DE20218295U1 - Contact element for circuit boards which provides both mechanical and electrical connection - Google Patents

Abstract

The contact element has a pin part for pressing into a hole in the circuit board. This has at least four outer edges (7) running in the longitudinal direction. The edges are formed to be moveable, pairwise, towards each other against a return force. The return force may be provided by deforming of the pin part such as by bending the arms (4).

Description

Contact element for printed circuit boards

The invention is based on a contact element for circuit boards. To contact circuit boards, it is known to insert pins into plated-through holes. These pins usually have a rectangular cross-section so that the edges slide into the hole wall.

Also known are pins with a round cross-section, which may connect to the bore wall over a larger area.

The invention is based on the object of creating a contact element for printed circuit boards which enables a very secure connection both mechanically and electrically.

20 To solve this problem, the invention proposes a contact element with the features mentioned in claim 1. Further developments of the invention are the subject of subclaims.

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The ability of the edges to move towards each other allows large forces to be generated, which lead to a secure connection with the metallization of the hole wall, even if the dimensions of the hole have a certain tolerance. Even as the pin part is being pushed in, an increasing deepening of the grooves created by the edges can be achieved.

In a further development of the invention, it can be provided that the edges run at least partially parallel to one another. In particular, to facilitate insertion, it can be provided that the insertion end of the pin part initially has a transverse dimension that is significantly smaller than the hole into which the pin part is to be inserted. From there, the edges can diverge, at least in one dimension. In the area that is arranged within the hole when the contact element is inserted, the edges are then preferably parallel.

In a further development of the invention, it can be provided that the restoring force of the pin part increases more than before, in particular suddenly, after a certain deflection from the starting position. This allows an even better adaptation to the fixing of the contact element to be achieved.

One way in which the pin part of the contact element can be designed is that the pin part has two approximately parallel arms, on whose outer sides facing away from each other the edges are formed.

The pin part of the contact element can be designed such that it has a slightly curved outer side when viewed from the side, while it has parallel outer sides when viewed from another direction.

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According to the invention, the restoring force can be caused by a deformation of the pin part. This deformation can be, for example, a bending of the arms. Other possibilities for the construction of the pin part are also conceivable, whereby the deformation can be designed as desired by appropriate design of cross sections.

According to the invention, it can be provided that the arms are connected to one another in the region of the free end of the pin part. This connection can consist of a simple system, but also of a one-piece structure. The deformation then leads to a reduction in the distance between the arms in the region in which the arms themselves deform.

However, it is also possible and is proposed by the invention that the arms leave a gap in the area of the free end of the pin part in the initial position, i.e. in the undeformed state. In other words, the pin part is designed like a fork.

It can be provided that the free ends of the arms have contact surfaces facing each other, which then come into contact with each other in the event of a corresponding deformation and lead to a different type of deformation occurring in the event of a further deformation.

According to the invention, it can be provided that when the contact element is inserted, the connection point of the arms is arranged outside the bore of the circuit board, that is to say on the opposite side of the circuit board.

Further features, details and advantages of the invention emerge from the claims, the wording of which is incorporated by reference

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the content of the description, the following description of a preferred embodiment of the invention and the drawing. Herein show: S

Figure 1 is a side view of the part of a contact element intended for engagement in a contacted bore;

Figure 2 is a side view of the arrangement of Figure 1 for example

from the right in Figure 1;
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Figure 3 shows the arrangement in a deformed state, as it can occur in a bore;

Figure 4 shows a cross section through the arrangement of Figure 1.

Figure 1 shows the lower end of a contact element for use with printed circuit boards. The contact element can, for example, be bonded to a power transistor or provided with a connection in some other way. The contact element contains a pin part 1 which is inserted into a plated-through hole. In the side view shown in Figure 1, namely a broad side view, this pin part 1 has a curved outer side 2. In the area of its free end 3, the sides 2 diverge and then change into the slightly curved shape mentioned. In the example shown, the pin part contains two arms 4, the free ends of which leave a gap 5 between them. The mutually facing surfaces 6 of the ends of the arms 4 form contact surfaces, both of which are complementary, in the present example flat.

From the view in Figure 2, which is offset by 90°, it can be seen that the other sides of the arms 4 and the pin part 1 are flat.

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The contact element is punched out of a piece of sheet metal to create this shape.

Figure 4 shows a cross-section through the pin part approximately along line IV-IV in Figure 2. The pin part has four outer edges 7 which lie on a rectangle. These four outer edges 7 run, see Figure 1, approximately parallel to one another, at least in the area which is still within the hole in the circuit board when the pin part is inserted. The pin part is designed in such a way that the outer edges 7, see Figure 4 again, can be brought closer together against a restoring force. In the example shown, this restoring force is achieved by deforming the pin part. This deformation is distributed over different areas of the pin part. The type of deformation can best be seen by comparing Figures 1 and 3.

The contact element is inserted into a hole with its pin part 1 perpendicular to the plane of a circuit board. The initially diverging shape of the outer sides 2, see Figure 1, enables easy insertion, after which the pin part is then centered. As soon as the outer edges 7 come into contact with the hole wall, the arms 4 bend inwards. The deformation is primarily limited to the connection area of the arms 4 with the rest of the contact element. Depending on the size of the hole, the deformation takes place until the contact surfaces 6 of the two arms 4 come into contact with each other, as shown schematically in Figure 3. If further deformation is to occur, which of course depends on the size of the hole, the further deformation will occur because the arms deform in themselves, i.e. are pushed slightly inwards. This deformation occurs gradually as the pin part is pushed in. During insertion, the edges dig into the metallization of the hole wall. This digging in is supported by the increasing restoring force.

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With the illustrated shapes of the pin part it is possible to achieve cold welding between the metallization of the bore wall and the pin part 1.
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Claims (10)

1. Contact element for printed circuit boards, with 1. 1.1 a pin part ( 1 ) designed to be pressed into a hole in the printed circuit board, 2. 1.2 has at least four longitudinally extending outer edges ( 7 ) which 3. 1.3 are designed to be movable towards each other in pairs against a restoring force. 2. Contact element according to claim 1, wherein the edges ( 7 ) run at least partially parallel to one another. 3. Contact element according to claim 1 or 2, wherein the restoring force increases more strongly, in particular abruptly, from a certain deflection from the starting position. 4. Contact element according to one of the preceding claims, in which the pin part ( 1 ) has two approximately parallel arms ( 4 ), on whose mutually opposite outer sides ( 2 ) the edges ( 7 ) are formed. 5. Contact element according to one of the preceding claims, wherein the restoring force is caused by a deformation of the pin part ( 1 ). 6. Contact element according to claim 4 or 5, wherein the deformation includes a deflection of the arms ( 4 ). 7. Contact element according to one of claims 4 to 6, wherein the arms ( 4 ) are connected to one another in the region of the free end ( 3 ) of the pin part ( 1 ). 8. Contact element according to one of claims 4 to 6, wherein the arms ( 4 ) leave a gap ( 5 ) in the region of the free end ( 3 ) of the pin part ( 1 ) in the starting position. 9. Contact element according to one of claims 4 to 8, wherein the free ends of the arms ( 4 ) have mutually facing contact surfaces ( 6 ). 10. Contact element according to one of claims 4 to 9, in which the connection point or the contact point of the arms ( 4 ) is arranged outside the circuit board.