DE102022131114A1 - TOLERANCE COMPENSATION IN AN ELECTRICAL CONNECTION - Google Patents

Abstract

Tolerances in the shape and arrangement of a first conductor (1) and a second conductor (2) in an electrical connection (300) are compensated by establishing the electrically conductive connection (300) between the first conductor (1) and the second conductor (2) via elastic and electrically conductive contact elements (30). The contact elements (30) are provided on the first conductor (1) and form an area (35) in which the second conductor (2) is received. The contact elements (30) can be components of a tolerance compensation element (3) that is attached to the first conductor (1). Such a tolerance compensation element (3) comprises a base body (33) and a plurality of contact elements (30) attached to it. The base body (33) can enclose the area (35) for receiving the second conductor (2) in a ring shape, the contact elements (30) are directed towards the interior of the area (35).

Description

The invention relates to the compensation of tolerances in component geometry and component arrangement in an electrical connection, as well as a tolerance compensation element provided for this purpose.

In an electrical connection between two electrical conductors, the largest possible contact area between the two conductors is desirable, as this minimizes the resistance of the contact point. Of course, the size of the contact area is limited by the geometry of the conductors themselves; if the two conductors in the connection are butt-jointed at one end, the largest possible contact area is limited by the smaller of the two conductor cross-sections. The actual achievable contact area between two conductors is often considerably smaller. This is the result of, for example, roughness of the contact surfaces of the conductors, a lack of flatness of the contact surfaces of the conductors, or it results from the conductors meeting at an angle that is not coordinated with the angle of the contact surfaces, resulting in a wedge-shaped gap between the conductors. A combination of these causes usually occurs.

It is the object of the invention to provide a solution for compensating the tolerances resulting from the situation described. This is achieved on the one hand by a tolerance compensation element according to claim 1, and on the other hand by an electrical connection according to claim 6. The dependent claims each contain advantageous further developments.

The tolerance compensation element according to the invention comprises a base body made of electrically conductive material. A plurality of contact elements made of elastic, electrically conductive material are attached to this base body and are in an electrically conductive connection with the base body. The base body has a receptacle for a first conductor. The base body, and thus the tolerance compensation element, can be in an electrically conductive connection with a first conductor via this receptacle. The plurality of contact elements is arranged in a region of the tolerance compensation element that is intended to accommodate a second conductor. The arrangement of the plurality of contact elements is such that the second conductor, when it is accommodated in the region, is in an electrically conductive connection with at least a subset of the plurality of contact elements.

If a tolerance compensation element according to the invention is used in an electrical connection, the first conductor and the second conductor are in an electrically conductive connection via the tolerance compensation element. The elasticity of the contact elements means that roughness and lack of flatness of the contact surfaces of the conductors no longer play a role in the quality of the electrical connection, in particular in the resistance of the electrical connection. Likewise, the quality of the electrical connection is no longer influenced, or only influenced to a reduced extent, by the angular position of the conductors relative to one another.

In one embodiment, the receptacle for the first conductor is designed to fasten the base body to the first conductor. This ensures mechanical stability of the electrical connection. Without restricting the invention to this, the base body can be fastened to the first conductor, for example, by means of a screw connection; in this case, a thread can be formed on an inner surface of the base body, via which the base body can be screwed onto an end of the first conductor on which a corresponding thread is formed. Alternative, non-limiting examples would be fastening via a bayonet lock, pressing or simply plugging on with frictional fixing. Fastening by soldering or welding is also conceivable.

In one embodiment, the area for receiving the second conductor is enclosed in a ring shape by the base body and the contact elements are directed from the base body into the interior of the area.

In one embodiment, the contact elements are designed as leaf springs. In another embodiment, the plurality of contact elements forms a brush.

The electrical connection according to the invention comprises a first conductor and a second conductor. At one end of the first conductor, a plurality of electrically conductive contact elements are provided, which are in electrically conductive connection to the first conductor and which form a region in which one end of the second conductor is received such that the second conductor is in electrically conductive connection to at least a subset of the contact elements.

The elasticity of the contact elements means that roughness and lack of flatness of the contact surfaces of the conductors no longer play a role in the quality of the electrical connection. Likewise, the quality of the electrical connection, in particular the resistance of the electrical connection, is no longer influenced, or only influenced to a reduced extent, by the angle of the conductors relative to one another.

In one embodiment, the contact elements are designed as leaf springs. In another embodiment, the plurality of contact elements forms a brush.

In one embodiment, the inventive design of the electrical connection is achieved by attaching a tolerance compensation element as described above to the end of the first conductor.

In one embodiment, the first conductor and the second conductor are pressed against each other. This mechanically secures the electrical connection and ensures stable contact between the second conductor and the plurality of contact elements. The pressing against each other can be carried out, for example, by an elastic element, such as a compression spring.

