The present invention relates to a contact device used in a conductive connection unit of an electrical apparatus.
In order to improve device-assembly property of electrical apparatus, its conductor is divided into several pieces. Therefore, a contact device for connecting between conductors to each other becomes necessary for easily assembling these conductors. In the contact device, because electric current also flows therethrough similarly to the conductors, in order to prevent heat generation due to electrical resistance, a stable low-electrical-resistance device is required. Moreover, based on a case-by-case system to which the device is applied, the device is required to have a function which absorbs a relative displacement due to size tolerance of the apparatus and/or that generated by thermal expansion/contraction of the conductors depending on its atmospheric condition.
For example, a conventional contact device of a gas-insulated switching apparatus has been configured in such a way that a pair of conductors arranged on the same axis are fitted to each other at their ends in the axis direction, and the conductive contact is arranged in a fitted portion between the conductors, so as to flow current therethrough (for example, refer to Patent Document 1).
The above described contact device disclosed in Patent Document 1 includes at least two kinds of gaps in the fitted portion of the conductor pair, and the gaps are formed by protrusions provided in a cylindrical inner periphery of the conductors. The contact device arranged in the fitted portion of the conductor pair is configured of a coil-spring shaped one having a spring action. A stable contact resistance to the conductor pair can be obtained by a contact load obtained by the spring action. According to such a configuration, in a contact portion of the conductor pair, because a stable contact load can be obtained even though varying the insertion angle of the conductors, a value of stable contact resistance can be obtained.
The spring contact is formed by spirally winding a bare wire constituted by highly electrical-conductive spring material with the wound wire being tilted by an angle less than 90 degrees to its winding axis, so as to be integral and belt-like, and is formed to be circular by jointing its both ends together, which is arranged in a groove provided along the circumferential direction on one of the fitted faces of the conductor pair. Here, the groove is provided in plural numbers along the axis direction, and a plurality of circular spring contacts is arranged in the axis direction.
Because the spring contact is formed by the spiral winding with tilting by the angle less than 90 degrees to the winding axis, its cross section perpendicular to the winding axis becomes elliptical, thereby providing a characteristic in which spring elasticity is provided thereon in the short-axis direction. Thereby, when the spring contact whose cross section is elliptical is fitted into the groove, with the side faces of the spring contact in the short axis direction facing the bottom face of the groove, and arranged in a gap between the pair conductors, elastic repulsion force of the spring contact acts between the spring contact and each of the conductors, providing a low-contact-resistance.
[Patent document 1]
The conventional contact device has been configured as described above; therefore, the bare wire of the spring contact and the conductor are made contact to each other, and many contact points are created. However, because the curvature radius of the bare wire of the spring contact is relatively small, the contact area contacting the conductor becomes small; thereby, contact pressure obtained by repulsion force of the spring elasticity is necessarily increased. Therefore, what has been a problem is an increased friction amount according to the increase of the contact pressure. Moreover, there is a problem that powders to be a cause of contact failure are generated by the friction at the contact portion between the contact and the conductor, thereby increasing electrical resistance of the contact device.
An objective of the present invention, which is made to solve the above described problem, is to provide a contact device which has, compared to the conventional device, a decreased contact pressure against a conductor caused by elastic repulsion force of a spring contact, to thereby enable suppressing friction and reducing electrical-resistance.
There is provided a contact device according to the present invention, comprising a pair of conductors that have been arranged on the same axis and moved in its axis direction to fit each other, a conductive spring contact arranged along a portion where a fitting face of any one of the conductors and a plane crossing to the axis direction of the pair of conductors are crossing to each other, and a conductive contact piece arranged between a fitting face of the other of the conductors and the spring contact, so that an electric current flows between the pair of conductors through the conductive spring contact and the conductive contact piece, the contact device characterized in that the spring contact is formed of a bare wire being spirally wound with tilting against the winding axis thereof, and has an elliptical cross section, and the contact piece is divided into a plurality of segments in a direction of the winding axis of the spring contact, and line-contacts or face-contacts said other of the conductors.
According to the present invention, the contact pressure against the conductor due to the elastic repulsion force of the spring contact can be reduced, and the friction between the contact piece and the conductor can be suppressed. Moreover, suppressing the friction results in preventing the increase of the electrical resistance of the contact device.
