EP2722930A1 - Coated contact element - Google Patents

Abstract

The element has a contacting area for contacting a complementary contact element, and a connection area connected with an electrical conductor (40), and comprises two areas (5, 6). One of the areas comprises a metallic coating i.e. tin-zinc-alloy (140). Another area is provided with a metallic coating i.e. zinc-tin-alloy (141), that is different from the coating of the former area. The coating of the former area consists of higher tin content than the coating of the latter area, and the coating of the latter are has higher zinc content than the coating of the former area. An independent claim is also included for a method for manufacturing an electrical contact element.

Description

The invention relates to an electrical contact element having a contacting region for contacting a complementary contact element and a connection region for connection to an electrical conductor, wherein the connection region has a metallic coating. As well as a method for producing such a contact element.

There is a continuing trend in automotive engineering to use aluminum as the conductor material in the cabling of automobiles. In practice, aluminum alloys with adapted properties are used. Aluminum cables have the advantage of being lighter and cheaper than copper cables. Even if the, compared to copper, lower electrical conductance requires a larger cross-section, usually outweigh the benefits of aluminum. However, the combination of aluminum and copper contact elements can, under certain conditions, cause effects that would not occur if only copper materials were used.

When using aluminum leads with contacts made of copper, corrosion is a special feature. According to the electrochemical series of aluminum and its alloys and copper and its alloys, there is a voltage difference between the materials, which results in current flow when contacting the materials with an electrolyte. In a vehicle, the electrolyte is typically salt water. The galvanic corrosion between the contact area of the contact and the aluminum lead causes that without further constructive measures, a use in the vehicle can not be realized.

Common measures are the sealing of the contact point by means of sealed plugs or the application of liquid sealant. Another possible ability to reduce corrosion is to coat the contact elements made of copper sheet with a metallization, typically tin alloy, so that a layer between the contact element and the aluminum is. Through this layer is achieved that the electromotive force of the galvanic reaction is reduced to a low potential, so that the galvanic corrosion is no longer in a critical range.

It has been found that the alloy layer has to fulfill two different functions. In the area in which the aluminum conductor is contacted, the layer must be particularly conductive. In the area that is close to the surface of the aluminum conductor, and can establish an electrical connection via an electrolyte, the layer must protect well against corrosion. For a good conductivity, a high tin content is necessary whereas for a good corrosion protection a high zinc content is an advantage.

The invention has for its object to provide an electrical contact element made of copper, which in the connection area has a coating which conducts particularly well and at the points where electrolyte can electrically connect the different metals provides good corrosion protection. As well as a method for producing a contact element having these properties.

The object is achieved by an electrical contact element having the features of claim 1 and in particular by the fact that the second region is provided with a metallic coating which differs from the coating of the first region and is suitable for reducing corrosion.

The invention utilizes selective and sequential deposition of tin and zinc monolayers on the terminal region, typically by electroplating. The tin layer is applied to the connection area. Thereafter, the zinc layer is applied to the tin layer. Subsequently, the contact element is subjected to a heat treatment, which is referred to as annealing. During annealing, the two layers mix to form an alloy. The proportions of tin and zinc in the alloy result from the layer thicknesses of the respective layers. Thus, in principle, any desired tin-zinc concentration can be adjusted.

Usually contact elements are made of tinned copper sheet. In this case, the contact element is separated from the support plate, wherein punching edges arise that have no tin coating and therefore are very susceptible to corrosion. If this contact element is treated as described, a second tin layer is applied to the tin layer already applied during tinning of the metal sheet. The tin layer in the contacting region is thus significantly stronger than at the punching edge. The zinc layer applied to the tin layer is rather thin in the contacting area, compared to the tin layer. A subsequent heat treatment causes mixing of the layers. The result is an alloy layer whose main components are tin and zinc. The concentration of the shares is spatially different. This results in the connection area to the Conductor a highly conductive layer with high tin concentration, hereinafter called tin-zinc alloy. At the Panzkannte results in a layer with higher zinc content, hereinafter called zinc-zinc alloy. The punched edge adjoins the surface of the aluminum conductor, so the protective coating is at the most vulnerable point for corrosion.

