Welding Device and Welding Method for Producing a Material Bond Connection between a Conductor and a Connecting Part

Abstract

The subject matter relates to a welding device as well as a welding method for producing a material bond connection between a conductor (10) and a connecting part (8), with at least one ultrasonic welding tool (4), wherein at least part of a contact surface (18) of the connecting part (8) contacts at least part of a contact surface (16) of the ultrasonic welding tool (4).

Description

The subject matter relates to a welding device as well as a welding method for producing a material bond between a conductor and a connecting part, with at least one ultrasonic welding tool, in particular with at least one sonotrode or at least one anvil, wherein at least part of a contact surface of the connecting part contacts at least part of a contact surface of the ultrasonic welding tool. The aforementioned welding connection between conductor and connecting part will be used in particular in automotive applications, preferably in the connection of conductors, in particular flat conductors, with connecting parts, in particular with flat parts.

The welding of conductors and connecting parts to each other by means of ultrasonic welding processes is sufficiently well known. In an ultrasonic welding process, an ultrasonic vibration is introduced by a sonotrode into one of the components to be welded together. This ultrasonic vibration causes the two components to be welded to move relative to each other at their contact surfaces. This relative movement results in friction and ultimately in welding of the surfaces of the two components to be welded together at a welding surface.

This type of welding is particularly useful when welding aluminum contact parts, since ultrasonic welding breaks up an aluminum oxide layer on the contact surface between the components to be welded. Ultrasonic welding plasticizes at least one of the two components to be welded together at the contact surface, resulting in a material bond.

In ultrasonic welding processes known from the prior art as well as ultrasonic welding devices, it is usual to first arrange a connecting part on an ultrasonic welding tool, in particular on a sonotrode or on an anvil, and then to fix the connecting part on the ultrasonic welding tool, in particular on a lower ultrasonic welding tool, by means of a frictional connection. However, such a process is disadvantageous in that it can compensate for production-related manufacturing tolerances of the connecting part only to a limited extent. The production-related manufacturing tolerances of the connecting parts to be welded mean that repeatable positioning of the connecting parts on the ultrasonic welding tool is only possible to an inadequate extent.

Furthermore, the welding method used for welding connecting parts and conductors can be selected as a function of the welding path. The welding path can be defined as the distance covered by the ultrasonic welding tool from the first contact with the conductor and/or the connecting part to the end of the welding cycle. Depending on the hardness and stiffness of the joining partners used, the welding path can be as low as 0.2 mm, for example. Due to the production-related manufacturing tolerances of the connecting parts and/or the conductors, the welding path can deviate by up to 0.3 mm compared to a connecting part with a completely flat contact surface and/or a conductor with a completely flat contact surface. Thus, it is critical for the process reliability and process repeatability of the ultrasonic welding process that such deviations of the weld path are avoided.

Furthermore, it is common for the connecting parts to be fixed to the ultrasonic welding tool by means of a force fit. This is usually accomplished by means of clamping the connection elements, whereby at least two surfaces of the connecting part that are not to be welded are clamped by means of pressing means. These surfaces of the connecting means are also not completely flat, but have certain process-related manufacturing tolerances and/or surface roughnesses, so that the position-related deviation of the connecting parts on the ultrasonic tool is further increased as a result.

The subject matter was therefore based on the object of specifying a welding device and a welding process that enable reproducible and reliable welding of a connecting part to a conductor.

This task is solved by a welding device according to claim 1 and by a welding method according to claim 8.

A welding device for producing a material connection between a conductor and a connecting part, having at least one ultrasonic welding tool, wherein at least a part of a contact surface of the connecting part contacts at least a part of a contact surface of the ultrasonic welding tool, is sufficiently known.

In such an apparatus, an ultrasonic welding tool, in particular a sonotrode or an anvil, is moved onto another ultrasonic welding tool, in particular an anvil or a sonotrode. The sonotrode is excited with ultrasonic vibration via an ultrasonic converter and an optional booster. With the aid of the contact force of the sonotrode or anvil on the connector or conductor, the ultrasonic vibration is introduced into the connector or conductor. Welding occurs in the area of the contact surfaces of the connecting part and the conductor that are in contact.

To apply the contact force, which makes it possible to introduce the ultrasonic vibration, the horn is moved in the direction of the anvil by means of a feed device. It is also possible that the sonotrode is fixed and the anvil is moved in the direction of the sonotrode. In this respect, a feed device by which the sonotrode and the anvil are movable relative to each other is proposed. The linear movement of the feed device preferably leads to two end positions, namely an open position and a final welding position. Between these two positions, the horn and anvil are movable relative to each other.

