Production of a planar connection between an electrical conductor and a contact piece

Abstract

A method is provided for electrically conductively connecting a contact part to a conductor having a multiplicity of individual wires includes inserting the conductor into a cavity in the contact part and lowering a tool for friction stir welding onto the contact part. The tool for friction stir welding is moved on the contact part in a plane, thus giving rise to a planar cohesive connection between the contact part and the conductor. In this way, a direct cohesive connection of a stranded conductor and a contact part is produced without the need for an additional part such as a sleeve, for example, to prevent the stranded conductor from sticking out.

Claims

1. Method for electrically conductively connecting a contact part to a conductor having a multiplicity of individual wires, said the method comprises the steps of: inserting the conductor into a cavity in the contact part; lowering a tool for friction stir welding onto the contact part; moving the tool for friction stir welding on the contact part in a plane, thus giving rise to a planar cohesive connection between the contact part and the conductor.

2. Method according to claim 1, wherein said method further comprises the step of cohesively connecting the individual wires of the conductor to one another.

3. Method according to claim 1, wherein moving the tool for friction stir welding is effected in a plane that is substantially perpendicular to a direction in which lowering the tool is carried out.

4. Method according to claim 1, wherein moving the tool is effected translationally along a line.

5. Method according to claim 1, wherein moving the tool for friction stir welding is a two-dimensional movement that is effected in a plane that is substantially perpendicular to a direction in which lowering the tool is carried out.

6. Method according to claim 5, wherein the two-dimensional movement of the tool for friction stir welding is effected translationally along an X-Y contour.

7. Method according to claim 5, wherein the two-dimensional movement of the tool for friction stir welding is composed of a superimposition of a translational and circular movement.

8. Electrical line comprising: a conductor, which has a multiplicity of individual wires and which is connected to a contact part, wherein the individual wires of the conductor are connected among one another and to the contact part by a planar cohesive connection produced by friction stir welding.

9. Electrical line according to claim 8, wherein the contact part is produced on the basis of copper or aluminium or an alloy thereof.

10. Electrical line according to claim 8, wherein the contact part is a busbar.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0026] The invention is explained in greater detail by way of example below on the basis of an embodiment with reference to the accompanying figures. All the figures are purely schematic and not to scale. In the figures:

[0027] FIG. 1 shows a plan view of an end side of a solid contact part;

[0028] FIG. 2 shows a cross section through the contact part from FIG. 1 with an inserted conductor;

[0029] FIG. 3A shows a first plan view of the contact part with the inserted conductor from FIG. 2;

[0030] FIG. 3B shows a second plan view of the contact part with the inserted conductor from FIG. 2;

[0031] FIG. 3C shows a third plan view of the contact part with the inserted conductor from FIG. 2; and

[0032] FIG. 4 shows a flow diagram of the method according to the invention.

[0033] Identical or similar elements are provided with identical or similar reference signs in the figures.

DETAILED DESCRIPTION

[0034] FIG. 1 schematically shows a plan view of an end side of a contact part 100 embodied as a solid component. The contact part 100 has a cavity 101, which serves for receiving an electrical conductor, as will be described further below. The cavity 101 is embodied as a blind hole, for example, the way in which the cavity is produced not being of importance in association with the invention. Besides other machining production methods, the cavity can also be produced by forming of the contact part or, if the contact part is a cast part, during the casting of the contact part. The cavity can also be embodied as a groove.

[0035] In one exemplary embodiment, the contact part 100 has securing means (not illustrated) used to connect the contact part to an electrical battery or an electrical machine, for example. In the simplest case, the securing means are screw holes into which a corresponding securing screw is inserted.

[0036] FIG. 2 shows the contact part from FIG. 1 in a cross section with a conductor 200 inserted into the cavity 101 of the contact part 100. The conductor 200 is produced from a multiplicity of individual wires or individual strands which are twisted and/or stranded together and form a stranded conductor. The conductor 200 is surrounded with an insulating sheath 202. The individual strands 201 consist of aluminium or an aluminium alloy. Since aluminium and its alloys readily oxidize and become coated with an insulating oxide layer, during practical use of stranded conductors composed of aluminium it is of great importance for all the individual strands 201 to be contacted in order that the cross section of the conductor 200 is utilized as well as possible for current transport. The insulating sheath 202 is removed at an end of the conductor 200 which is inserted into the cavity 101 of the contact part 100. As is evident from FIG. 2, the diameter of the cavity 101 is dimensioned such that the conductor 200 is able to be inserted into the cavity without the individual strands 201 sticking out, i.e. without individual or a plurality of individual strands 201 not being received in the cavity 101 but rather jutting outwards.

