阅读说明：本技术 用于与配合触头配合的电触头 (Electrical contact for mating with a mating contact ) 是由 V.塞佩 W.斯塔布罗思 于 2019-09-04 设计创作，主要内容包括：本发明涉及用于与配合触头(16)配合的电触头(1),包括铝主体(2),其沿纵向轴线(L)延伸,由铝或铝合金制成,铝主体(2)设置有用于连接到铝导体(6)的连接部分(4),接触区(10),布置在铝主体(2)的表面(8)上,用于电连接到配合触头(16),以及接触弹簧(12),连接到铝主体(2),具有用于接触配合触头(16)的接触区域(14),其中接触弹簧(12)至少部分地搁置在接触区(10)上,并且由比铝或铝合金更硬的材料形成,并且接触区(10)由比铝或铝合金更耐蠕变的材料形成。此外,本发明涉及接触装置(3),其包括根据本发明的电触头(1)和以整体结合和/或形状配合的方式连接到连接部分(4)的铝导体(6)。(The invention relates to an electrical contact (1) for mating with a mating contact (16), comprising an aluminum body (2) extending along a longitudinal axis (L), made of aluminum or an aluminum alloy, the aluminum body (2) being provided with a connection portion (4) for connecting to an aluminum conductor (6), a contact zone (10) arranged on a surface (8) of the aluminum body (2) for electrical connection to the mating contact (16), and a contact spring (12) connected to the aluminum body (2) having a contact region (14) for contacting the mating contact (16), wherein the contact spring (12) rests at least partially on the contact zone (10) and is formed of a material harder than aluminum or the aluminum alloy, and the contact zone (10) is formed of a material more resistant to creep than aluminum or the aluminum alloy. Furthermore, the invention relates to a contact arrangement (3) comprising an electrical contact (1) according to the invention and an aluminum conductor (6) which is connected to the connection portion (4) in an integrally bonded and/or form-fitting manner.)

1. An electrical contact (1) for mating with a mating contact (16), comprising:

an aluminum body (2) extending along a longitudinal axis (L), made of aluminum or an aluminum alloy, said aluminum body (2) being provided with a connection portion (4) for connection to an aluminum conductor (6),

a contact zone (10) arranged on the surface (8) of the aluminum body (2) for electrical connection to a mating contact (16), and

at least one contact spring (12) connected to the aluminum body (2) having a contact area (14) for contacting a mating contact (16),

wherein the at least one contact spring (12) rests at least partially on the contact area (10) and is formed from a material harder than aluminum or an aluminum alloy, and wherein the contact area (10) is formed from a material more resistant to creep than aluminum or an aluminum alloy.

2. The electrical contact (1) according to claim 1, wherein the aluminum body (2) is a stamped and bent part (26).

3. Electrical contact (1) according to claim 1 or 2, wherein the aluminium body (2) is made of an aluminium/magnesium alloy.

4. Electrical contact (1) according to any one of claims 1 to 3, wherein the contact zone (10) is made of a noble metal (32).

5. Electrical contact (1) according to any one of claims 1 to 4, wherein the contact zone (10) is arranged flush with the surface (8).

6. Electrical contact (1) according to any one of claims 1 to 5, wherein an intermediate layer (36) is arranged between the surface (8) and the contact region (10).

7. Electrical contact (1) according to any one of claims 1 to 6, wherein the at least one contact spring (12) is elastically deflectable between the contact region (10) and a contact area (14).

8. Electrical contact (1) according to any one of claims 1 to 7, wherein the aluminum body (2) has no form-fitting element.

9. Electrical contact (1) according to any one of claims 1 to 8, wherein the contact zone (10) is applied onto the aluminium body (2) by means of roll cladding.

10. Electrical contact (1) according to any one of claims 1 to 9, wherein the at least one contact spring (12) extends away from a sleeve (40) connected in a form-fitting manner to a free end (18) of the aluminum body (2), which free end faces away from the connection portion (4).

11. Electrical contact (1) according to claim 10, wherein the at least one contact spring (12) is bent around the free end (18).

12. Electrical contact (1) according to claim 10 or 11, wherein at least one outer surface (43) facing away from the aluminium body (2) is coated with a noble metal.

13. A contact arrangement (3) comprising an electrical contact (1) according to any one of claims 1 to 12 and an aluminum conductor (6) connected to a connection portion (4) in an integrally bonded and/or form-fitting manner.

14. The contact arrangement (3) according to claim 13, wherein the aluminium conductor (6) is welded to the connection portion (4).

Technical Field

The present invention relates to an electrical contact for mating with a mating contact. Furthermore, the invention relates to a contact arrangement having an aluminum conductor and an electrical contact.