For coating a galvanic process is used here, but other methods such as sputtering, dipping and Lackierverfahre etc. possible. These methods can be used to create layer systems with a defined mixing ratio, depending on the required functionality.

Advantageous embodiments of the invention are described in the dependent claims, the description and the drawings.

According to one embodiment, the second region adjoins the surface of the electrical conductor when the contact element is connected to an electrical conductor. As a result, the region of the contact element which would be particularly susceptible to corrosion in the presence of an electrolyte is protected under the corrosion-inhibiting coating.

Tin and zinc alloys are preferably used for the coating. The properties of these elements are well known in the art and have long been used in the industry. However, other metals which are electrically conductive and reduce the corrosion potential can also be used.

Preferably, the coating in the first region has a higher tin content than the coating in the second region. To one to achieve low contact resistance at the junction between the aluminum conductor and the contact element

According to another embodiment, the coating in the second region has a higher zinc content than the coating in the first region. Since the second region adjoins the surface of the conductor, a higher zinc content in the coating is preferred for a corrosion-resistant layer. A coating in the first range is preferred with a tin content in the range of 65% -100% and a zinc content in the range of 0% -35%. This ratio gives a very conductive bonding layer between the contact element and the aluminum conductor.

In a further embodiment, the coating in the second region comprises a tin content in the range of 50% -95% and a zinc content in the range of 5% -50%. This ratio creates a layer that provides good corrosion protection.

The layer thickness of the coating in the first region is preferably in the range of 1-10 μm and the layer thickness of the coating in the second region in the range of 0.1-5 μm. By varying the layer thicknesses in these ranges, the concentration of tin and zinc in the alloy can be set very accurately. This allows the properties of the layer to be determined.

According to a further embodiment, the contact element consists of copper or a copper-based alloy. The use of copper alloys allows the mechanical and electrical properties of the contact element to be precisely adjusted.

The connection region preferably has a crimp section with crimp wings and a holding region with holding wings. After attaching the cable to the connection area of the Kotaktelements, the Crimpflügel abut the surface of the conductor and provide for mechanical and electrical contact. The holding wings are pressed into the insulation of the conductor and increase the mechanical connection and thus the resistance against unintentional pulling out of the conductor.

Advantageously, the crimping section is arranged between two holding regions along an axis in order to fasten conductors, coming from opposite sides, together in the crimping section. This arrangement, wherein the axis can be seen as an extension of the conductor, allows greater flexibility in the positioning of the contact element. Narrow spaces often require a predetermined position of Kotaktelement to electrical conductors. This problem is mitigated by an additional firing option. Another application of this embodiment is the use as a contact element for connecting two or more electrical lines together. Known in the art as Splice Crimp. In this case, the function of the contacting area is in the background and only the extended connection area is used.

Preferably, galvanic processes are used for the coating. The terminal region of the contact element is coated in a known manner, each with a layer of tin on the following a layer of zinc is applied. This sequential coating by standardized coating processes enables the creation of a SnZn layer system. The subsequent annealing process mixes tin and zinc. In practice, temperatures in the range of 80 ° C - 240 ° C are used. ever After the selected temperature, the process time of tempering must be designed accordingly. At a temperature of 240 ° C, the annealing time is about 10 minutes. At a temperature of 80 ° C, the annealing time of about 12 hours to 48 hours. The tempering is carried out according to the furnace used according to a corresponding process curve. In this case, the temperature profile is used for the required layers and thus produces the desired mixing at the corresponding areas.

Preferably, the terminal area is used as known in the art. This connection area already possesses a layer of tin which, however, is missing due to the process steps carried out in the production process. The connection area is thus very well suited for being coated with the inventive method.

Particularly advantageous is a coating with matte tin or bright tin has been found.

Another embodiment relates to a connecting line comprising an inventive contact element which is connected to an electrical conductor. Wherein the electrical conductor is preferably made of aluminum or an aluminum alloy. This connection line has a low electrical resistance and a high corrosion resistance.

Fig. 1

eine perspektivische Ansicht eines Kontaktelements aus dem Stand der Technik.

