DE102016105116A1 - Grounding plate arrangement - Google Patents

Abstract

An electrical module comprising a printed circuit board (1) having at least one contact pad (2, 3) electrically connected to a contact section (11) of a grounding plate (10), the grounding plate (10) having a terminal section (12), with which it is electrically conductively connectable to a grounded conductor, characterized in that the contact portion (11) has two elastically displaced in the direction away fork arms (13, 14) with successive facing contact projections (15, 16) in a relaxed state the fork tines (13, 14) have a distance (a) from one another, which is smaller than the distance (b) of two facing away from each other wide sides of the printed circuit board (1), directly opposite contact fields (2, 3) and of a elastic tension of the fork tines (13, 14) in each case against a contact field (2, 3) are acted upon.

Description

Field of engineering

The invention relates to an electrical module with a printed circuit board, which has at least one contact field, which is in electrical conduction to a contact portion of a grounding plate, wherein the grounding plate has a connection portion with which it is electrically conductively connected to a grounded conductor.

The invention further relates to a grounding plate for use on a printed circuit board.

State of the art

Ground plates are on electronic modules, for example, for connecting actuators or sensors, as shown in the DE 197 16 137 C1 used to connect a contact pad of a printed circuit board to a grounded conductor. Such a grounding plate shows, for example, the DE 197 10 183 C1 ,

A grounding plate usually has a contact portion which is connected to the contact pad of the printed circuit board via a solder joint. A terminal portion of the grounding plate is electrically conductive, in particular materially connected to the contact portion of the grounding plate and can be attached, for example by means of a screw to a grounded conductor.

The DE 37 06 101 shows plug contacts in the form of fork-like leaf spring elements. The DE 36 25 476 shows two leg cutting contacts.

Summary of the invention

The invention has the object of providing an electrical module or a grounding plate useful further advantageous to simplify in particular the attachment of the grounding plate to the circuit board.

The object is achieved by the invention specified in the claims, wherein the dependent claims represent not only advantageous developments of the independent claims, but also independent solutions to the problem.

First and foremost, it is proposed that the contact section form two elastically displaceable forks in a direction away from each other. The forks have mutually facing contact projections. The forks are elastic and can be bent away from each other, wherein an elastic restoring force is formed, which acts on the two contact projections in the direction of each other. In the relaxed state, the clear width between the contact projections is smaller than the distance between two facing away from each other broad sides of the circuit board, directly opposite contact fields. The contact projections and the prongs are preferably formed by a cutout, which is designed as a narrow edge of a sheet metal strip open longitudinal slot, which is introduced into the broad side plane of the metal strip. The longitudinal slot forms a gap open to the edge, into which the edge of the circuit board can be inserted, so that the immediately adjacent to the edge of the contact pads lie between the contact projections. The contact projections are adjacent to the edge opening of the cutout. The edge of the opening of the recess forms bevels, which leak into the contact projections. These ramps occur when attaching the contact portion on the edge of the circuit board in touching contact with the edge of the circuit board, so that a postponement of the contact portion on the edge of the circuit board has a mutually-away movement of the forks result. As a result of the elasticity of the fork tines, a mechanical stress builds up within the fork tines, which acts on the contact projections against the contact fields. The cutout extends within the broad side plane of a sheet metal strip, so that the contact zones of the contact sections are formed by narrow side sections. The contact sections have a rounded contour line relative to the broad side plane, so that the contact sections can also be used as latching connection elements if the opposing contact fields have latching recesses or latching recesses into which the contact projections can engage. Preferably, the two contact fields are connected to each other with a bore. The wall of the hole is metallized, so that the two contact fields are electrically conductively connected to each other via the bore. The rounded, facing each other contact projections engage in the opposite mouths of the bore. For this purpose, it is advantageous if the contact projections of the different fork tines are directly opposite. In the assembled state, the plane of extent of the sheet metal section from which the forks are cut free, is perpendicular to the plane of extension of the circuit board. Unlike a leaf spring, the spring stiffness of the forks is influenced by their width. If one draws a center line through the open longitudinal slot extending between the two fork tines, then the two fork tines have a mirror-symmetrical shape to this center line. The in the broad side plane of the sheet, from which the forks are cut free, extending width of the Forks correspond approximately to the width of the free cut in an area between the contact portions and the closed end of the free cut.