Background

In the prior art, copper contacts made of copper or copper alloys are used to connect electrical conductors to mating contacts. However, these copper contacts have high weight and high material cost. However, particularly in the automotive industry, particularly in the case of large conductor cross sections, as is partially required in electric vehicles, lightweight is desired. Therefore, copper conductors such as copper cables are increasingly replaced by aluminum conductors made of aluminum or aluminum alloys. However, due to the mechanical stability of the copper, the copper contact is held in place so as to generate the necessary contact normal force with the mating contact. The connection of copper contacts to aluminum conductors can only be overcome with great effort.

Disclosure of Invention

The problem of the present invention is therefore to provide a solution which enables a stable electrical and mechanical contact between the electrical contact and the mating contact, as well as a simple connection to an aluminum conductor.

According to the invention, this problem is solved by an electrical contact comprising: an aluminum body extending along a longitudinal axis, made of aluminum or an aluminum alloy, the aluminum body being provided with a connection portion for connection to an aluminum conductor, a contact zone arranged on a surface of the aluminum body for electrical connection to a mating contact, and at least one contact spring connected to the aluminum body having a contact area for contacting the mating contact, wherein the at least one contact spring rests at least partially on the contact zone and is formed of a material harder than aluminum or the aluminum alloy, and wherein the contact zone is formed of a material more resistant to creep than aluminum or the aluminum alloy.

According to the invention, the contact arrangement comprises an electrical contact according to the invention and an aluminum conductor connected to the connection portion in an integrally bonded and/or form-fitting manner.

The use of an aluminum body results in weight and material cost savings compared to currently known electrical contacts, such as the copper contacts mentioned at the outset. Since the connecting portion of the aluminum body is likewise made of aluminum or an aluminum alloy, a simple connection of the aluminum conductor to the connecting portion is possible without expensive treatment of the connecting portion, as is the case, for example, with copper contacts. The contact with the mating contact is produced by at least one contact spring, whereby the aluminum body is subjected to less mechanical stress. The current is absorbed by the contact area via at least one contact spring. By the contact region being more resistant to creep than the aluminum body, a long-term contact of the mating contact can be achieved without losing contact quality, and wear on the electrical contact can be reduced.

For the application, the aluminum alloy includes all alloys in which aluminum is a main component.

In the following, developments are cited which can be combined with one another independently of one another as required and which are each advantageous when viewed independently.

Thus, according to a first advantageous configuration, the aluminium body can be a stamped and bent part. As a result, the aluminum body can be simply produced. The stamping and bending process by its precision and speed proves to be particularly advantageous in particular in connection with the mass production of electrical contacts.

The aluminium body may be made of an aluminium/magnesium alloy, in particular an AlMg3 alloy. As a result, the aluminum body can be tilted and welded very well, whereby the design of the aluminum body and/or the connection to the aluminum conductor can be further optimized. Furthermore, this alloy has good weather conditions and brine corrosion resistance compared to pure aluminum.

According to a particularly advantageous configuration, the contact region may be formed from a noble metal or a noble metal alloy. By using a contact area made of a noble metal or noble metal alloy, surface corrosion on the contact area, which may lead to a reduced conductivity, is avoided. In particular, the contact region may be made of silver or a silver alloy, whereby a good electrical conductivity is achieved in the contact region and surface corrosion is avoided. The material costs of silver or silver alloys remain at a limit compared to other precious metals such as gold. However, in alternative configurations, the contact region may be formed from other noble metals or noble metal alloys, such as gold or gold alloys or palladium alloys. Alternatively, the contact region may be formed of tin or a tin alloy, particularly in the case of applications in the lower temperature range, i.e. below about 120 ℃.

To avoid sharp edges at the transition between the surface and the contact zone, the contact zone may be arranged flush with the surface. In this case, flush arrangement means that there is no wear between the surface and the contact zone when sliding on the transition portion. The contact area can be deposited on the surface, for example by chemical vapor deposition, in particular by electron beam, or also by electroplating. Alternatively, the contact zone may be applied by roll cladding. In this case, the contact zone can be applied directly to the press belt, which is particularly advantageous for industrial manufacture of large numbers of press-bent parts.