• 1 zeigt schematisch eine elektrische Verbindung zwischen zwei Leitern in einer Idealsituation.
• 2 zeigt schematisch eine elektrische Verbindung zwischen zwei Leitern in einer realistischen Situation.
• 3 bis 6 zeigen schematisch Kontaktflächen von Leitern.
• 7 zeigt schematisch eine erfindungsgemäße elektrische Verbindung.
• 8 zeigt schematisch eine erfindungsgemäße elektrische Verbindung unter Verwendung eines erfindungsgemäßen Toleranzausgleichselements.
• 9 zeigt schematisch eine erfindungsgemäße elektrische Verbindung unter Verwendung eines erfindungsgemäßen Toleranzausgleichselements in Draufsicht.
• 10 zeigt schematisch eine erfindungsgemäße elektrische Verbindung unter Verwendung eines erfindungsgemäßen Toleranzausgleichselements.
• 11 zeigt schematisch eine erfindungsgemäße elektrische Verbindung unter Verwendung eines erfindungsgemäßen Toleranzausgleichselements.
• 12 zeigt ein erfindungsgemäßes Toleranzausgleichselement.
• 13 zeigt schematisch eine erfindungsgemäße elektrische Verbindung unter Verwendung eines erfindungsgemäßen Toleranzausgleichselements.

The invention and its advantages are explained in more detail below with reference to the accompanying drawings.

• 1 shows schematically an electrical connection between two conductors in an ideal situation.
• 2 shows schematically an electrical connection between two conductors in a realistic situation.
• 3 to 6 show schematic contact surfaces of conductors.
• 7 shows schematically an electrical connection according to the invention.
• 8th shows schematically an electrical connection according to the invention using a tolerance compensation element according to the invention.
• 9 shows schematically an electrical connection according to the invention using a tolerance compensation element according to the invention in plan view.
• 10 shows schematically an electrical connection according to the invention using a tolerance compensation element according to the invention.
• 11 shows schematically an electrical connection according to the invention using a tolerance compensation element according to the invention.
• 12 shows a tolerance compensation element according to the invention.
• 13 shows schematically an electrical connection according to the invention using a tolerance compensation element according to the invention.

The figures refer only to embodiments of the invention and are therefore not to be construed as a limitation of the invention.

1 shows schematically an electrical connection 100 between a first electrical conductor 1 and a second electrical conductor 2 at end faces 11, 21 of the conductors 1, 2. An ideal situation is shown in which the end faces 11, 21 of the conductors 1, 2 are flat and are in full-surface contact with one another, so that in the situation shown the contact surface 20 between the first conductor 1 and the second conductor 2 is congruent with the end face 21 of the second conductor 2 and has its maximum size for the given conductors.

2 shows schematically an electrical connection 100 between a first electrical conductor 1 and a second electrical conductor 2 at end surfaces 11, 21 of the conductors 1, 2. A realistic situation is shown. The second conductor 2 is tilted against the first conductor 1, the end surfaces 11, 21 of the conductors 1, 2 are not in full contact with each other. The contact surface 20 between the first conductor 1 and the second conductor 2 is significantly smaller than that in 1 The electrical resistance of this electrical connection is therefore greater than the resistance of the 1 electrical connection shown.

3 to 6 show various exemplary deviations of the end surface 11 of the conductor from the ideal shape using the example of the first conductor 1. The ideal shape is characterized by a flat end surface, which is indicated by a dashed line. In the 3 the end surface 11 deviates from the ideal shape over a large area. In the 4 There are wave-like deviations from the ideal shape. 5 illustrates the roughness of the end surface 11. 6 shows a combination of roughness and wave structure.

7 shows an electrical connection 300 according to the invention between a first electrical conductor 1 and a second electrical conductor 2. An electrical contact between the conductors 1, 2 is achieved here differently than in the 1 and 2 not via a contact surface between an end surface 11 of the first conductor 1 and an end surface 21 of the second conductor 2, but rather via elastic and electrically conductive contact elements 30, which in the embodiment shown are leaf springs 31. The contact elements 30 are attached to the first conductor 1 and form an area 35 in which one end of the second conductor 2 is received. A current then flows from the first conductor 1 into the contact elements 30 and from these into the second conductor 2.

8th shows an electrical connection 300 according to the invention between a first electrical conductor 1 and a second electrical conductor 2 using a tolerance compensation element 3. The tolerance compensation element 3 comprises a base body 33 and a plurality of elastic and electrically conductive contact elements 30, which in the embodiment shown form a brush 32. The brush 32 defines an area 35 in which one end of the second conductor 2 is received. The base body 33 is attached to one end of the first conductor 1, for example plugged or screwed on. A current then flows from the first conductor 1 into the base body 33, from there into the contact elements 30, and from these into the second conductor 2.

