The present invention relates to a contact that electrically connects two conductors in a gas insulated switchgear for use in a high-voltage transmission system while allowing relative displacement between the two conductors by thermal expansion.
There has been conventionally known a spring apparatus that gives electrical conductivity includes a coil spring and end coils. The coil spring has two ends and a plurality of intermediate coils canted along a centerline of the coil spring. Each of the intermediate coils has a leading portion disposed at a front angle to a normal line to the centerline and a trailing portion disposed at a back angle to the normal line. The end coils are congruent with the plurality of intermediate coils, are disposed at the two ends, have back angle means, and define a trailing portion of at least one of the end coils for locking the end coils on one end of the intermediate coils to the end coils on another end of the intermediate coils. The end coil trailing portion of the at least one of the end coils has a back angle different from the intermediate coil trailing portion back angle. The end coils are disposed at positions not interfering with deflection of the intermediate coils. Such a spring apparatus has been disclosed, for example, in Patent Document 1.
Moreover, there has been known a spring holding connector (contact) that includes a housing having a bore therethrough, a shaft rotatably and slidably arranged in the bore, an annular groove formed in one of the bore and shaft, and a circular coil spring disposed in the annular groove for slidably holding the shaft within the bore. The ends of the wire of the coil spring are welded to form a circular form. The groove is sized and shaped for controlling, in combination with a coil spring configuration, shaft mobility within the bore. Such a spring holding connector has been disclosed, for example, in Patent Document 2.
[Patent Document 1] Japanese Patent Application Laid-open No. H8-210404
In the conventional art disclosed in Patent Document 1, to form the circular coil spring by coupling both ends of the coil spring, it is necessary to form the end coils having a shape different from that of the intermediate coils. However, such a circular coil spring is difficult to manufacture and therefore costly.
On the other hand, in the conventional art disclosed in Patent Document 2, the ends of the wire of the coil spring are welded to form a circular coil spring. However, it is difficult to weld the ends of the wire of the coil spring and to secure the reliability. Therefore, there is a problem that the production cost increases and the securing of quality is difficult, similarly to the conventional art disclosed in Patent Document 1.
The present invention has been achieved in view of the above problems, and an object of the invention is to provide a contact with an easy-to-form circular coil spring, excellent reliability, and lower cost.
To solve the above problems and to achieve the above objects, according to an aspect of the present invention there is provided a contact including a first conductor that has a fitting hole formed therein; a second conductor that has a shaft that can be inserted into the fitting hole and an annular groove formed on an outer circumference of the shaft; and an inclined coil spring that has a ring inserted into a coil, is circularly formed by the ring to be provided inside the annular groove, and is in contact with the annular groove and the fitting hole to electrically connect the first and second conductors.
According to the contact of the present invention, the circular coil spring is easily formed, the reliability is excellent, and the increase of cost can be suppressed.
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Exemplary embodiments of a contact according to the present invention will be explained below in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments explained below.
As illustrated in
It is not necessary to connect both ends of the inclined coil spring 13 by welding in this configuration. Moreover, use of the insulating ring 14, which is cheaper, will lead to a large reduction in cost as compared to the conventional ring disclosed in Patent Document 1 or 2. Furthermore, because the distortion of the inclined coil spring 13 does not occur due to weld and it is not necessary to perform a heat treatment. As a result, the quality and reliability of the inclined coil spring 13 can be improved.
The first and second conductors 11 and 12 are made of any of copper, a copper alloy, aluminum, and an aluminum alloy. The first and second conductors 11 and 12 are also plated with silver to raise their surface electrical conductivity. The inclined coil spring 13 is made of a copper alloy that is excellent in spring property. In consideration of the stability of electric conduction performed by the inclined coil spring 13 and the possibility that minute foreign metal pieces generated by friction between the insulating ring 14 and the inclined coil spring 13 affect the insulation performance of the gas insulated switchgear badly, it is preferable that the insulating ring 14 is made of insulating resin such as Teflon (registered trademark) or glass epoxy resin. It is needless to say that the insulating ring 14 can be made of metal. Alternatively, the insulating ring can be made of metal and only the surface of the insulating ring can be coated with insulating resin. When the insulating ring is a metal ring, local heat generation may take place when a current is passed, and an electric arc may occur due to accidental shunt of short-circuit currents.
The Z axis-direction width size Wd of the cross section of the insulating ring 14 is larger than the size T of the radial-direction thickness of the insulating ring. When the insulating ring is formed in this way, a radial-direction gap is secured between the inclined coil spring 13 and the insulating ring 14 even if the inclined coil spring 13 is inserted into the fitting hole 11a and is compressed in a radial direction to slant the coil further.
The inclined coil spring 13 is helically wound at a slant so that the shape of the inclined coil spring is an ellipse and the short axis of the ellipse forms an acute angle with the central axis line of the coil as illustrated in
When such a configuration is employed, the axial-direction both ends of the insulating ring 14 prevents the inclined coil spring 13 from being deformed in the long-axis direction and prevents the inclined coil spring 13 from being twisted in the annular groove 12b. Therefore, the inclined coil spring 13 will deform only in the short-axis direction. Moreover, because the inclined coil spring 13 is provided inside the annular groove 12b so that its short axis is directed to the radial direction of the shaft 12a, the annular groove 12b can be shallow. Therefore, it is not necessary to deeply machine the annular groove. In this way, the machining cost can be reduced and the cross section for electric conduction of the second conductor 12 can be increased.
As illustrated in
The axial-direction both ends of the insulating ring 14 are formed in the shape of a hemicycle in the embodiment. However, the shape of the axial-direction both ends is not necessarily limited to a hemicycle. For example, the cross section of the insulating ring 14 may be formed in the shape of a rectangle and an angular portion coming in contact with the inclined coil spring 13 may be chamfered.
As illustrated in
Moreover, the angle of inclination of the lateral surfaces 12d and 12e of the annular groove 12b is set to an acute angle, a conducting distance of the wire of the inclined coil spring 13 is shortened and a contact pressure is increased, and electric resistance and electric contact resistance of the inclined coil spring are reduced. The more the angle of inclination of the lateral surfaces 12d and 12e of the annular groove 12b approaches 90 degrees (a right angle), the better the electric conduction performance becomes. However, the inclined coil spring 13 easily falls into the bottom surface 12c of the annular groove 12b, and the electric conduction performance becomes unstable when the inclined coil spring 13 easily falls. Therefore, it is preferable that the angle of inclination be somewhat smaller than 90 degrees in consideration of the fluctuation of a component tolerance. Moreover, the lateral surfaces 12d and 12e of the annular groove 12b are plane surfaces in the embodiment. However, the lateral surfaces 12d and 12e can be curved surfaces.
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As described above, the contact according to the present invention is useful for a gas insulated switchgear used in a high-voltage transmission system.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2008/057289 | 4/14/2008 | WO | 00 | 10/7/2009 |