According to a further advantageous configuration, an intermediate layer can be arranged between the surface of the aluminum body and the contact region. The intermediate layer may be formed of, for example, copper or a copper alloy, and may result in a material saving of the contact region material. The intermediate layer can thus in particular be made of a material having a lower material cost than the material of the contact region. As with the contact regions, the intermediate layer can be deposited on the surface by chemical vapor deposition, in particular by electron beam, or else by electroplating. Preferably, the intermediate layer may be applied to the surface by roll cladding. In this case, the intermediate layer can be applied directly to the punched strip, for example as a strip. The contact zone may be applied to an intermediate layer, wherein the intermediate layer may facilitate the application of the contact zone. For this purpose, in particular, the thickness and composition of the intermediate layer can be optimized. Furthermore, the intermediate layer may prevent aluminum from creeping from the aluminum body to the contact area.

The material thickness of the contact region may be between about 2 μm and about 10 μm thick. The material thickness of the intermediate layer may be between about 10 μm and about 20 μm thick.

The at least one contact spring may be made of a material, such as copper or a copper alloy, which is thermally more resistant to relaxation than aluminum or an aluminum alloy. Alternatively, the at least one contact spring may be made of stainless steel. As a result, it can be ensured that the material does not soften even at high temperatures and the contact normal force from the contact spring to the mating contact is not reduced.

The at least one contact spring may have a coupling region through which the at least one contact spring is coupled to the aluminum body. The coupling region can thus clamp the end of the aluminum body facing away from the connection portion, for example transversely to the longitudinal axis, and can be fixed to the aluminum body. Alternatively or additionally, the coupling region may be placed onto the free end. The coupling region may preferably have a catch mechanism that can engage with a compatible catch mechanism of the aluminium body, thus preventing accidental sliding of the coupling region from the aluminium body.

The coupling region may be shaped as a sleeve and, together with the aluminum body, may surround the socket cavity, wherein the sleeve may be placed onto a free end of the aluminum body facing away from the connection portion.

The at least one contact spring may be bent around the free end and may protrude into the socket cavity.

At least the outer surface of the sleeve facing away from the aluminium body may be coated with a precious metal. As a result, corrosion of the sleeve can be avoided. In particular, at least one contact spring may be coated with a noble metal at least on its contact area and/or support surface, by means of which the contact spring rests on the contact area. The coating of the contact spring can in particular be formed from the same material as the contact zone, whereby contact corrosion can be prevented when the mating contact and/or the contact zone are contacted.

The at least one contact spring may be bent around an end remote from the connection portion. The aluminum body can be configured, in particular, at least in sections in the form of a socket, which surrounds a socket cavity and is open in the longitudinal direction, wherein the contact region is arranged in the socket cavity. The at least one contact spring may protrude into the socket cavity and may at least partially rest on the contact region. One contact region may be arranged on each of the opposite sides in the socket cavity. Alternatively, the contact region may also extend radially around the socket cavity in the longitudinal section. The coupling region may be formed as a sleeve placeable onto the socket. In this case, corresponding to the side of the socket provided with the contact region, respectively at least one contact spring, preferably two contact springs, may extend away from the sleeve and may be bent into the socket cavity. In this respect, the mating contacts can be, in particular, plug contacts and/or round contacts, which are contacted from a plurality of sides by electrical contacts.

The contact spring is elastically deflectable between the contact area and the contact region. The contact spring can be elastically deflected in the direction of the contact zone upon contact with the mating contact, wherein the contact spring presses against the contact zone. As a result, a stable current is ensured. In this case, the contact region can be configured in a particularly wear-resistant manner with respect to the friction caused by the contact spring, for example by being made of a noble metal such as silver or a noble metal alloy such as a silver alloy.

According to an exemplary configuration, the aluminum body has no form-fitting elements, in particular no elasticity, thereby preventing a contact force from being transmitted to or generated by the aluminum body. This prevents the aluminum body from influencing the contact normal force, whereby the stability of the electrical connection between the mating contact and the electrical contact can be improved again.

The connection portion may extend away from the socket in the longitudinal direction such that the connection portion is freely accessible for connection with the aluminum conductor. The connection portion may be provided with a crimping sleeve spanning an arc over the connection portion into which the aluminum conductor may be inserted. The crimp sleeve may then be compressed, whereby the connection between the aluminum conductor and the electrical contact may be strengthened again.

According to a particularly advantageous configuration, the aluminum conductor may be an aluminum cable, which may be connected to the connection portion in an integrally bonded and/or form-fitting manner.

The aluminum conductor may be welded to the connection portion, for example, by ultrasonic welding or friction welding. As a result, a stable integral bonding connection can be achieved. It has proved to be particularly advantageous if the aluminum conductor is welded to the connection portion by ultrasonic welding. By ultrasonic welding, the connection partners, i.e. the connection portions and the aluminum conductors, are heated to a lower extent than by other welding methods. As a result, damage to surrounding materials, such as insulation of aluminum conductors, can be prevented.

