Composite material for producing an electric contact surface, in addition a method for creating a lubricated, corrosion-free electric contact surface

Description

FIELD OF THE INVENTION

The present invention relates to a composite material for manufacturing an electrical contact area, comprising a support material and a contact surface applied on the support material, and to a method for producing a low-friction and low-corrosion electrical contact surface.

BACKGROUND INFORMATION

Contact areas are used to enable an electrical plug connection between a connector and mating connector, and to conduct current accordingly. In automotive applications in particular, tin, gold, or silver surfaces are used for the surfaces of the electrical contact areas. These are hot-galvanized or electroplated layers in the range of a few micrometers, which are applied onto a support material, for example a circuit board. The layers themselves have properties of deformability and good electrical conductivity.

At the interfaces to typical copper-based alloys, for example bronze, that often serve as the basic material for electrical plug connections, diffusion results in the formation of an intermediate layer that is made of intermetallic compounds, e.g. Cu₃Sn or Cu₆Sn₅. This intermediate layer is harder, and can grow as a function of temperature.

Several other alloys based on the elements recited above may be found, for example SnPb, SnAg, SnAgCu, AuCu0.3.

Tin alloys, in particular, have low hardness and therefore also little wear resistance; as a result, frequent insertion/removal, or vehicle or engine-related vibrations can very easily cause the contact surface to be rubbed through, which in turn means that the plug connection has a tendency toward oxidation, i.e., so-called fretting corrosion. As a result of this rubthrough and/or the corresponding fretting corrosion, failures of important electrical components can cause disruptions to the operation of a motor vehicle.

Another disadvantage is that the aforementioned alloys have very high adhesion tendencies, so that the insertion forces that must be applied in order to establish an electrical plug connection are very high. The plastic deformation associated therewith is also too great for many applications. The adhesion can in fact cause the layer to be torn off or transferred, or to become chipped.

Similar processes can also occur with gold and silver surfaces if the contact surface is rubbed through and the material located beneath is correspondingly oxidized.

SUMMARY

It is an object of the invention to avoid the disadvantages of the existing art by creating a method and a material with which the insertion forces necessary for establishing an electrical plug connection are reduced, and the oxidation processes that occur are minimized.

The object is achieved by creating a composite material which is produced in such a way that a lubricant is incorporated into the contact surface.

By way of a modification of the frictional state and surface condition, the insertion forces for establishment of an electrical plug connection are reduced and the connection is protected from oxidation and fretting corrosion.

Lubricants having specific additives, for example perfluoropolyethers, ester oils, or similar materials, may achieve this effect. These additives are applied separately; this may entail a separate production step, metering control, preparation of the oil, etc. Lubricant incorporation, on the other hand, namely the “freezing” of microscopic oil dispersions into the contact surface, yields the advantage that lubricant molecules are made available at the contact points experiencing wear, so that the desired properties are achieved.

A further advantage of the invention is the fact that by way of a partial treatment, individual contact regions can be specifically treated.

By selecting a suitable material, it is possible to ensure that only a brief melting of the surface is produced, in particular, as a result of the laser treatment, using a Nd:YAG laser, for example. During this melting operation, the lubricant that had previously wetted the surface to be treated diffuses into the contact surface. Switching off the laser causes the contact surface to solidify again to assume almost its original state. The lubricant molecules themselves become embedded in the fluid structure, however, and the fluid structure solidifies together with the melted surface, so that a portion of the lubricant is embedded (incorporated) within the contact surface.

The excellent slip property ensures that as a result of the insertion operation, the connector slides along the slide contact and does not remove material at the very first insertion operation and thus provoke corresponding corrosion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic view of a first method step of the method according to an example embodiment of the present invention.

FIG. 2 shows a schematic view of the method according to an example embodiment of the present invention after completion of the first and second processing procedure.

DETAILED DESCRIPTION

FIG. 1 depicts a support material 1 on which a contact surface 2, which may include, for example, tin, is applied.

Prior to the actual processing procedure for producing a low-friction, low-corrosion electrical contact surface 2′ (as shown in FIG. 2), contact surface 2 is equipped with a lubricant film 3. As an alternative to this, provision is made for immersing support material 1, together with contact surface 2, into a bath.

Brief melting of the contact surface is accomplished, in the example embodiment depicted here, by way of a pulsed laser, such as a Nd:YAG laser. The corresponding light waves 4 are depicted schematically in FIG. 1. The light waves of the pulsed laser penetrate through lubricant film 3 almost without modification, and melt contact surface 2. Temperatures between 200 and 400° C. are achieved and liquify the metallic contact surface 2; as a result of this aggregate state, lubricant film 3 penetrates into the almost-liquid contact surface 2 and mixes with it.

As a result of the pulsing (power level, duration) of the Nd:YAG laser, which is to be adapted to the coating material, the melting occurs in controlled fashion, so that immediately after the end of the corresponding pulses, contact surface 2 solidifies together with the lubricant already diffused into the liquid contact surface, and the corresponding situation as shown in FIG. 2 is thus achieved. The new contact surface 2′ on support material 1 thus corresponds to a micro- or nanodispersion of metallic layer and lubricant.