1: First conductor, 2: Second conductor, 1a and 2a: Conductor-side installation groove, 3: Spring contact, 4: Contact piece, 4a: Contact-piece-side installation groove, 5: Connection unit
In
Conductor-side installation grooves 2a are provided along the circumferential direction on the outer face of the small-diameter portion of the second conductor 2. Spring contacts 3 are located in the installation grooves 2a whose cross-sectional shapes (cross-sectional shapes perpendicular to the circumferential direction) are rectangular, and the second conductor 2 and the spring contacts 3 are electrically connected to each other.
Conductive contact pieces 4, for example, made of metal, which are segmented into a plurality of segments in the winding axis direction of the spring contacts 3 (circumferential direction of the first conductor 1 or the second conductor 2), are arranged between the spring contacts 3 and the inner peripheral face of the first conductor 1, so as to cover the spring contacts 3, and each of the contact pieces 4 is electrically connected to the spring contacts 3 and to the first conductor 1.
Contact-piece-side installation grooves 4a are extendedly provided in the circumferential directions on the inner peripheral faces of the contact pieces 4. The cross-sectional shape (cross-sectional shape perpendicular to the circumferential direction) of the installation grooves 4a is rectangular, and the spring contacts 3 are located in the installation grooves 4a.
The installation grooves 2a are provided in a plural number at predetermined positions in the axis (line B) direction, and the plurality of the circular spring contacts 3 are arranged in the axis (line B) direction.
Here, the number of the installation groove 2a may be single, or one spring contact 3 may be configured to be arranged in the single installation groove 2a provided at a predetermined position in the axis (line B) direction.
Because the spring contacts 3 are each formed by the spiral winding with tilting by the angle less than 90 degrees against the winding axis, its cross section perpendicular to the winding axis becomes elliptical, thereby providing a characteristic showing spring elasticity in the short axis direction. Therefore, the spring contacts 3 are arranged between the second conductor 2 and the contact pieces 4, with the spring contacts being embedded in the installation grooves 2a so that side faces in the short axis direction of the elliptical cross sections of the spring contacts 3 are contacted to the bottom faces of the installation grooves 2a, as well as being embedded in the installation grooves 4a of the contact pieces 4. According to the above described configuration, the elastic repulsion force of the spring contacts 3 acts between the spring contacts 3 and the second conductor 2, between the spring contacts 3 and the contact pieces 4, and between the contact pieces 4 and the first conductor 1, thereby providing low electrical contact resistance.
Here, each size of the conductor-side installation grooves 2a and the contact-piece-side installation grooves 4a is assumed to be designed so that the sum of the depth of the grooves 2a and that of the grooves 4a becomes smaller than the outer diameter, in the short axis direction, of the spring contacts 3.
The contact pieces 4 are each constituted of a plurality of contact piece segments whose number is the same as the spring-winding turn number of each spring contact 3, and are arranged on the outer periphery of the spring contacts 3 in a manner that each one of the contact piece segments 4 corresponds to each one of winding turns of the spring contact 3, so that the inner peripheral face of each of the contact piece segments 4 and each bare wire of the spring contact 3 are electrically connected to each other. Moreover, the outer peripheral face of each of the contact piece segment 4 and the inner peripheral face of the first conductor 1 are electrically connected to each other.
In order to arrange the plurality of the contact piece segments 4, so as to correspond to the bare-wire positions of the spring contact 3 that are disposed along the circumferential direction and are placed at a regular pitch, at the same pitch as that of the bare wire, the plurality of the contact piece segments 4 are connected by a connection unit 5.
Here, in
The contact pieces 4 are formed of a plate-like shape and made of a material having conductivity. The contact piece segments 4 have curved faces that contact the first conductor 1, and each of the contact piece segments 4 and the first conductor 1 line-contact to each other in a direction perpendicular to the axis direction. That is, each of the curved faces, as represented in
According to such a configuration, because the contact state of the contact pieces 4 and the first conductor 1 becomes a line-contact one, their contact area increases in comparison with the case where the spring contact and the conductor are point-contacted to each other as in the conventional configuration, resulting in reducing the surface pressure against the first conductor 1 caused by the elastic repulsion force of the spring contacts 3. By reducing the surface pressure against the first conductor 1, the assembling of the conductor becomes easier, and an effect of reducing the friction between the contact pieces 4 and the first conductor 1 during the assembling can also be expected. Moreover, due to the prevention of the friction, the increase in electrical-resistance of the contact device is prevented, thus allowing a longer-term usage of the contact device.
