JP2010055869A - Surge arrester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent in advance that an insulator is damaged by the scattering of broken pieces caused by the explosive destruction of an arrestor and/or the generation of an external arc. <P>SOLUTION: In the arrestor 12 which is arranged opposite to the insulator 11 and in which a current-limiting element 23 having nonlinear electric current voltage characteristics is covered by an insulating outer cover 25, a shielding plate 28 opposing the insulator 11 is arranged between the current-limiting element 23 and the insulating outer cover 25. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a lightning arrester, and more particularly to a lightning arrester that protects peripheral devices of a transmission / distribution line from a lightning surge or the like when an abnormal voltage occurs due to a lightning surge or the like.

  Generally, when lightning strikes near the insulators installed on high-voltage or extra-high-voltage transmission / distribution lines, an abnormal voltage due to lightning surges, etc., protects the peripheral equipment of the transmission / distribution lines from lightning surges, etc. As shown in FIG. 6, the lightning arrester 1 is attached between the grounding side and the electric wire side of the insulator 5 (for example, refer patent document 1).

  The lightning arrester 1 has a built-in current limiting element made of ZnO or the like having a non-linear current-voltage characteristic that exhibits low resistance to surge voltage and high resistance to normal ground voltage of transmission and distribution lines. It comprises. The lightning arrester 1 electrically and mechanically connects the current limiting element described above between a metal upper terminal electrode 2 serving as an electric wire side terminal and a metal lower terminal electrode 3 serving as a ground side terminal. It has a structure in which an insulating outer covering 4 such as an elastic polymer or EPDM is attached to the outer peripheral surfaces of the electrodes 2 and 3 and the current limiting element.

  The lightning arrester 1 which consists of the above-mentioned structure is attached to the insulator 5 attached to the upper part of the utility pole via a brace. That is, the arm of the power pole is grounded, and the lower terminal electrode 3 of the lightning arrester 1 is electrically and mechanically connected to the ground-side mounting portion 6 of the insulator 5 electrically connected to the arm by screwing or the like. To do. Thus, the lower discharge electrode 9 is electrically and mechanically connected to the upper terminal electrode 2 of the lightning arrester 1 held upright, and the upper discharge is applied to the electric wire side mounting portion 7 of the insulator 5 to which the power transmission and distribution line is attached. The electrodes 8 are electrically and mechanically connected, and the tip portions of the lower discharge electrode 9 and the upper discharge electrode 8 are arranged to face each other so that a discharge gap 10 having a predetermined gap length is formed.

In this lightning arrester 1, when an abnormal voltage due to a lightning surge occurs, a lightning current due to the lightning surge flows to the ground through a current limiting element due to a discharge in the discharge gap 10 between the upper discharge electrode 8 and the lower discharge electrode 9. At this time, the current limiting element has a low resistance value against the abnormal voltage caused by lightning surge, and this is instantaneously released to the ground, and if the abnormal voltage disappears, the current limiting element becomes a high resistance value and becomes normal grounding. Cut off the voltage. This valve action protects the peripheral equipment of the transmission and distribution lines from lightning surges.
JP-A-10-247430

  By the way, when an abnormal voltage such as a direct lightning exceeding the performance of the lightning arrester 1 occurs, the current limiting element may break down. In that case, an internal arc is generated between the upper terminal electrode 2 and the lower terminal electrode 3, A large amount of gas is generated by the arc heat, and the internal pressure rapidly increases. When the internal pressure rises rapidly, the insulating envelope 4 is easily broken and the arc is emitted to the outside. By generating this external arc, the internal arc is extinguished. This prevents the lightning arrester 1 from being explosively destroyed due to a sudden increase in internal pressure and the fragments from being scattered around.

  However, since the discharge position of the external arc generated due to the fault of the current limiting element is not fixed, the external arc that is released when the insulation jacket 4 of the lightning arrester 1 is broken hits the insulator 5 that is disposed opposite to the lightning arrester 1. Sometimes. If this external arc continues to hit the surface of the insulator 5, the insulator 5 will be damaged, and the insulator 5 will be damaged.

  Therefore, the present invention has been proposed in view of the above-mentioned problems, and the object of the present invention is to dissipate debris due to explosive destruction accompanied by a rapid increase in internal pressure and to tear and release the insulating envelope. Another object of the present invention is to provide a lightning arrester that can prevent the insulator from being damaged by the occurrence of an external arc.

  As a technical means for achieving the above-mentioned object, the present invention is a lightning arrester in which a current limiting element having a non-linear current-voltage characteristic, which is disposed opposite to a power distribution device, is covered with an insulating envelope. A shielding plate facing the power distribution device is disposed between the flow element and the insulating jacket. In addition, as the above-mentioned power distribution apparatus, there is an insulator attached to the upper part of the utility pole via a brace. Moreover, as the above-mentioned shielding plate, those made of FRP are preferable in terms of strength.

