DE102012203297A1 - Printed circuit board device and a related electrical arrangement - Google Patents

Abstract

The invention is based on a printed circuit board device (2), comprising a printed circuit board (4) with an electrically insulating substrate (6) and at least one electrically conductive conductor track (8). The conductor track (8) is firmly connected to the substrate (6). The conductor track (8) extends along a longitudinal extension direction (L) of the substrate (6). A plug (10) with a plug housing (12) and an electrical contact element (14) arranged in the plug housing can be electrically conductively connected to the printed circuit board (4). According to the invention, a spring element (18, 20) is fixedly connected to the printed circuit board (4). When the plug (10) is connected to the printed circuit board (4), the spring element (18, 20) exerts a force (F1, F2) on the plug housing (12) substantially perpendicular to the printed circuit board (4) to generate the electric current Press contact element (14) on the conductor track (8).

Description

State of the art

In direct plug-in technology, direct plug-in connectors or connectors are contacted directly on the printed circuit board without additional pin headers. The plugs are usually attached to the edge-mounted contact pads on the circuit boards. The contact pads can be integrated on the PCB top side as well as on the underside of the PCB in the PCB layout. The contact pads are usually formed from the mechanically firmly connected to an electrically insulating substrate of the circuit board interconnects. The plug essentially consist of a plug housing and a contact element, wherein in the plugged state, the contact element is pressed by means of a spring force against the contact pad. The contact element is in this case usually resilient, so that the contact element for applying the spring force to the conductor track, respectively on the contact pad on which made of an insulating material, usually made of plastic, plug housing of the plug is supported.

However, it has been found that, under the influence of the spring force acting essentially perpendicularly on the contact pads, the plug housing made of plastic relaxes, thus becoming plastically deformed. Thus, over the life of a printed circuit board-plug combination, the spring force decrease such that a secure electrically conductive connection between the contact pad and the contact element is not guaranteed.

Summary of the invention

There may therefore be a need to ensure an electrical conductive connection of the plug-and-board combination over their calculated life.

The need can be satisfied by the subject matters of the independent claims. Advantageous embodiments will become apparent from the subject matters of the dependent claims.

According to a first exemplary embodiment of the invention, a printed circuit board device comprising a printed circuit board with an electrically insulating substrate and at least one electrically conductive conductor track is provided. The conductor track is firmly connected to the substrate. The conductor extends along a longitudinal direction of the substrate. A plug having a plug housing and an electrical contact element arranged in the plug housing can be electrically conductively connected to the printed circuit board. With the circuit board, a spring element is firmly connected. When the plug is connected to the printed circuit board, the spring element exerts a force on the plug housing substantially perpendicular to the printed circuit board in order to press the electrical contact element onto the printed conductor.

In such an embodiment, the contact element may be resilient or designed only as a rigid plate. In particular, when the contact element is resilient, the relaxation of the plug housing and thus decreasing the conductor track pressure force is compensated for by the fact that the spring element presses the plug housing and thus the contact element to the circuit board. By this spring element is thus ensured that the contact element is secured to the conductor over the calculated lifetime of the PCB-connector connection. In this case, the printed circuit board can be made of resin-impregnated glass fiber fabric in a quality of FR4 or higher. Also, the electrically non-conductive substrate may be made of ceramic. The conductor can also be formed as a stamped grid. The force acting perpendicular to the circuit board of the spring element does not necessarily have to be introduced into the circuit board. For example, the force introduced into the spring element can be supported on a carrier element, wherein the printed circuit board can be connected to the carrier element without supporting the carrier element. Thus, no forces are introduced into the circuit board, which are required to press the contact elements to the conductor tracks. Of course, the spring element can also be connected to the printed circuit board in such a way that the force acting on the spring element is conducted into the printed circuit board.

According to a further embodiment of the invention, the connector housing has a groove. When the plug is connected to the circuit board, a portion of the circuit board is covered by the groove.

