The invention relates to an electrical contact device of the contact finger type for high nominal current.
A first known example of an embodiment of electrical contact of the contact finger type between a first part 10 and a second part 11 is shown in
A second known example of an embodiment of electrical contact of the contact finger type consists in a one-piece contact, in which the three above-described functions of providing electrical contact, of passing electricity, and of acting as a spring are combined in a single element that is obtained for example, by machining or by die-stamping.
This second example constitutes an economical embodiment. However, a difficulty remains due to the current-passing function and the spring function being dimensioned together. The current-passing function would require a choice of materials having conductive properties suitable for limiting temperature rises: typically copper, aluminum, or alloys thereof. However, the use of such materials for providing the spring function leads to considerable limits concerning contact dimensions, notably because of the stresses and of the resulting force, in particular because of a maximum stress that must not be exceeded for the material. As a result, for a given size, said second example presents a limit value for acceptable nominal current.
The invention aims to modify such a one-piece contact, or a contact that is close in design to such a one-piece contact, in order to increase the nominal current in a given size.
The invention provides an electrical contact device of the contact finger type for high nominal current between a first part that is conductive and a conductive surface of a second part, said device comprising a flexible rod connected to a first connection element for mechanical and electrical connection to the first part, a contact portion applied on the conductive surface of the second part, and at least one metal contact blade placed at a first end between a first end of the flexible rod and the first part, the device being characterized in that the flexible rod is conductive and in that the at least one metal blade is connected at its second end to the second end of the flexible rod by means of a second mechanical and electrical connection element. The first connection element may comprise a screw or a rivet. The second connection element may comprise a rivet. The second connection element may be made by crimping and deforming a prominent portion of a contact pad. The first connection element may be connected to the first part by screw-fastening. In a first embodiment the flexible rod and the contact portion form a single piece. Advantageously, the flexible rod and the contact portion are made of copper, aluminum, or alloys thereof.
The device of the invention makes it possible to increase the nominal current for a given size.
The
In the device of the invention, as shown in
The contact element 20 comprises a first portion 22 in the form of a rod and a second portion 23 in the form of a contact pad that may form parts of a single piece or that may form two separate pieces. A first end of the at least one blade 21 is disposed between the first part 10 and the first end of the first portion of the conductive part 20, that is itself connected to said first part 10 via the connection element 16. A second end of the at least one blade 21 is connected to the second end of the first portion 22 of the contact element 20 by a mechanical and electrical connection element 24.
The at least one contact blade makes it possible to increase the nominal current without increasing the contact force.
The reference 25 designates the contact zone between the second portion 23 of the contact element 20 and the conductive surface 26 of the second part 11.
This first connection element 16 may be made with the help of a screw or rivet 30 connecting the contact element 20 and the contact blade(s) 21 to the first part 10. A single link thus enables the three elements to be joined together: first part 10, metal blades 21, and contact element 20.
When the clamping force is considerable, in order to limit the compression stress in the conductive materials and/or in order to provide a satisfactory current-passing surface, a force-distribution washer 31 may be used that is placed under the screw or rivet head.
The second connection point between the blade or blades 21 and the contact element 20 may be made either by a rivet 40, as shown in
In an advantageous example embodiment, the contact element 20 may have a length lying in the range 3 centimeters (cm) to 15 cm, a thickness in its first portion 22 lying in the range 3 millimeters (mm) to 20 mm. Each metal blade may have a thickness lying in the range 0.1 mm to 1 mm. The contact element 20 and the blades may be made of copper, aluminum, or alloys thereof.
Number | Date | Country | Kind |
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1259334 | Oct 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/070318 | 9/30/2013 | WO | 00 |