  When an abnormal voltage such as a direct lightning strike that exceeds the performance of the lightning arrester occurs, the current limiting element of the lightning arrester breaks down and an internal arc is generated between the terminal electrodes. The insulation envelope is broken by the sudden increase in internal pressure, and an external arc is emitted. Even in such a case, in the lightning arrester of the present invention, an explosion caused by a rapid increase in internal pressure is caused by arranging a shielding plate facing the power distribution device between the current limiting element and the insulation jacket. The shielding plate can prevent debris from external destruction and external arc emitted from the lightning arrester from hitting the power distribution equipment.

  The lightning arrester in the present invention preferably has a structure in which a current limiting element is sandwiched between a pair of terminal electrodes and these are arranged coaxially, and a shield plate is attached to the pair of terminal electrodes. If the shield plate is attached to the pair of terminal electrodes in this way, a strong attachment structure of the shield plate can be realized, so that sufficient strength against a sudden increase in internal pressure due to the failure of the current limiting element is ensured. Can do.

  According to the present invention, the shielding plate facing the power distribution device is disposed between the current limiting element and the insulation jacket, so that it is emitted from debris or a lightning arrester due to explosive destruction due to a rapid increase in internal pressure. The shield plate can prevent the external arc to hit the power distribution equipment. As a result, it is possible to prevent damage to the power distribution equipment due to scattering of fragments and external arcs, so that safety and reliability can be improved, and a long-life lightning protection device can be provided.

  Embodiments of the lightning arrester according to the present invention will be described in detail below. FIG. 1 exemplifies a structure in which a lightning arrester is attached between the electric wire side and the ground side of an LP insulator or a retention insulator that is a power distribution device. In addition, this invention is applicable also to other power distribution apparatuses other than LP insulator and a retention insulator.

  The embodiment shown in FIG. 1 includes an insulator 11 attached to an upper portion of a utility pole through a brace 30 in a standing state, and a lightning arrester 12 attached to the insulator 11. An upper terminal electrode 16 serving as a wire-side terminal of the lightning arrester 12 is electrically and mechanically connected to the wire-side attachment portion 14 of the insulator 11 to which the transmission / distribution wire 13 is attached via an arm 15.

  On the other hand, one discharge electrode 18 is electrically and mechanically connected to the lower terminal electrode 17 serving as the ground side terminal of the lightning arrester 12, and the other discharge electrode 20 is electrically connected to the ground mounting portion 19 of the insulator 11. And mechanically connected. The distal ends of one discharge electrode 18 and the other discharge electrode 20 are arranged to face each other so that a discharge gap 21 having a predetermined gap length is formed. The electric wire side mounting portion 14 of the insulator 11 is covered with an insulating cover 22.

  As shown in FIGS. 1 to 5, the lightning arrester 12 is a ZnO having a non-linear current-voltage characteristic that exhibits a low resistance to a surge voltage and a high resistance to a normal ground voltage of a transmission and distribution line. And a current limiting element 23 made of the like.

  The lightning arrester 12 electrically and mechanically connects the current limiting element 23 described above between a metal upper terminal electrode 16 serving as a wire side terminal and a metal lower terminal electrode 17 serving as a ground side terminal. A plurality of current limiting elements 23 are sandwiched between the upper terminal electrode 16 and the lower terminal electrode 17 so as to be coaxially arranged, and a plurality of FRP insulating rods 24 are arranged around the insulating rods 24. The upper terminal electrode 16 and the lower terminal electrode 17 are fixed to both ends of the.

  On the outer peripheral surfaces of the upper terminal electrode 16, the lower terminal electrode 17 and the current limiting element 23, an insulating covering 25 made of a polymer material such as silicone, EVA or EP rubber having excellent weather resistance, insulation and tracking resistance. Adhere. The insulating covering body 25 is formed by a method of directly forming on the side surface of the current limiting element 23 or a method of attaching a tube-shaped member by heat shrinkage or insertion.

  In addition, in order to make the joining state of several current limiting elements 23 favorable, between the upper terminal electrode 16 and the current limiting element 23, and between the lower terminal electrode 17 and the current limiting element 23, it is spring property. A member (not shown) is interposed. Further, in order to secure a contact area between the upper terminal electrode 16 and the current limiting element 23 and a contact area between the lower terminal electrode 17 and the current limiting element 23, and between the upper terminal electrode 16 and the current limiting element 23, Spacers 26 and 27 are interposed between the terminal electrode 17 and the current limiting element 23, respectively.

  The spacer 26 interposed between the upper terminal electrode 16 and the current limiting element 23 serves as a starting point of an arc due to a short-circuit current generated when the current limiting element 23 fails, so that the upper terminal electrode 16 is prevented from being melted. Therefore, it is made of heavy metal such as iron, stainless steel, copper, brass, etc., and has a certain thickness (for example, 6 mm or more).

  The FRP insulating rod 24 is fixed to the upper terminal electrode 16 and the lower terminal electrode 17 by using appropriate means such as caulking, bonding or screwing. The upper terminal electrode 16 and the lower terminal electrode 17 positioned at both ends are fixed by hooking loop-shaped FRP members to the upper terminal electrode 16 and the lower terminal electrode 17 at both ends, in addition to using the FRP insulating rod 24. And a method of winding an uncured or semi-cured FRP sheet around the side surfaces of the upper terminal electrode 16, the lower terminal electrode 17 and the current limiting element 23 and curing them.

