The present invention concerns a method for the electrical connection of an electrical conductor to a contact element as well as a plug connector with a conductor and a contact element, wherein the connection between conductor and contact element was produced according to the method. The present invention in particular concerns a method for the connection of a flat flex conductor to a contact element by resistance welding. The invention finds application, for example, in the automobile industry, where flat flex conductors are utilized increasingly due to the incorporation of additional electrical components, in order to be able to better conduct the increasingly larger current fluxes over a larger cross section of the conductor. The invention can be utilized in all types of conductors, in particular flat flex conductors, which have been produced, for example, in laminated, printed, etched or extruded manner.
For connecting a plug connector or contact element to a conductor, various contacting techniques are known, such as crimp contactings, material-fitted contactings or clamp contactings. In the case of material-fitted contactings, the connection can be produced, for example, by soldering, adhering or welding, wherein welding methods provide better mechanical and electrical properties for the contacting sites than does soldering or adhering. When welding the conductive track to the contact element of a plug connector, the welding can be produced by resistance welding, laser welding or ultrasound welding. In the present field of plug contacts, resistance welding finds a broad application since it can be conducted simply and rapidly as well as in a cost-effective manner.
It was previously necessary, however, prior to the welding process, to strip the insulation from the electrical conductor at the end on which it is connected to the contact element. This step of stripping the insulation complicates the production process and makes it expensive, which is a particular disadvantage for the cost-sensitive automobile field.
The object of the present invention is thus the provision of a rapid connection that is simple to conduct, cost-effective, and which can be maintained both mechanically and electrically.
This object is solved according to the invention by a method according to patent claim 1.
According to the invention, the following steps are conducted when connecting an electrical conductor to a contact element:
To begin with, the electrical conductor that is ensheathed with insulation is introduced between two legs of the contact element. Then the welding device is applied to the two legs and the welding process is conducted, whereby the welding current is turned on. The insulation of the electrical conductor is broken down by the welding current and the heat introduced thereby during the welding process, which leads to a solid mechanical and electrical connection of the conductor with the contact element.
A stripping of the insulation of the electrical conductor prior to the welding process is no longer necessary due to the method according to the invention. The electrical conductor, in a state in which the insulation is not stripped, can be simply inserted between the legs of the contact element. In this way, the welding process can be considerably shortened, which considerably reduces the cost of production of plug connector components.
In a preferred embodiment, the welding process is conducted by resistance welding, wherein the heat introduced is produced by the current flowing in the welding process and the ohmic resistance of the conductor. The method according to the invention, however, is not limited to resistance welding; other fusion welding methods such as electrical arc welding or gas welding or also other pressure welding methods can be applied.
At the beginning of the method according to the invention, for example, in a resistance welding, the current flows out over the two legs of the contact element, i.e., from the anode over one leg, then to the other leg over the cathode. The current does not yet flow over the conductor provided with insulation to the cathode. Since the introduced heat is very high and the current always seeks the shortest path, the insulation lying between the legs of the contact element, which [legs] guide the current, begins to melt, so that the current then flows directly from the anode to the first leg, then the electrical conductor to the second leg to the cathode. In this way, however, a welding current generally arises, and this current must flow first over the two legs and the point where the two legs are connected to one another via a “bypass”.
Preferably, in the welding process, the welding device is applied to the outer sides of the two legs lying opposite the conductor.
Preferably, one welding stamp of the welding device is applied to one outer side of the contact element, so that the two welding stamps sandwich the two legs of the contact element and the electrical conductor introduced therein.
In a preferred embodiment, the contact element is additionally connected to a plug connector, which can be connected to a complementary plug connector, for further guiding the current path of the electrical conductor.
Preferably, the electrical conductor is a flat flex conductor, which is produced, for example, by laminating, printing, etching or extruding. The method according to the invention, however, is not limited to the connection of flat flex conductors with contact elements. The electrical conductor can have any shape.
Preferably, the contact element is bent in S shape, whereby the conductor is inserted into one of the two openings of the S. Likewise, the contact element can also be C-shaped, whereby the conductor is then inserted into the C-shaped opening. The contact element, however, can also be laterally clipped onto the conductor. It is advantageous for the embodiment of the invention only that the electrical conductor is enclosed by the contact element on two sides which are joined together. A U-shaped formation of the contact element is also possible.
The invention likewise concerns a plug connector, which has a contact element and an electrical conductor connected to the contact element, wherein the connection between contact element and electrical conductor was produced according to the method described above.
In order to better understand the invention, it is described in more detail below, with reference to the appended schematic drawings. Here:
a–4d show different embodiments of the connection of the electrical conductor with the contact element,
In
An excerpt of a circuit board 10 with its conductive tracks 22, which are provided with an insulation 6, is shown in
Several plug connectors 11 are shown in
The contact element 1, which is soldered to the conductive track at one end, is provided on its other end with the plug connector 11, which is shaped like a bushing in the embodiment shown.
The plug connector 11 has clips 25, which are bent inwardly, on its back end, on which can be attached, among other things, conductor elements of a mating plug connector. The plug connector has an insulating housing 26, which has a raised side wall 27 for encoding and a locking leg 28, which extends obliquely upward, spring-loaded by a bridge 29 counter to the direction of introduction, with which the plug connector 11 can be attached in an uptake (not shown).
In
In summary, it can be established that a good electrical connection between an electrical conductor and a contact element can be achieved by the method according to the invention in a simple and rapid manner, with a welding method.
Number | Date | Country | Kind |
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102 50 930 | Oct 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP03/11739 | 10/23/2003 | WO | 00 | 4/19/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/040702 | 5/13/2004 | WO | A |
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Number | Date | Country | |
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20060060372 A1 | Mar 2006 | US |