Fig. 2

eine perspektivische Ansicht eines Kontaktelements mit einem, daran befestigten Leiter

Fig. 3

eine Schnittansicht des Kontaktelements und des elektrischen Leiters aus Fig.2 wobei der Schnitt entlang der Achse A verläuft

Fig. 4

eine Detailvergrößerung des Kontaktelements nach Fig. 3. Der Bereich entspricht dem, in Figur 3 mit dem Buchstaben B gekennzeichneten, Bereich.

Fig. 5

die Detaildarstellung nach Fig. 4.wobei eine Zinnschicht auf das Anschlusselement aufgebracht ist.

Fig. 6

die Detaildarstellung nach Fig. 5 wobei eine Zinkschicht auf die Zinnschicht auf aufgebracht ist.

Fig. 7

die Detaildarstellung nach Fig. 6.nachdem das Anschlusselement einer Wärmebehandlung ausgesetzt wurde.

Fig. 8

eine Schnittansicht eines Kontaktelements das nach dem erfinderischen Verfahren beschichtete ist. Wobei der Schnitt entlang der Achse A verläuft.

The invention will be described below by way of an advantageous embodiment purely by way of example with reference to the accompanying drawings
described. Show it:

Fig. 1

a perspective view of a contact element of the prior art.

Fig. 2

a perspective view of a contact element with a conductor attached thereto

Fig. 3

a sectional view of the contact element and the electrical conductor Fig.2 the section being along the axis A.

Fig. 4

an enlarged detail of the contact element after Fig. 3 , The area corresponds to the, in FIG. 3 marked with the letter B, area.

Fig. 5

the detailed representation after Fig. 4 .With a tin layer is applied to the connection element.

Fig. 6

the detailed representation after Fig. 5 wherein a zinc layer is applied to the tin layer.

Fig. 7

the detailed representation after Fig. 6 .after the connection element has been subjected to a heat treatment.

Fig. 8

a sectional view of a contact element coated according to the inventive method. Wherein the section runs along the axis A.

Fig. 1 shows a known from the prior art contact element 1 in a perspective view. It has a contact region 2 and a connection region 3. The connection region 3 is subdivided into a crimp section 10 and a holding region 11. The crimp section 10 has two crimp wings 20 with which an electrical conductor (not shown here), by pressing the Crimpflügel 20 around the conductor, can be electrically contacted. The holding area 11 has two holding wings 22 which can be pressed onto the insulating layer of the conductor to improve the pull-off force. The contact element 1 has a tin layer 7 covering the surface of the contact element. At the punching edge 6 this tin layer 7 is missing.

Fig. 2 shows a known in the prior art contact element 1 in a perspective view. The contact element was connected in this illustration with a conductor 40. The Crimpflügel 20 enclose the electrical conductor 40. The retaining wings 22 enclose the insulation 42 of the electrical conductor 40th

Fig. 3 shows a sectional view of the crimping portion 10 of in Fig.2 The contact extends vertically along axis A. In this illustration, an electrical conductor 40 is connected to the contact element 1. The contact element 1 has on its surface a tin layer 7 which is missing at the punched edge 6. This is due to the fact that in the manufacture of the contact element 1, a tinned copper sheet is used, from which the mold is punched out. The conductor 40 is enclosed by the Crimpflügel 20 after the pressing. The tin layer 7 is located between the inside of the Crimpflügel 20 and the surface 41 of the conductor 40. The punched edge 6 is located adjacent to the surface 41 of the conductor 40th

Fig. 4 shows a detail of the cut representation FIG. 3 , The illustrated region corresponds approximately to the circle marked B, but without representation of the conductor 40. The inner side 5 of the crimping tab 20 has a tin layer 7. At the punching edge 6 this layer is missing.

Fig. 5 shows a view accordingly FIG. 4 however, after a tin layer 130 has been applied to the contact element 1. On the inside is now on the tin layer 7, a further tin layer 130. The punched edge 6 is covered only by tin layer 130.

Fig. 6 shows a view accordingly FIG. 5 wherein a layer of zinc was applied to the contact element. The tin layers 7, 130 are covered by the zinc layer 131.