The contact surfaces of the connecting part and the ultrasonic welding tool are defined as those surfaces which are designed to be in contact with the ultrasonic welding tool or the connecting part. At least parts of these contact surfaces are formed in such a way that they have profiles corresponding essentially to one another and/or are formed in such a way that they can engage in one another at least partially in a form-fitting manner.

A profiling in the sense of the application is any surface condition that exceeds usual surface tolerances and/or usual surface roughnesses of the contact surfaces of the ultrasonic welding tool and/or the connecting part. In this context, it is preferred that the profiles of the connecting part and of the ultrasonic welding tool are formed in such a way that the profiles at least partially engage in one another in a form-fitting manner and/or correspond substantially to one another.

As a result, the effective surface in contact between the connecting part and the ultrasonic welding tool can be increased during the welding process compared to flat contact surfaces of the connecting part and the ultrasonic welding tool known from the prior art, so that the process accuracy of the welding process can be increased. In particular, due to the mutually corresponding profiling and/or due to the positive interlocking of the connecting part and the ultrasonic welding tool, a welding process or a welding device can be provided that is robust with respect to production-related manufacturing tolerances of the connecting part. In particular, a variance of the welding path can be reduced so that a process-safe and reliable welding of the connecting part and conductor is made possible.

In this context, it is preferred that the mutually corresponding profilings of at least one part of the contact surface of the connecting part and of the at least one part of the contact surface of the ultrasonic welding tool are designed in such a way that the profilings can be manufactured in a process-favorable manner and also lead to a higher process accuracy during the welding of the connecting part and conductor. For example, the profiles can be jagged and/or triangular in shape.

According to an embodiment, it is proposed that the profilings are formed by substantially mutually corresponding wave-shaped profilings of at least part of the contact surfaces of the connecting part and the ultrasonic welding tool. Wave-shaped profilings are favorable to manufacture from a constructional point of view and lead to the fact that the connecting element can be arranged in a reliable manner on the ultrasonic welding tool, thus enabling a process-reliable welding between the connecting part and the conductor.

According to an embodiment, it is proposed that the profilings are formed by substantially mutually corresponding corrugated profilings of at least a part of the contact surfaces of the connecting part and the ultrasonic welding tool. Fluted profilings are favorable to manufacture from a design point of view and result in the connecting element being arrangeable on the ultrasonic welding tool in a reliable manner, thereby enabling a process-reliable weld between the connecting part and the conductor.

According to an embodiment, it is proposed that the conductor is a flat conductor or a bus bar and/or that the connecting part is a flat part. A flat conductor and/or a flat part preferably have a substantially rectangular cross-section with two narrow sides and two broad sides. The connecting part can be designed, for example, as a cable lug, as a crimp contact, as a connection lug or likewise as a conductor. Furthermore, it is preferred that the conductor, in particular the flat conductor, has an insulated region and a stripped region, wherein at least a part of the stripped region of the conductor is welded to the connecting part.

According to an embodiment, it is proposed that the connecting part is formed of an aluminum material or a copper material, in particular that the connecting part is formed of a composite material. Furthermore, it is preferred that the conductor is an aluminum stranded conductor. The ultrasonic welding process is particularly advantageous in the case of joining partners comprising at least partially aluminum, since during welding by means of ultrasound an aluminum oxide layer is broken up at the contact surface between the components to be welded.

According to an embodiment, it is proposed that the welding device comprises a further ultrasonic welding tool, that at least one part of a contact surface of the further ultrasonic welding tool contacts at least one part of a contact surface of the conductor, and that the at least one part of the contact surface of the further ultrasonic welding tool and/or the at least one part of the contact surface of the conductor has a further profiling. The further ultrasonic welding tool may be a sonotrode or an anvil. By providing the profiling and/or the profilings, a reproducible welding process can be provided which exhibits sufficient process reliability. When providing profilings each on at least a part of the contact surface of the further ultrasonic welding tool and on at least a part of the contact surface of the conductor, it is preferred that the profilings substantially correspond to each other and/or can be brought into positive engagement with each other.

According to an embodiment, it is proposed that the further profiling and/or the further profilings are formed by wave-shaped profilings, by serrated profilings or by fluted profilings. Serrated, fluted or wavy profilings are favorable to manufacture from a design point of view and result in the connecting element being arrangeable on the ultrasonic welding tool in a reliable manner, thus enabling a process-reliable welding between the connecting part and the conductor.

According to an embodiment, it is proposed that the connecting element is fixed on the ultrasonic welding tool in a force-fit manner. This can enable precise positioning of the connecting part on the ultrasonic welding tool, whereby additional process accuracy can be achieved.

