 is broken, and the gas generated inside is released to the outside through the through-hole 18 so that the outside is released. By generating an arc, the internal arc is extinguished and explosive destruction due to a sudden increase in internal pressure is prevented. At this time, if the through-hole 18 of the insulating tube 14 is formed at a position corresponding to the inner ends of the terminal electrodes 12 and 13 or in the vicinity of the inner ends as described above, the lightning arrester is provided for safety. Even if the end of the terminal electrode 12 is covered with a cover, the inner end of the terminal electrode 12 and the terminal fitting 22 or the terminal electrode 1 through the through hole 18 of the insulating tube 14.
An external arc can be reliably generated between the inner end of the lightning arrester 3 and the explosive destruction of the lightning arrester.

In addition, both terminal electrodes 1 in the insulating cylinder 14
The organic insulating material 20 filled in the internal space sandwiched by the two and 13 is easy to move because it is a sticky gel, and the gas generated inside is instantaneously released from the through hole 18 to the outside. And a smooth pressure release is achieved. Further, the pressure rise at the location where the internal arc occurs is uniformly dispersed, and the pressure rise is not locally concentrated. Since the organic insulating material 20 is in the form of a sticky gel, the difference in thermal expansion between the organic insulating material 20 and the internal element such as the current limiting element 11 due to temperature fluctuation can be absorbed, and the separation from the internal element can be prevented. Can be prevented.

As described above, a part of the insulating jacket 19 is broken, and the external arc is applied to the terminal fitting 2 on the ground side or the electric wire side.
When it occurs between the terminal fittings 21 and 22, the arc heat starts to melt from the opening periphery of the cylindrical portions of the terminal fittings 21 and 22, but the thick part 23 is formed on the opening periphery of the terminal fittings 21 and 22. Therefore, the peripheral edges of the terminal fittings 21 and 22 do not completely melt and disappear, and the sealed state inside the insulating jacket 19 is not damaged, and the terminal fittings 21 and 22 do not fall off. Absent. In the illustrated terminal fittings 21 and 22, the thick portion 23 is formed only on the peripheral edge of the opening.
The portion excluding the bottom of the terminal fittings 21 and 22, that is, the entire cylindrical portion may be thick.

As described above, in the lightning arrester of FIG. 1, the through hole 18 is formed in the side wall surface of the insulating cylinder 14. However, the present invention is not limited to this. For example, as shown in FIG. It is also possible to form a thin portion 25 on the side wall surface of the insulating tube 14 in contact with the internal space of the insulating cylinder 14. This thin portion 25
It is manufactured by forming a concave hole in the inner peripheral surface of the insulating cylinder 14 and making the insulating cylinder 14 thin at that location. Other structures are the same as those of the above-described embodiment, and therefore, are denoted by the same reference numerals, and redundant description will be omitted. The formation of the thin portion 25 can completely prevent moisture from entering the inside of the insulating tube 14, so that the electrical characteristics of the current limiting element 11 can be maintained well.

In the lightning arrester of this embodiment, an internal arc is generated in the internal space of the insulating cylinder 14 due to the generation of a surge voltage exceeding the rating such as a direct lightning strike, and a large amount of gas is generated by the heat of the arc. Even if the pressure rises sharply, when the internal pressure rises to some extent, the thin portion 25 formed on the side wall surface of the insulating cylinder 14 is easily torn, and a portion corresponding to the thin portion 25 of the insulating jacket 19. Breaks. Thereby, the internal arc is extinguished by releasing the gas generated inside to the outside and generating an external arc,
Prevents explosive destruction due to sudden increase in internal pressure.

Further, as in the case of the above-described embodiment,
Since the organic insulating material 20 filling the internal space sandwiched between the two terminal electrodes 12 and 13 in the insulating cylinder 14 is in a gel state, the gas generated by the generation of the internal arc can be instantaneously released to the outside. And smooth pressure release. Further, the pressure rise at the location where the internal arc occurs is uniformly dispersed, and the pressure rise is not locally concentrated.