Fig. 7 shows a view accordingly FIG. 6 , This view time the contact element 1 after it has been subjected to a heat treatment. The tin layers 7, 130 and the zinc layer 131 have mixed through the heat treatment. It has formed a layer that has regionally different tin-zinc mixing ratios. The coating on the punching edge 6 contains a high proportion of zinc. This zinc-tin alloy 141 is particularly resistant to corrosion. The area outside the punching edge 6 contains a high tin content. This tin-zinc alloy 140 is particularly conductive.

Fig. 8 shows a sectional view of the contact element after FIG. 1 after being coated with the inventive coating method. The view corresponds to the view in Fig. 3 and also shows the crimp section 10 of the contact element 1. The crimp wings 20 have on their inner side 5 a coating with the tin-zinc alloy 140. The tin-zinc alloy 140 covers the entire crimping portion 10 except for the punched edge 6. The punched edge is covered by the zinc-tin alloy 141. The conductor 40 is enclosed by the Crimpflügel 20 after the pressing. The tin-zinc alloy layer is located between the inside 5 of the crimping section 10 and The surface 41 of the conductor 40. Between the punched edge 6 and the surface 41 of the conductor 40 are also a layer of zinc-tin alloy 141st

Claims (15)

An electrical contact element (1) having a contacting region (2) for contacting a complementary contact element and a connection region (3) for connection to an electrical conductor (40), wherein the connection region (3) comprises two regions (5, 6),
the first region (5) has a metallic coating (140) which is suitable for contacting with an electrical conductor (40) and a second region (6) which adjoins the first region (5),
characterized in that the second region (6) is provided with a metallic coating (141) different from the coating of the first region (5). Electrical contact element (1) according to claim 1,
characterized in that the second region (6) abuts the surface (41) of the electrical conductor (40) when the contact element is connected to an electrical conductor. Electrical contact element (1) according to claim 1,
characterized in that the coating (140, 141) consists of an alloy based on tin and zinc. Electrical contact element (1) according to claim 3,
characterized in that the coating (140) in the first region (5) has a higher tin content than the coating in the second region (6). Electrical contact element (1) according to claim 3,
characterized in that the coating (141) in the second Region (6) has a higher zinc content than the coating in the first region (5). Electrical contact element (1) according to claim 4,
characterized in that the coating (140) in the first region (5) comprises a tin content in the range of 65% -100% and a zinc content in the range of 0% -35%. Electrical contact element (1) according to claim 5,
characterized in that the coating (141) in the second region (6) comprises a tin content in the range of 50% -95% and a zinc content in the range of 5% -50%. Electrical contact element (1) according to claim 1,
characterized in that the layer thickness of the coating (140) in the first region (5) in the range of 1-10 microns and the layer thickness of the coating (141) in the second region (6) in the range of 0.1-5μm. Electrical contact element (1) according to claim 1,
characterized in that the contact element (1) consists of copper or a copper-based alloy. Electrical contact element (1) according to claim 9,
characterized in that the connection region (3) comprises a crimp section (10) with crimp wings (20) and a holding region (11) with holding wings (22). Electrical contact element (1) according to claim 9,
characterized in that the crimping portion (10) is disposed between two holding portions (11) along an axis to come together conductors (40) from opposite sides to be fixed in the crimp section and held in the holding area. Method for producing an electrical contact element (1) according to one of Claims 1 to 11,
characterized by the following steps: providing the connection region (3) of the contact element (1), Degreasing the connection area (3), Rinsing the connection area (3), Electrolytic degreasing of the connection area (3), Rinsing the connection area (3), Picking the connection area (3), Rinsing the connection area (3), Coating the connection area (3) with tin, Rinsing the connection area (3), Picking the connection area (3), Rinsing the connection area (3), Coating the connection area (3) with zinc, Rinsing the connection area (3), Drying the connection area (3). Annealing the connection area (3). Method according to claim 12,
characterized in that the connection region (3) has tinned and non-tin-plated regions (5, 6). Method according to claim 12,
characterized in that the used in step h) matte or gloss tin for coating. Connecting line comprising an electrical contact element (1) according to claim 1 and at least one electrical conductor (40).

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