[0037] The electrical connection between the contact part 100 and the conductor 200 is produced by a planar cohesive connection which firstly produces a metallurgical connection between the conductor 200 or the stranded conductors 201 and the contact piece 100 and secondly produces at the same time a metallurgical connection between the individual stranded conductors 201. A good transverse conductivity is produced in this way, such that all the individual strands 201 contribute to current transport and the cross section of the conductor 200 is utilized optimally for current transport.

[0038] According to the invention, the planar cohesive connection is produced by friction stir welding. In this welding method, the temperature required for a weld is generated by friction. In this case, the material of the contact part 100 bonds to the stranded conductor 200 cohesively at a temperature below the melting point of the metals used or they are welded together by diffusion. Contributions to this are also made by the pressure applied by the tool 203, and the deformation work performed as a result. The tool used in the method accordingly has a friction surface 204, the efficacy of which is improved by a projecting tip 206 arranged centrally. In order to produce the connection, the rapidly rotating tool 203 is lowered onto the contact part 100. In FIG. 2, the rotation of the tool 203 is indicated by an arrow R, and the lowering movement by an arrow P. The tool 203 exerts pressure on the contact part 100, which pressure together with the rotational movement causes the material of the contact part 100 and the individual strands 201 to convert to a plastic state and to enter into a metallurgical cohesive connection among one another.

[0039] When the tool 203 is placed against the contact part 100, it has advantageously already been caused to rotate. However, it can also be caused to rotate only after it has been placed against the contact part.

[0040] Merely lowering the rotating tool 203 only results in a spot weld, however, which is insufficient for high-voltage and/or high-current applications such as are present in the case of electric vehicles, for example.

[0041] FIG. 3A illustrates how a planar connection between the conductor 200 and the contact part 100 is achieved. For this purpose, the tool 203, the diameter of which approximately corresponds to or is greater than the diameter of the conductor 200, is moved onto the contact part 100 along the arrow 301. This gives rise to a planar welding connection by way of friction stir welding with the advantages mentioned in the introduction. The area of the weld approximately corresponds to the diameter of the tool 203 in one direction and to the length of the arrow 301 in the other direction.

[0042] FIG. 3B illustrates an alternative procedure for producing the planar connection between the contact part 100 and the conductor 200. In accordance with the alternative procedure, the tool 203, the diameter of which is less than the diameter of the conductor 200, is moved along an X-Y contour, wherein a planar cohesive welding connection is once again produced by friction stir welding. The X-Y contour is indicated by an arrow 302 in FIG. 3B. This alternative method is advantageous particularly if the conductor 200 has a comparatively large diameter.

[0043] Finally, FIG. 3C shows a further method for producing the planar cohesive connection between the contact part 100 and the conductor 200. In this case, the tool 203 is moved on a cycloid along the conductor 200 inserted into the contact part 100. The cycloid arises as a result of the superimposition of a translational movement with a circular movement and is symbolized by the arrow 303 in FIG. 3C. This method, too, is suitable for conductors 200 having a comparatively large diameter.

[0044] In other embodiments, the tool executes other movement patterns, for example a zigzag line, on the contact part 100. In further embodiments, the tool 203 executes movement patterns on the contact part 100 which are produced from a combination of the movement patterns described.

[0045] The direction in which the tool 203 is lowered is symbolized by an arrow A into the plane of the drawing in FIGS. 3A to 3C. Accordingly, the tool 203 executes a movement towards the contact part 100 in the plane of the drawing.

[0046] In all the methods for producing the planar cohesive connection illustrated in FIGS. 3A to 3C, the tool 203 is raised from the contact part 100 when the tool 203 has moved a little way beyond the end of the conductor 200 situated in the cavity 101. As a result, the conductor 200 is cohesively connected to the contact part 100 over its entire length situated in the cavity 101.

[0047] FIG. 4 shows a flow diagram of the method for producing a planar cohesive connection in a general form. In a first step S1, the conductor 200 is inserted into the cavity 101 in the contact part 100. Then, in a step S2, the tool 203 for friction stir welding is lowered onto the contact part 100 and caused to rotate if it was not already rotating prior to being lowered. Finally, in a step S3, the lowered tool 203 is moved on the contact part 100 in a plane that extends substantially perpendicular to the direction in which lowering the tool 203 is carried out. In this last step S3, the individual strands 201 of the conductor 200 are cohesively connected to one another and to the contact part 100, thus giving rise to a planar cohesive connection.

LIST OF REFERENCE SIGNS

[0048] 100 Contact part [0049] 101 Cavity [0050] 200 Conductor [0051] 201 Individual strands [0052] 202 Insulating sheath [0053] 203 Tool [0054] 204 Friction surface [0055] 206 Lug [0056] 301 Direction of movement [0057] 302 Direction of movement [0058] 303 Direction of movement