9 shows an electrical connection 300 according to the invention in plan view. Visible are the tolerance compensation element 3 with base body 33 and brush 32, as well as the second conductor 2. The first conductor is covered by the tolerance compensation element 3.

10 shows an electrical connection 300 according to the invention, in which a tolerance compensation element 3 is used. Elastic and electrically conductive contact elements 30 are attached to the base body 33 of the tolerance compensation element 3. The base body 33 is attached to a first conductor 1. The contact elements 30 define an area 35 in which one end of a second conductor 2 is received. The connection 300 is shown with ideal alignment of the conductors 1 and 2.

11 shows the inventive electrical connection 300 from 10 with realistic alignment of the conductors, that is, the first conductor 1 and the second conductor 2 are tilted against each other. Due to the elasticity of the contact elements 30, these can deform in order to adapt to the tilting of the second conductor 2, so that despite the non-ideal alignment of the first conductor 1 and the second conductor 2 to each other, there is good electrical contact between the second conductor 2 and the contact elements 30, so that ultimately the electrical resistance of the electrical connection 300 consists of 11 not significantly from the electrical resistance of the electrical connection 300 10 It can also be seen from the illustration that the contact elements 30 are also able to compensate for displacements of the second conductor 2 in a radial direction 71 and in an axial direction 72.

12 shows a tolerance compensation element 3 according to the invention. The base body 33 is made of a metal and has an internal thread 34 in order to screw the base body 33 onto one end of a first conductor. A brush 32 made of metallic bristles is attached to the base body 33 and forms the contact elements of the tolerance compensation element 3. A second conductor can be introduced into the tolerance compensation element 3 from the side of the base body 33 opposite the internal thread 34. The area enclosed by the internal thread 34 forms a receptacle 36 for the first conductor.

13 is an exemplary representation of an electrical connection 300 according to the invention in an installation environment 400. The electrical connection 300 is arranged in a housing 330 and uses a tolerance compensation element 3 according to the invention to establish an electrically conductive connection between a first conductor 1 and a second conductor 2. An electrically conductive connection between the second conductor 2 and an area outside the housing 330 is realized via a feed 25. A guide 27 is provided for the second conductor 2, in which a compression spring 26 is also guided. The compression spring 26 presses the second conductor 2 in the direction of the first conductor 1 and thus also in the direction of the tolerance compensation element 3. In this way, the electrical connection 300 is mechanically stabilized.

List of reference symbols

1

first director

2

second director

3

Tolerance compensation element

11

End face (first conductor)

20

Contact surface (first and second conductor)

21

End face (second conductor)

25

Feeding

26

Compression spring

27

guide

30

Contact element

31

Leaf spring

32

brush

33

Base body

34

inner thread

35

Area

36

Recording

71

radial direction

72

axial direction

100

electrical connection

300

electrical connection

330

Housing

400

Installation environment

Claims (10)

Tolerance compensation element (3) comprising a base body (33) made of electrically conductive material; a plurality of contact elements (30) made of elastic, electrically conductive material, which are attached to the base body (33) and are in electrically conductive connection with the base body (33); wherein the base body (33) has a receptacle (36) for a first conductor (1); and wherein the plurality of contact elements (30) are arranged in a region (35) of the tolerance compensation element (33) which is provided for receiving a second conductor (2), such that the second conductor (2) is in electrically conductive connection with at least a subset of the plurality of contact elements (30). Tolerance compensation element (3) according to Claim 1 , wherein the receptacle (36) for the first conductor (1) is designed to fasten the base body (33) to the first conductor (1). Tolerance compensation element (3) according to one of the preceding claims, wherein the region (35) for receiving the second conductor (2) is enclosed in a ring shape by the base body (33) and the contact elements (30) are directed from the base body (33) into the interior of the region (35). Tolerance compensation element (3) according to one of the Claims 1 until 3 , wherein the contact elements (30) are designed as leaf springs (31). Tolerance compensation element (3) according to one of the Claims 1 until 3 , wherein the plurality of contact elements (30) forms a brush (32). Electrical connection (300) comprising a first conductor (1) and a second conductor (2), wherein at one end of the first conductor (1) a plurality of electrically conductive contact elements (30) are provided, which are in electrically conductive connection to the first conductor (1) and which form a region (35) in which one end of the second conductor (2) is received such that the second conductor (2) is in electrically conductive connection to at least a subset of the contact elements (30). Electrical connection (300) to Claim 6 , wherein the contact elements (30) are designed as leaf springs (31). Electrical connection (300) to Claim 6 , wherein the plurality of contact elements (30) forms a brush (32). Electrical connection (300) to Claim 6 , wherein at the end of the first conductor a tolerance compensation element (3) according to one of the Claims 1 until 5 is attached. Electrical connection (300) according to one of the Claims 6 until 9 , wherein the first conductor (1) and the second conductor (2) are pressed against each other.

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