Especially in this embodiment, the electrical contact element can be supported on the connector housing to be resiliently pressed against the conductor track. The spring element may be arranged with respect to the circuit board such that the contact elements are already connected to the conductor track before the spring element is in engagement with the connector housing. This can be avoided in an advantageous manner, damage to the surface of the contact elements and / or the conductor, which is often due to the high pressure force of the contact elements of the known direct connector, which already acts on the conductor track when sliding these contact elements. It may therefore be formed, for example, the contact element low spring to thereby a Perform pre-positioning of the connector housing when pushed onto the conductor, while the contact pressure for reliable electrical contacting of the contact elements is effected by the spring element.

According to a further embodiment of the invention, the spring element has at least in a partial area substantially a Z-shape with a first leg member, a second leg member and a first leg member and the second leg member with each other inseparably connecting first web element. The first leg member is connected to the circuit board. When the plug is connected to the circuit board, the second leg member exerts the force on the plug.

Here, the circuit board may be designed such that the forces acting on the circuit board in the longitudinal direction of the circuit board or perpendicular to the circuit board, are absorbed by the circuit board. However, the circuit board may also be designed such that only a force in the longitudinal direction of the circuit board is received. For example, the spring element may in this case be arranged on a first side of the printed circuit board, whereas the force acting through the plug on the spring element perpendicular to the longitudinal direction of the printed circuit board force can be introduced into a receiving element, wherein the receiving element on one of the first side of the circuit board opposite second side of Printed circuit board can be arranged. Here, the circuit board may be fixed to the receiving element such that no forces must be absorbed by the spring element through the circuit board. Thus, the circuit board can be free from the forces generated by the spring element.

According to a further embodiment of the invention, the second leg member is formed substantially S-shaped with a first bay and a second bay. The first bay is firmly connected to the web element. When the plug is connected to the circuit board, the second bay exerts the force on the plug.

By the S-shaped configuration of the second leg member, the force is applied linearly to the connector housing. Characterized in that the second leg member is connected by means of a first bay to the web element, the force is entered by the second leg member in the web element arcuate. As a result, high stresses are avoided within the material, as they could otherwise occur if the transition of the rod element in the second leg member would be sharp-edged.

According to a further exemplary embodiment of the invention, the second leg element has at least one cut, so that the second leg element has at least two independent resilient spring lamellae.

By a division of the second leg member in at least two resilient spring blades manufacturing tolerances of both the spring element and the connector housing can be compensated and thus an uneven force distribution over the connector housing can be avoided.

According to a further embodiment of the invention, the circuit board device further comprises a second spring element. The first spring element and the second spring element are firmly connected to one another such that when the plug is connected to the printed circuit board, the second spring element exerts a second force on the plug substantially perpendicular to the printed circuit board. The second spring element is configured such that the first force and the second force are substantially equal.

In this proposed embodiment, neither the first force nor the second force are conducted into the circuit board. By the first and the second spring element, the plug housing is encompassed and pressed the contact elements to the respective conductor tracks. In this case, the plug housing can be designed reversibly elastically deformable, so that the plug housing is deformed by the two counteracting forces such that the electrical contact element are pressed by the two Federlemente to the conductor. In particular, when the conductor tracks are arranged both on a first side of the electrically insulating substrate and a second side of the substrate opposite the first side, it is achieved by such an arrangement that both the first side facing contact elements and those facing the second side Contact elements of the connector are pressed against the conductor tracks. Here, the first spring element and the second spring element may be connected to one another by soldering, screwing, riveting, welding or clinching.

According to a further embodiment of the invention, the first spring element and the second spring element are substantially equal to each other when the plug housing is configured with respect to a mirror formed in the plug housing mirror image. The first spring element and the second spring element are rigidly connected to one another with respect to the printed circuit board.

Thus, the first spring element and the second spring element in a tool be made. For a very inexpensive production of the spring elements is possible. Through the groove, when the plug is connected to the circuit board, a portion of the circuit board comprises. Due to the rigid connection, both spring elements can exert a force on the plug housing.

According to a further embodiment of the invention, the second spring element is formed substantially L-shaped with a third leg member and a non-detachably connected to the third leg member second web member. The second web element and the first web element are non-releasably rigidly connected to each other.

The first force is introduced via the second leg element into the first web element and the second force via the third leg element into the second web element. In particular, the two web elements are rigidly connected to each other in such a way that the forces introduced into the web elements over the entire service life of the printed circuit board / plug combination can not damage this connection.