Because the contact state of the contact pieces 4 and the first conductor 1 is a line-contact one in the direction perpendicular to the axis direction, an effect can be obtained that foreign substances causing contact failure when relative displacement occurs by thermal expansion/contraction, of the conductor depending on the atmospheric condition, are removed from the contacting portion.
Here, in the above embodiment, as represented in
In Embodiment 1, the cross-sectional shape of the installation grooves 4a of the contact pieces 4 is rectangular. In Embodiment 2, the cross-sectional shape of the installation grooves 4a (cross-sectional shape perpendicular to an extending direction of the installation grooves 4a) is a V-shaped one whose opening angle is θ1. The groove angle θ1 of the installation grooves 4a having V-shaped cross sections has an arbitrary angular value larger than 0 degree and smaller than 180 degrees.
The other configurations and functions are similar to those of the contact device represented in Embodiment 1.
According to such a configuration, the spring contacts 3 each contact dual positions of both side walls of each of the installation grooves 4a of the contact pieces 4; that is, the number of the contact positions between each of the spring contacts 3 and each of the contact pieces 4 can be set to be dual. Therefore, the contact areas between the spring contacts 3 and the contact pieces 4 increase compared to those in a single-contact state; as a result, the contact electrical resistance can be reduced. Moreover, the current paths inside the spring contacts 3 are shortened; as a result, the electrical resistance between the second conductor 2 and the contact pieces 4 can be reduced.
In Embodiment 2, the cross-sectional shape of the installation grooves 4a provided on the contact pieces 4 is given to have a V-shaped (or U-shaped) concave curved face. In Embodiment 3, the installation grooves 4a of the contact pieces 4 are circular in cross-sectional shape perpendicular to the extending direction of the installation grooves 4a. The other configurations and functions are similar to those of the contact device represented in Embodiment 1.
As represented in
Therefore, on this occasion, the contact areas between the contact pieces 4 and the spring contacts 3 also increase, to thereby reduce the electrical resistance between the contact pieces 4 and the second conductor 2.
Here, in this embodiment, although the spring contacts 3 cannot be embedded inside the installation grooves 4a, the spring contacts 3 can be prevented from moving in the axis direction thereof by the installation grooves 2a and 4a.
While shown in Embodiment 2 is the installation grooves 4a of the contact pieces 4 which is V-shaped in cross section, in Embodiment 5, the cross section of the installation grooves 2a of the second conductor 2 where the spring contacts 3 are embedded (cross section perpendicular to the extending direction of the installation grooves 2a), is also designed to be similarly V-shaped. The groove angle of the V-shaped cross-sectional installation grooves 2a is an arbitrary angle larger than 0 degree and smaller than 180 degrees.
The other configurations and functions are similar to those of the contact device represented in Embodiment 2.
According to such configuration, each of the spring contacts 3 contacts dual points of both side walls of each of the installation grooves 4a of the contact pieces 4, and also contacts dual points of both side walls of each of the installation grooves 2a of the second conductor 2, that is, the number of the contact portions of each of the spring contacts 3 to each of the contact pieces 4, and to the second conductor 2 can be respectively made to be dual. Therefore, the contact area of the spring contacts 3 and the contact pieces 4 increases compared to that of the single-contact states, resulting in reduction of the contact resistance. Moreover, the conductive path inside the spring contact is shortened, to thereby reduce the electrical resistance between the second conductor 2 and the contact pieces 4.
Here, in
In Embodiment 1, as represented in
Here, in
It can be realized to increase the number of the line-contact portions between each of the contact pieces 4 and the first conductor 1, by providing, for example, as represented in
According to such a configuration, the contact areas between the contact pieces 4 and the first conductor 1 increase, and the contact resistance can be reduced. Moreover, because the contact pressure is further decreased, the friction between the contact pieces 4 and the first conductor 1 can be suppressed.
In Embodiments 1 to 6, the devices are represented in which the installation grooves 2a and 4a are provided on the contact pieces 4 and the second conductor 2 for defining the arrangement positions of the spring contacts 3; however, in Embodiment 7, the spring contacts 3 are held at predetermined positions of the second conductor 2 by way of the elastic force of the spring contacts 3 without providing such installation grooves 2a and 4a, whereby the spring contacts 3 are sandwiched between the contact pieces 4 and the second conductor 2.
The other configurations and functions are similar to those of the contact devices represented in Embodiments 1 and 6.