Preferably, the contact portion has two pairs of forks which are spaced from each other. The forks pairs extend parallel to each other. The pair of forks are preferably formed by a curved to a U sheet metal strip portion. The two U-legs of the metal strip run parallel to each other, so that the two pairs of forks run in parallel planes to each other. Each of the two pairs of forks has a pair of contact fields associated with it on the printed circuit board, each contact field pair forming two contact fields which are also arranged facing away from one another and which are preferably interconnected with metallized bores. Each pair of forks has mutually facing contact projections that can enter detent and electrically conductive in the mouths of the holes. A U-web connecting the two U-legs, which forms a back of the grounding plate, may have a slot, so that two mutually parallel arms are formed, on which the two pairs of forks are formed to form a right-angled bend. The back can form a transition area, which is followed by a flag, which is provided with a contact zone, for example. A bore. The contact zone, in particular the flag, has means for positive connection of the grounding plate with a grounded conductor. The grounding plate is designed in particular as a stamped and bent part. It may have a Z-shape, wherein the transition region forms a Z-bar and the two pairs of forks a first Z-leg and the connecting portion a second Z-leg. In particular, it is provided that the transition region between contact section and connection section extends in a first plane which runs perpendicular to a plane in which the connection section lies. A third plane, which is perpendicular to the plane of the transition region and perpendicular to the plane of the connection section, forms the plane of extent in which the fork tines extend. Again, it is preferably provided that two pairs of forks extend in mutually parallel extension directions, which in turn extend perpendicular to the plane of extension of the circuit board. The material thickness of the sheet from which the forks are cut, is preferably less than one millimeter. The width with which a fork extends in the plane of extent of the sheet metal section is at least 5 times, preferably 10 times, greater than the material thickness. The length of the fork tine extending transversely to the width of the fork tine in the plane of extent of the sheet metal strip section is preferably at least twice, preferably at least four times, the width of the fork tine. All bending lines of the stamped and bent part extend in the plane of extent of the sheet metal. All punching structures also extend in the plane of the sheet. The contact projections are thus spaced apart within the plane of the sheet.

Brief description of the drawings

The invention will be explained with reference to the accompanying drawings. Show it:

1 in a perspective view of a printed circuit board, for example, an electronic module for connecting actuators or sensors,

2 a top view of the in 1 illustrated arrangement,

3 the section according to the line III-III in 2 .

4 increases the section according to the line IV-IV in 3 .

5 a first perspective view of a grounding plate 10 .

6 a second perspective view of the grounding plate 10 .

7 a rear view of the grounding plate,

8th a side view of the grounding plate, and

9 a plan view of the grounding plate.

Description of the embodiments

The in the figures with the reference number 1 designated circuit board carries not shown electrical or electronic components, for example. Plug elements and is arranged in a housing, not shown. In the housing is a grounded electrical conductor having, for example, an internal thread.

With the grounding plate 10 are contact fields 2 . 3 the circuit board 1 connected to the grounded conductor. For this purpose has the earthing plate 10 a contact section 11 in electrical connection with the contact pads 2 . 3 stands and a connection section 12 with which the grounding plate 10 connected to the grounded conductor.