According to a further embodiment of the invention, the first spring element and the second spring element made of metal or a metal alloy.

In particular, metals or metal alloys which have resilient properties, such as, for example, cold-rolled, as a rule, stainless steel sheets, are suitable for this purpose. Furthermore, metal or its alloys has no relaxation behavior, as is known from plastics. Thus, the spring made of metal spring elements can ensure over the entire life of the PCB-plug combination that the contact elements are pressed electrically conductive to the tracks.

According to a further embodiment of the invention, the first spring element or the second spring element or a combination of the first spring element and the second spring element is in one piece.

The one-piece design eliminates further steps for the preparation of the individual spring elements. Thus, it is possible that only with the use of a tool first spring elements or second spring elements or a combination of the first spring element and the second spring element can be manufactured.

According to a further embodiment of the invention, an electrical arrangement is provided with a printed circuit board device and a plug as described above. The plug is electrically conductively connected to the circuit board. At least one component of the group of first spring element and second spring element exerts a force on the plug.

It is noted that thoughts on the invention are described herein in the context of both a printed circuit board device and an electrical device. It will be clear to a person skilled in the art that the individual features described can be combined with one another in various ways so as to arrive at other embodiments of the invention.

Brief description of the drawings

Embodiments of the invention will be described below with reference to the accompanying drawings. The figures are only schematic and not to scale.

1 shows a printed circuit board device with a circuit board and a first spring element and a second spring element and a plug ready for sliding onto the circuit board in a longitudinal section;

2 shows the off 1 known printed circuit board device with a pushed plug in a longitudinal section;

3 shows the off 1 known circuit board device without plug in a 3D exploded view;

4 shows the off 3 known printed circuit board device in the assembled state in a 3D view;

5 shows a further printed circuit board device with an integrally formed combination of the first spring element and the second spring element in a 3D exploded view; and

6 shows the off 5 known printed circuit board device in the assembled state in a 3D view.

Detailed description of exemplary embodiments

1 shows a printed circuit board device 2 with a circuit board 4 consisting of an electrically insulating substrate 6 and one with the substrate 6 mechanically connected trace 8th consists. In this case, the conductor extends 8th along a longitudinal direction L of the substrate 6 , Furthermore, in 1 a plug 10 with a connector housing 12 and two facing contact elements 14 recognizable. The two contact elements 14 partially protrude into one in the connector housing 12 trained groove 16 , The groove 16 is designed to be a subarea 24 the circuit board 4 to pick up when the plug 10 with the circuit board 4 connected is. In the subarea 24 the circuit board 4 are the tracks 8th by means of the contact elements 14 electrically conductive contactable. Furthermore, on the circuit board 4 a first spring element 18 and a second spring element 20 with respect to the circuit board 4 arranged in mirror image. In the direction of an arrow 22 can the plug 10 in the longitudinal direction L of the substrate 6 , respectively the PCB 4 , on the circuit board 4 be deferred.

2 shows the off 1 known printed circuit board device 2 with pushed plug 10 , Here practice the first spring element 18 a first force F1 and the second spring element 20 a second force F2 on the plug 10 , respectively the plug housing 12 , out. These two forces F1, F2 become the contact elements 14 to the tracks 8th pressed. In the present embodiment, the contact elements 14 in turn resiliently configured, so that by the two forces F1, F2, the contact pressure of the contact elements 14 to the tracks 8th is increased. In particular, when the spring force of the contact elements 14 due to relaxation of the plastic-made plug housing 12 decreases, passing through the two spring elements 18 . 20 on the connector housing 12 exerted forces F1, F2 off that the contact elements 14 over the entire life of the circuit board 4 - plug 10 - Combination with the tracks 8th stay connected electrically conductive. Furthermore, it can be seen that the subarea 24 the circuit board 4 from the groove 16 of the connector housing 12 is included.