  In the lightning arrester 12, when an abnormal voltage due to a lightning surge occurs, a lightning current due to the lightning surge flows to the ground via the current limiting element 23 due to discharge in the discharge gap 21 between the discharge electrodes 18 and 20. At this time, the current limiting element 23 has a low resistance value against the abnormal voltage caused by the lightning surge, and this is instantaneously released to the ground. If the abnormal voltage disappears, the current limiting element 23 has a high resistance value and is normal. Shut off the ground voltage. This valve action protects peripheral devices of the transmission and distribution line 13 from lightning surges and the like.

  When an abnormal voltage such as a direct lightning strike that exceeds the performance of the lightning arrester 12 occurs, the current limiting element 23 of the lightning arrester 12 breaks down and an internal arc is generated between the upper terminal electrode 16 and the lower terminal electrode 17, and the arc heat causes As a result, a large amount of gas is generated and the internal pressure rises rapidly. When the internal pressure rises rapidly, the insulating jacket 25 is easily broken and the arc is released to the outside, and the internal arc is extinguished by generating this external arc. This prevents the lightning arrester 12 from being explosively destroyed due to a sudden increase in internal pressure and the fragments from scattering to the surroundings.

  In the lightning arrester 12 having the above-described configuration, the FRP shielding plate 28 facing the insulator 11 is disposed between the current limiting element 23 and the insulating envelope 25. By configuring the shielding plate 28 from FRP having excellent heat resistance and insulation, sufficient strength against a sudden increase in internal pressure due to a failure of the current limiting element 23 is ensured. For example, as the shielding plate 28, it is preferable to use an FRP plate having a thickness of about 1 to 6 mm, which is a single layer or a laminate in which insulating fibers are impregnated and cured with a resin. The shielding plate 28 may be other than the above-described FRP as long as the material has heat resistance, insulation, and strength.

  The shielding plate 28 has a structure in which a plurality of current limiting elements 23 are attached to the upper terminal electrode 16 and the lower terminal electrode 17 in which the current limiting elements 23 are coaxially arranged by screws 29. Since the shield plate 28 is attached to the upper terminal electrode 16 and the lower terminal electrode 17 in this way, a strong attachment structure of the shield plate 28 can be realized, so that the internal pressure is rapidly increased due to the failure of the current limiting element 23. Sufficient strength against rising can be ensured. The shielding plate 28 can be fixed to the upper terminal electrode 16 and the lower terminal electrode 17 by using appropriate means such as caulking or bonding in addition to screws.

  When an abnormal voltage such as a direct lightning strike that exceeds the performance of the lightning arrester 12 occurs, the current limiting element 23 of the lightning arrester 12 breaks down and an internal arc is generated between the upper terminal electrode 16 and the lower terminal electrode 17, and the arc heat causes As a result, a large amount of gas is generated and the internal pressure rises rapidly. Even if the internal pressure of the lightning arrester 12 is shattered due to explosive destruction due to the rapid increase in internal pressure, or the outer sheath 25 of the lightning arrester 12 is broken and an external arc is emitted, the current arrester 12 Since the shielding plate 28 that opposes the insulator 11 is disposed between the insulator 23 and the insulating envelope 25, the shielding plate 28 indicates that fragments or external arcs emitted from the lightning arrester 12 directly hit the insulator 11. Can be prevented. As a result, it is possible to prevent damages such as chipping of the insulator 11 and cutting of the trunk due to scattering of fragments and external arc.

  The present invention is not limited to the above-described embodiments, and can of course be implemented in various forms without departing from the gist of the present invention. It includes the equivalent meanings recited in the claims, and the equivalent meanings recited in the claims, and all modifications within the scope.

It is a front view which shows embodiment of the lightning arrester which concerns on this invention. It is a longitudinal cross-sectional view which shows the lightning arrester of FIG. It is the longitudinal cross-sectional view seen from the left side of FIG. 2 with the lightning arrester of FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2 in the lightning arrester of FIG. 1. FIG. 3 is a cross-sectional view taken along line BB in FIG. 2 in the lightning arrester of FIG. 1. It is a front view which shows the prior art example of a lightning arrester.

Explanation of symbols

11 Power distribution equipment (Isogo)
12 Lightning arrester 16 Terminal electrode (upper terminal electrode)
17 Terminal electrode (lower terminal electrode)
23 Current-limiting element 25 Insulation envelope 28 Shield plate

Claims (4)

  A lightning arrester that is disposed opposite to a power distribution device and that has a current limiting element having a non-linear current-voltage characteristic and is covered with an insulating envelope, and between the current limiting device and the insulating envelope, A lightning arrester characterized by arranging opposing shielding plates.   The lightning arrester according to claim 1, comprising a structure in which the current limiting element is sandwiched between a pair of terminal electrodes and arranged coaxially, and a shielding plate is attached to the pair of terminal electrodes.   The lightning arrester according to claim 1 or 2, wherein the shielding plate is made of FRP.   The lightning arrester according to any one of claims 1 to 3, wherein the power distribution device is an insulator attached to an upper portion of a power pole via a brace.

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