The present invention is not limited to the illustrated lightning arrester, but includes a current limiting arc horn in which an air gap is combined with a current limiting element having a current limiting element, or a current limiting element. It is also applicable to lightning arresters such as insulators.

[0033]

According to the present invention, a through hole or a thin portion for facilitating pressure release is formed on the side wall surface of the insulating cylinder, and the internal space of the insulating cylinder is filled with a gel-like organic insulating material. Therefore, even if the current limiting element fails due to the occurrence of surge voltage exceeding the rating such as direct lightning, etc., the internal pressure that rises due to gas generation in the internal space will not concentrate locally, and the internal pressure will be reduced to gel-like. It can be dispersed with organic insulating material and can realize smooth pressure release from through-holes or thin-walled parts. It is possible to provide a lightning arrester that is rich in responsiveness and good in response. In addition, when a thin portion is formed on the side wall surface of the insulating cylinder, it is possible to completely prevent moisture from entering the inside of the insulating cylinder, so that the electrical characteristics of the current limiting element can be maintained satisfactorily.

Further, when the through hole or the thin portion is formed at or near the inner end of the terminal electrode, an external arc can be reliably generated and the lightning arrester can explode. It is possible to more reliably prevent the temporary destruction.

Further, when a thick portion is formed at least on the peripheral edge of the opening of the terminal fitting fitted to the end of the insulating jacket, the peripheral edge of the terminal fitting is completely melted and lost due to the occurrence of an external arc. There is no possibility that the sealed state of the inside of the insulating jacket is damaged or the terminal fittings do not fall off.

[Brief description of the drawings]

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

FIG. 2 is a sectional view showing another example of the embodiment of the present invention.

FIG. 3 is a sectional view showing an example of a conventional lightning arrester.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Current limiting element 12 Terminal electrode 13 Terminal electrode 14 Insulation cylinder 18 Through hole 19 Insulation jacket 20 Organic insulating material 21 Terminal fitting 22 Terminal fitting 23 Thick part 25 Thin part

Continued on the front page (72) Inventor Koichi Murota 2-1-282 Watanabe-dori, Chuo-ku, Fukuoka City Inside Kyushu Electric Power Company (72) Inventor Koji Fukui 3-7-18 Meishincho, Amagasaki City, Hyogo Prefecture Otowa Amagasaki Plant of Denki Kogyo Co., Ltd.

Claims (4)

[Claims] 1. A current-limiting element having a non-linear voltage-current characteristic is sandwiched between a pair of terminal electrodes, they are arranged coaxially and inserted into an insulating cylinder. In a lightning arrester having an electrode fixed and an insulating jacket attached to an outer peripheral surface of an insulating cylinder, a through hole is formed on a side wall surface of the insulating cylinder to communicate with an internal space of the insulating cylinder to facilitate pressure release. A lightning arrester characterized in that the interior space of the insulating cylinder is filled with a gel-like organic insulating material. 2. A current limiting element having a non-linear voltage-current characteristic is sandwiched between a pair of terminal electrodes, they are arranged coaxially and inserted into an insulating cylinder, and said terminals are provided at both ends of the insulating cylinder. In a lightning arrester having an electrode fixed and an insulating jacket attached to an outer peripheral surface of an insulating cylinder, a thin wall portion is formed on a side wall surface of the insulating cylinder so as to be in contact with an inner space of the insulating cylinder to facilitate pressure release. A lightning arrester characterized in that a gel-like organic insulating material is filled in an inner space of the insulating cylinder. 3. The terminal according to claim 1, wherein the through hole or the thin portion is formed at a position corresponding to an inner end of the terminal electrode fixed to both ends of the insulating cylinder or at a position near the inner end. Or the lightning arrester according to 2. 4. A bottomed cylindrical terminal fitting electrically connected to the terminal electrode is fitted to an end of the insulating jacket, and a thick portion is formed at least on an opening periphery of the terminal fitting. The lightning arrester according to claim 1, 2, or 3.