3 shows the off 1 known circuit board assembly without the plug in a 3D exploded view. Clearly visible are those in the subarea 24 the circuit board 2 arranged conductor tracks 8th which may be formed as contact pads. These tracks 8th are usually electrically connected to electrical components not shown here. Both the first spring element 18 as well as the second spring element 20 each have a Z-shape 26 with one of the circuit board 4 facing first leg member 28 and one of the circuit board 4 spaced second leg member 30 wherein the first leg member 28 and the second leg member 30 by means of a first stake element 32 are inextricably linked. The second leg element 30 is designed to plug in 10 , as in 1 shown to exert a force F1, F2. The second leg element 30 has an S-shape 34 with a first bay 36 and a second bay 38 , Here is the second bay 38 designed to go on, but not outlined here 1 known connector housing 12 to press. By means of the second bay 38 is the second leg element 30 to the first web element 32 inextricably linked. Both the first spring element 18 as well as the second spring element 20 are each made in one piece from a cold-rolled sheet of stainless steel. Through the first bay 36 the force F1, F2 becomes arcuate in the first web element 32 initiated, so that at the transition of the first Stegelements 32 to the second leg member 30 no high stresses occur within the material. Furthermore, the second leg element has 30 cuts 40 , which are up to the first bay 36 extend.

Through these cuts 40 that better in 4 are visible, is the second leg member 30 in springy spring blades 42 divided. Through these resilient spring blades 42 is over the entire length of the connector housing 10 ensures a uniform force distribution of the forces F1, F2. By the resilient spring blades 42 can manufacturing tolerances, especially the plug 10 to be compensated. The first leg element 28 of the first spring element 18 and the first leg member 28 of the second spring element 20 are in the present design example by means of clinching, also called toxins, inextricably rigid connected to each other, wherein the circuit board 4 between the two first leg elements 28 in the longitudinal direction L of the circuit board 4 extends. When the plug 10 on the circuit board 4 is pushed, the forces F1, F2 are based on the two first web elements 32 over the two first leg elements 28 from. Due to the fact that the two first leg elements 28 are rigidly connected to each other, which are perpendicular to the circuit board 4 acting forces F1, F2 not in the circuit board 4 directed. Thus, the circuit board takes 4 only forces that occur along the longitudinal direction L. These are usually the forces that are needed to plug in 10 in its predetermined position on the circuit board 4 postpone. Incidentally, the first spring element 18 and the second spring element 20 same, so that they can be made in a common tool. Also, the first spring element 18 and the second spring element 20 with respect to the circuit board 4 arranged in mirror image to each other.

5 shows a further embodiment of the circuit board assembly 2 , Here, the first leg member 28 of the first spring element 18 opposite to the representations in the 3 and 4 greatly reduced and serves only to fix the firmly connected spring elements 18 . 20 on the circuit board 4 , The second spring element 20 is essentially in an L-shape 44 configured with a third leg member 46 and one with the third leg member 46 undetachably connected second web element 48 , The first web element 32 of the first spring element 18 and the second web element 48 of the second spring element 20 are rigidly connected to each other. The two bridge elements 32 . 48 have a common slot in the middle 52 who is at a first end 56 and at one the first end 56 opposite second end 58 each by a bridge 54 is available.

How better in 6 is apparent, is the slot 52 designed such that the subarea 24 the circuit board 4 through the slot 52 can be threaded. This is done along the arrow 62 , Furthermore, the circuit board has 4 adjacent to the subarea 24 one recess each 60 into which the two bridges 54 can be introduced.

If now the off 1 known plug 10 on the circuit board 4 are pushed on the plug 10 acting forces F1, F2 exclusively in the web elements 32 . 48 initiated, so that none of the forces F1, F2 in the circuit board 4 is directed.

By the proposed printed circuit board device 2 become perpendicular to the longitudinal direction L of the circuit board 4 in conjunction with the plug 10 acting forces F1, F2 within the interconnected spring elements 18 . 20 taken, so that can be dispensed with an additional component for receiving the forces F1, F2. Since the joining force along the longitudinal direction L of the circuit board 4 at a touch of the spring elements 18 . 20 with the plug 10 can increase, a powerless prefixing of the plug 10 on the circuit board 4 occur. Of course, the spring elements 18 . 20 be configured continuously instead of the comb-like configuration.