Since the connecting portion is made of aluminum or an aluminum alloy, a welded connection can be produced between the connecting portion and the aluminum conductor without difficulty.

Hereinafter, the present invention is described in more detail by using examples of exemplary embodiments with reference to the accompanying drawings. In the figures, elements that correspond to one another in design and/or function have the same reference numerals.

Combinations of features shown and described in various exemplary embodiments are for explanation purposes only. In light of the above statements, features of the exemplary embodiments may be omitted if the technical effect is not important in a particular application. Rather, in light of the above statements, another feature may be added in the exemplary embodiments if its technical effect is advantageous or necessary for a particular application.

Drawings

In the drawings:

figure 1 shows a schematic perspective view of an electrical contact according to the invention; and

fig. 2 shows a schematic cross-sectional view of a contact arrangement according to the invention.

Detailed Description

First, the design of the electrical contact 1 according to the invention will be explained with reference to fig. 1 and 2. Fig. 2 shows a contact arrangement 3 according to the invention with an aluminium conductor 6 connected to an electrical contact 1.

The electrical contact 1 comprises an aluminum body 2, which extends along a longitudinal axis L, is made of aluminum or an aluminum alloy, has a connection portion 4 for connecting an aluminum conductor 6, a contact region 10 arranged on a surface 8 of the aluminum body 2, and at least one contact spring 12, which is connected to the aluminum body 2, has a contact area 14 for contacting a mating contact 16.

In this exemplary configuration, the aluminum body 2 is formed of an aluminum/magnesium alloy AlMg 324. The aluminum body 2 is formed as a stamped and bent part 26. Fig. 1 schematically shows, by way of example, a stamping strip 28, only the electrical contact 1 being shown. A plurality of electrical contacts 1 arranged next to one another in a row can be arranged on the punching strip 28, as a result of which a simple and automatable mass production of at least the aluminum body 2 can be achieved.

The aluminum body 2 has a shape of a receptacle 20 at the free end 18, the receptacle 20 surrounding a receptacle cavity 22 for receiving the mating contact 16. The connecting portion 4 extends from the socket cavity 22 along the longitudinal axis L in a direction away from the free end 18. At the connection portion 4, the electrical contact 1 is connected to an aluminum conductor 6.

For this purpose, the aluminum conductor 6 is fixed to the surface 8 of the connecting section 6 by means of a welded connection 19, in particular an ultrasonic welded connection. Alternatively or additionally, the aluminum conductor 6 may also be connected to the connection portion 4 by a crimp connection. The aluminum conductor 6 may be, for example, an aluminum cable 21 made of aluminum or an aluminum alloy. The aluminium cable 21 preferably has up to 99.7% aluminium.

In a plane arranged transversely to the longitudinal axis L, the socket 20 has a substantially rectangular cross-section, wherein the socket 20 is open in the direction of the longitudinal axis L. In a longitudinal portion 30 extending along the longitudinal axis L, the two surfaces 8 are arranged opposite each other and laterally define the socket cavity 22, the contact region 10, in the height direction H. In this configuration, the contact zone 10 is made of a noble metal 32, preferably silver 34, and is applied to the surface 8 by rolling cladding.

In order to save costs for the relatively expensive material of the contact region 10, an intermediate layer 36 made of copper or a copper alloy is arranged in the height direction H between the contact region 10 and the surface 8.

Before the contact zone 10 is applied to the intermediate layer 36, the intermediate layer 36 can likewise be applied to the surface 8 by roll cladding. As an alternative to roll cladding, both the contact region 10 and the intermediate layer 36 may be applied by chemical vapor deposition, in particular by electron beam or galvanic deposition.

The intermediate layer 36 and the contact zone 10 may preferably be applied directly as a strip onto the stamping belt 28 before bending, which is particularly advantageous for industrial manufacture of a large number of stamped and bent parts 26.

By means of the intermediate layer 36, the application of the contact region 10 can be simplified, since the composition and the material thickness of the intermediate layer 36 can be optimized. Furthermore, the intermediate layer 36 may prevent the aluminum in the aluminum body 2 from creeping into the contact region 10. Furthermore, by shaping the contact region 10 from a noble metal, corrosion of the surface, which may lead to a reduction in conductivity, may be prevented.

The contact zones 10 are arranged flush with the surface 8 along the longitudinal axis L, so that when sliding along the longitudinal axis L no undesired wear and resulting increased wear occurs at the transition between the surface 8 and the contact zones 10.