Also, in such a configuration, the contact state of the contact pieces 4 and the first conductor 1 becomes a line-contact one, and thus the surface pressure against the conductor 1 due to the elastic repulsion force of the spring contact can be reduced, thereby reducing the friction between the contact pieces 4 and the first conductor 1.
Here, in
In Embodiments 1 to 6, the configurations of arranging the spring contacts 3 between the second conductor 2 and the contact pieces 4 are represented, whereas, in Embodiment 8, the spring contacts 3 are arranged between the first conductor 1 and the contact pieces 4. That is, as represented in
The contact pieces 4 are each constituted of a plurality of contact piece segments whose number is the same as the spring-winding turn number of each spring contact 3, and are arranged on the inner periphery of the spring contacts 3, in a manner that each one of the contact piece segments 4 corresponds to each one of winding turns of the spring contact 3, and the contact piece segments 4 are arranged at a regular interval so as to cover the spring contacts 3. In order to arrange a plurality of the contact piece segments 4, at the same interval as that of the bare wire of the spring contact 3 that forms lines at a regular interval along the circumferential direction, and in place corresponding to the positions of the bare wire lines, the plurality of the contact pieces 4 are connected by the connection unit 5. Each outer peripheral face of the contact piece segments 4 and the bare wire of the spring contact 3 are electrically connected to each other, and each inner peripheral face of the contact piece segments 4 and the outer peripheral face of the second conductor 2 are electrically connected to each other.
Each contact piece segment 4 has a face as curved one to be in contact with the second conductor 2, and the contact piece segments 4 and the second conductor 2 are line-contacted in a direction perpendicular to the axis direction. That is, as represented in
According to such a configuration, the contact state of the contact pieces 4 and the second conductor 2 becomes a line-contact one, and thus the surface pressure against the second conductor 2 due to the elastic repulsion force of the spring contacts 3 can be reduced. By reducing the surface pressure against the second conductor 2, an effect can be expected that the assembling of the conductor becomes easier as well as the friction between the contact pieces 4 and the second conductor 2 is reduced during the assembling.
Here, in each of the above embodiments, the spring contacts 3 are configured to be arranged along the plane perpendicular to the axis direction of the conductors 1 and 2; however, the spring contacts 3 may be arranged along any plane crossing to the axis direction of the conductors 1 and 2.
In Embodiments 1 to 7, the devices are represented in which the contact piece segment 4 is configured to have the face, opposite to the first conductor 1, of a convex curved one having a curvature radius also in the axis direction, and the contact state of the contact piece segment 4 and the first conductor 1 is a line-contact one; however, the contact piece segment 4 may be configured so that its face opposite to the first conductor 1 includes a flat face in the axis direction, at least at a portion to be in contact with the first conductor 1 so that the contact state of the contact pieces 4 and the first conductor 1 is a plane-contact one. According to such a configuration, the surface pressure against the first conductor 1 due to the elastic repulsion force of the spring contacts 3 can be reduced; therefore, an effect can be expected that the friction between the contact pieces 4 and the first conductor 1 during the assembling is reduced.
Similarly, in Embodiment 8, the device are represented in which the contact state of the contact piece segment 4 and the second conductor 2 is a line-contact one; however, the contact piece segment 4 may be configured so that its face opposite to the second conductor 2 includes a flat face in the axis direction, at least at a portion to be in contact with the second conductor 2 so that the contact state of the contact pieces 4 and the second conductor 2 is a plane-contact one. According to the configuration, the surface pressure against the second conductor 2 due to the elastic repulsion force of the spring contacts 3 can be reduced; therefore, an effect can be expected that the friction between the contact pieces 4 and the second conductor 2 during the assembling is reduced.
Moreover, in Embodiments 1 to 8, the first conductor 1 as well as the second conductor 2 is made to be columnar; however, the conductors may be another cylindrical shape.
Furthermore, it may be so configured that the first conductor 1 is formed of a flat plate having a U-shaped cross section in its end portion, the second conductor 2 is formed of a flat plate which can be inserted into the gap inside the U-shaped portion of the first conductor 1, the spring contact is provided, along a direction perpendicular to the insertion direction of the second conductor, on an insertion face of one of the conductors (top or bottom face of the second-conductor edge or inner face of the U-shaped portion of the first conductor), and the conductive contact piece is provided between the spring contact and the other one of the conductors, whereby electric current flows between a pair of conductors through the spring contact and the contact piece.
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WO2009/072263 | 6/11/2009 | WO | A |
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