In the following, the subject matter is explained in more detail with reference to a drawing showing embodiments. In the drawing show:

FIG. 1 a schematic view of an embodiment of a welding device, and

FIG. 2 shows another embodiment of a welding device in a schematic view.

FIG. 1 shows a welding device 2 in a schematic view comprising a lower ultrasonic welding tool 4 and an upper ultrasonic welding tool 6. The lower ultrasonic welding tool 4 can be formed, for example, as a sonotrode and the upper ultrasonic welding tool 6 as an anvil. It is also possible that the lower ultrasonic welding tool 4 is formed, for example, as an anvil and the upper ultrasonic welding tool 6 is formed as a sonotrode. A connector 8 is arranged on the lower ultrasonic welding tool 4, which is welded to a conductor 10. The conductor 10 has an insulated area 12 and a stripped area 14.

Both the connecting part 8 and the lower ultrasonic welding tool 4 have contact surfaces 16 and 18 on their surfaces facing each other. On at least a part of the contact surfaces 16 and 18, the connecting part 8 and the lower ultrasonic welding tool 4 have mutually corresponding profilings 20 and 22. The profilings 20 and 22 are wave-shaped and lead to a positive interlocking of the connecting part 8 and the lower ultrasonic welding tool 4, whereby the process accuracy can be improved during the welding process.

FIG. 2 shows a further embodiment of a welding device 2 in a schematic view. The conductor 10 is designed as a flat conductor and has a stranded conductor 11 with an insulation 13, the insulation 13 being removed on the side to be welded to a connecting part 8. On at least a part of the contact surfaces 16 and 18, the connecting part 8 and the lower ultrasonic welding tool 4 have profiles 24 and 26 corresponding to one another, the profiles 24 and 26 being formed in a corrugated manner.

After the connecting part 8 has been arranged on the lower ultrasonic welding tool 4, the connecting part 8 is non-positively fixed with the aid of pressing means 29. The upper ultrasonic welding tool 6 has a serrated profiling 30 on at least part of its contact surface 28, with the aid of which the conductor 10 can be additionally fixed during the welding process.

Claims

1-9. (canceled)

10. Welding device for producing a material bond connection between a conductor and a connecting part, with at least one ultrasonic welding tool, pressing tool and at least on connecting part,wherein at least a part of a contact surface of the connecting part contacts at least a part of a contact surface of the ultrasonic welding tool, whereinthe at least one part of the contact surface of the connecting part and the at least one part of the contact surface of the ultrasonic welding tool have profilings corresponding substantially to one another andthe pressing tool is arranged for fixing, with a force fit, the connecting part onto the ultrasonic welding tool with at least two surfaces of the connecting part not to be welded.

11. Welding device according to claim 10, wherein that the profilings are formed by substantially mutually corresponding wave-shaped profilings of at least part of the contact surfaces of the connecting part and of the ultrasonic welding tool.

12. Welding device according to claim 10, wherein the profilings are formed by substantially mutually corresponding corrugated profilings of at least part of the contact surfaces of the connecting part and of the ultrasonic welding tool.

13. Welding device according to claim 10, wherein the conductor is a flat conductor or a bus bar and/orthe connecting part is a flat part.

14. Welding device according to claim 10, wherein the connecting part is formed from an aluminum material or a copper material, in particular in that the connecting part is formed from a composite material.

15. Welding device according to claim 10, with at least one conductor, whereinthe welding device has a further ultrasonic welding tool,at least part of a contact surface of the further ultrasonic welding tool contacts at least part of a contact surface of the conductor, andthe at least one part of the contact surface of the further ultrasonic welding tool and/or the at least one part of the contact surface of the conductor have a further profiling.

16. Welding device according to claim 15, wherein the at least one further profiling and/or the further profilings are formed by wave-shaped profilings, by serrated profilings or by fluted profilings.

17. Welding method for producing a material bond connection between a conductor and a connecting part, in which the connecting part is arranged on at least one ultrasonic welding tool,wherein at least a part of a contact surface of the ultrasonic welding tool and at least a part of a contact surface of the connecting part are in contact with each other, whereinat least one part of the contact surface of the connecting part and the at least one part of the contact surface of the ultrasonic welding tool have profilings corresponding to one another,wherein at least a portion of the connecting part is welded to the conductor by means of the ultrasonic welding tool,whereinthe at least one part of the contact surface of the connecting part and the at least one part of the contact surface of the ultrasonic welding tool at least partially interlock andthe connecting part is fixed, with a force fit, the onto the ultrasonic welding tool with at least two surfaces of the connecting part not to be welded by the pressing tool.