Claims (10)

Printed circuit board device comprising a printed circuit board ( 4 ) with an electrically insulating substrate ( 6 ) and at least one electrically conductive track ( 8th ), wherein the conductor track ( 8th ) with the substrate ( 6 ), whereby the conductor track ( 8th ) along a longitudinal direction (L) of the substrate (FIG. 6 ), wherein a plug ( 10 ) with a connector housing ( 12 ) and one in the connector housing ( 12 ) arranged electrical contact element ( 14 ) with the printed circuit board ( 4 ) is electrically conductively connectable, characterized in that with the circuit board ( 4 ) a spring element ( 18 . 20 ), whereby when the plug ( 10 ) with the printed circuit board ( 4 ), the spring element ( 18 . 20 ) on the connector housing ( 12 ) substantially perpendicular to the printed circuit board ( 4 ) exerts a force (F1, F2) to move the electrical contact element ( 14 ) on the conductor track ( 8th ). Printed circuit board device according to claim 1, characterized in that the spring element ( 18 . 20 ) at least in a partial area substantially a Z-shape ( 26 ) with a first leg element ( 28 ), a second leg member ( 30 ) and a first leg member ( 28 ) and the second leg element ( 30 ) inseparably connected to each other first web element ( 32 ), wherein the first leg element ( 28 ) with the printed circuit board ( 4 ), wherein when the plug ( 10 ) with the printed circuit board ( 4 ), the second leg element ( 30 ) on the plug ( 10 ) exerts the force (F1, F2). Printed circuit board device according to claim 1 or 2, characterized in that the second leg element ( 30 ) is substantially S-shaped with a first bay ( 36 ) and a second bay ( 38 ), wherein the first bay ( 36 ) with the web element ( 32 . 48 ), whereby when the plug ( 10 ) with the printed circuit board ( 4 ), the second bay ( 38 ) on the plug ( 10 ) exerts the force (F1, F2). Printed circuit board device according to one of the preceding claims, characterized in that the second leg element ( 30 ) at least one incision ( 40 ), so that the second leg element ( 30 ) At least two mutually independent resilient spring blades ( 42 ) having. Printed circuit board device according to one of the preceding claims, characterized in that the printed circuit board device ( 2 ) further comprises a second spring element ( 20 ), wherein the first Spring element ( 18 ) and the second spring element ( 20 ) are firmly connected to each other such that when the plug ( 10 ) with the printed circuit board ( 4 ), the second spring element ( 18 ) on the plug ( 10 ) substantially perpendicular to the printed circuit board ( 4 ) exerts a second force (F2), wherein the second spring element ( 20 ) is configured such that the first force (F1) and the second force (F2) are substantially equal, with neither the first force (F1) nor the second force (F2) in the circuit board ( 4 ). Printed circuit board device according to claim 5, characterized in that when the plug housing ( 12 ) with respect to one in the connector housing ( 12 ) formed groove ( 16 ) is designed mirror-inverted, the first spring element ( 18 ) and the second spring element ( 20 ) are substantially equal to each other, wherein the first spring element ( 18 ) and the second spring element ( 20 ) in mirror image with respect to the printed circuit board ( 4 ) are rigidly connected to each other. Printed circuit board device according to claim 5 or 6, characterized in that the second spring element ( 20 ) substantially L-shaped with the second leg member ( 30 ) and one with the second leg element ( 30 ) undetachably connected second web element ( 48 ), wherein the second web element ( 48 ) and the first web element ( 32 ) undetachably rigidly connected to each other. Printed circuit board device according to one of the claims, characterized in that the first spring element ( 18 ) and the second spring element ( 20 ) are made of metal or a metal alloy. Printed circuit board device according to one of the claims, characterized in that the first spring element ( 18 ) or the second spring element ( 20 ) or a combination of first spring element ( 18 ) and second spring element ( 20 ) is integral. Electrical arrangement with a printed circuit board device ( 2 ) according to one of claims 1 to 9 and a plug, characterized in that the plug ( 10 ) with the printed circuit board ( 4 ) is electrically conductively connected, wherein at least one component from the group of first spring element ( 18 ) and second spring element ( 20 ) on the plug ( 4 ) exerts a force (F1, F2).

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