The contact spring 12 extends away from the coupling region 38 in the direction of the longitudinal axis L. The coupling region 38 is shaped as a sleeve 40 which is placed on this free end 18 of the aluminum body 2 facing away from the connecting portion 4. The coupling region 38 and the aluminum body 2 may have a catch mechanism, for example a catch clip, which are complementary to each other and snap into place with a window or notch to prevent the coupling between the contact spring 12 and the aluminum body 2 from being released. In particular in vehicle applications, the electrical contact 1 is exposed to high vibration and/or impact stresses, which may result in the coupling being released.

The sleeve 40 may be coated with a corrosion resistant coating 45, for example made of a noble metal such as silver, at least on its outer surface 43 facing away from the aluminium body 2. In the example shown, however, it is advantageous if both the support surface 47 of the contact spring 12, by means of which the contact spring 12 rests on the contact region 10, and the contact region 14 are coated with a noble metal, in particular silver. The coating and the contact area 10 are preferably formed of the same material, whereby contact corrosion can be prevented.

At a respective side 41 of the sleeve 40 arranged in the height direction H, a pair of wave-like contact springs 12 extends in the direction of the connection portion 4 and is bent around the free end 18 and protrudes into the socket cavity 22. Here, the opposing contact springs 12 define a receptacle 42 in the height direction H, into which the mating contact 16 can be inserted in an insertion direction S extending substantially parallel to the longitudinal axis. The pair of contact springs 12 are arranged alongside one another in a transverse direction Q transverse to the height direction H and transverse to the longitudinal axis L, wherein they are offset relative to one another in the direction of the longitudinal axis L. In other words, the contact springs 12 protrude deeper into the socket cavity 22 along the longitudinal axis L than the contact springs 12 arranged side by side in the transverse direction.

The contact spring 12 is made of a material which is mechanically and thermally more resistant and stable than aluminum or an aluminum alloy, such as stainless steel or copper, in particular a copper alloy, and has an undulating shape with a first curvature 44 towards the opposite side 41 and a second curvature 46 away from the opposite side 41. The first curvature 44 defines the receptacle 42 in the height direction H and is provided with a contact region 14 for contacting the mating contact 16. The contact spring 12 rests with its second curvature 46 on the contact region 10.

When the mating contact 16 is inserted, an electrical current is conducted from the mating contact 16 through the contact spring 12 to the contact zone 10 and is absorbed by the contact zone. By the creep resistance of the contact zone 10, the wear due to creep is reduced. According to an exemplary configuration, the contact region 10 is formed of silver, thereby avoiding surface corrosion that may compromise the conductivity of the contact region 10. The current is then led from the contact region 10 via the aluminum body 2 to the aluminum conductor 6. The contact normal force for contacting the mating contact 16 is generated by the contact spring 12, whereby the aluminum body 2 does not generate a contact normal force for contacting the mating contact 16.

By inserting the mating contact 16, the contact spring 12 is elastically deflected between the contact region 14 and the contact zone 10 and is pressed against the contact zone 10. For this purpose, it is particularly advantageous if the contact region 10 is made of a mechanically strong material, for example a noble metal, whereby the contact region 10 can withstand the pressure of the contact spring 12 without yielding and without wear due to friction between the contact springs 12 on the contact region 10 as a result of relative movements.

With the electrical contact 1 according to the invention, a particularly simple connection between the aluminum conductor 6 and the contact 1 is possible without any additional treatment of the contact 1 prior to the connection. Since both components are made of substantially the same material, it is possible to connect the aluminum conductor 6 directly to the contact 1 without the risk of contact corrosion. In the case of electrical contacts with a high material thickness, great difficulties arise, in particular with copper contacts, when preparing the contacts for connection to aluminum conductors. Most importantly, electroplating copper contacts at high material thicknesses involves high costs. Since the contact 1 according to the invention has an aluminum body 2 with a connection portion 4 for connection to an aluminum conductor 6, these difficulties can be avoided even in the case of an electrical contact 1 with a high material thickness.

Furthermore, with the contact according to the invention, a cheaper and lighter alternative is created than the copper contacts known in the prior art, due to the lower material costs and the aluminum content compared to copper.

List of reference numerals

1 electric contact

2 aluminum body

3 contact device

4 connecting part

6 aluminum conductor

8 surface of

10 contact zone

12 contact spring

14 contact area

16 mating contact

18 free end

19 welded connection

20 socket

21 aluminum cable

22 socket cavity

24 AlMg3

26 stamping a bent part

28 punch band

30 longitudinal part

32 noble metal

34 silver

36 intermediate layer

38 coupling region

40 sleeve

41 opposite sides in the height direction

42 socket

43 outer surface

44 first curvature

45 corrosion resistant coating

46 second curvature

47 support surface

H height direction

L longitudinal axis

S direction of insertion

Q transverse direction