The grounding plate 10 is made of a metal sheet. In a first processing step, a large sheet metal strip becomes a T-shaped one Body punched out, pointing away from each other T-leg with open to the narrow sides of the T-leg free cuts 17 is provided. At the free end of the bridge there is an opening 22 which is designed as a bore. In a subsequent bending step, the free ends of the T-bars are bent into a U so that they or the forks formed by them 13 . 14 extend in the same direction. From the T-bridge is a the bore 22 training banner 21 angled so that the flag 21 over a transition area 20 with the U-bridge of the contact section 11 connected is. The U-web can be up to the transition area extending slot 18 have, which is open to the edge of the metal strip.

The U-legs bent portions of the sheet metal strip each form a fork pair 13 . 14 out. The forks pairs 13 . 14 The two U-legs are the same design and have a folding symmetry with respect to a cross through the cutout 17 laid flat. This level corresponds to the plane of extent of a printed circuit board 1 for contacting contact fields 2 . 3 in the space between the fork legs 13 . 14 is pushed.

The free cut 17 is introduced into the wide side surface of the sheet metal portion and has a narrow edge of the contact portion 11 open mouth. At the mouth close obliquely to the direction of extension of the free cut 17 running bevels 23 on, which are formed by the narrow side edges of the sheet metal strip portion. The ramps 23 are approximately V-shaped to each other and go into contact protrusions 15 . 16 over, each in the region of the free ends of the mutually parallel forks 13 . 14 are arranged. They form mutually assigning rounded contact areas, which have a clear distance a from one another, which is greater than the material thickness of a circuit board 1 or the distance b of two on the broad side surfaces of the circuit board 1 arranged on opposite sides contact fields 2 . 3 ,

The free cut 17 continues with obliquely running towards each other edge edges in the direction of the U-leg. At the end of the free cut, the marginal edges merge into one another to form an approximately 180 ° rounding. The mutually pioneering edges of the forks 13 . 14 , which form the outer peripheral edges of the U-legs, extending in the direction of the free ends of the forks 13 . 14 towards each other, so that the on the extension plane of the fork tines 13 . 14 running width of the forks 13 . 14 towards the root of the forks 13 . 14 first tapered, then in the area of contact protrusions 15 . 16 to join again. In the area of the ramps 23 decreases the width of the forks 13 . 14 towards their free ends.

In the area between the contact projections 15 . 16 and the root of the forks 13 . 14 owns the free cut 17 a width that is greater than the material thickness of the circuit board 1 , leaving a marginal edge of the circuit board 1 free in the free cut 17 protrudes.

The two directly opposite contact fields 2 . 3 the circuit board are through a metallization 5 a hole 4 electrically connected to each other. The hole 4 has a diameter which is so on the contour of the contact projections 14 . 15 is agreed that the contact zones of the contact projections 15 . 16 on the edge 6 . 7 the bore 4 rests. A vertex portion of the contact projection 15 . 16 protrudes into the mouth of the hole 4 into it and thus fulfills a locking function. In the the 4 shown mounted state is the edge of the circuit board 1 from the end section of the free cut 17 spaced. Only the contact zones of the contact projections 15 . 16 lie in touching contact with the metallized edges 6 . 7 the bore 4 ,

When mounting the grounding plate 10 will the board 1 in the free section 17 pushed in. The edge of the board acts on it 1 the ramps 23 so that the forks are 13 . 14 turn away from each other. It is an elastic bend, which leads to a restoring force with which the contact projections 15 . 16 be acted upon each other. The forks 13 . 14 are bent so far that the clear distance of the contact projections 15 . 16 the material thickness b of the circuit board 1 equivalent. The associated deformation is in the 4 represented by the arrows p. Upon further insertion of the printed circuit board 1 in the free section 17 reach the contact projections 15 . 16 the hole and snap into the mouth of the hole 4 one. The diameter of the bore is preferably several times greater than the material thickness of the sheet from which the forks 13 . 14 are cut free. The rounded narrow edges of the contact projections 15 . 16 are spring-loaded at two points in diametrical opposite position on the edge of the hole 4 on, wherein the spring force is caused by an elastic bias of the fork tines, which extend as a flat body in an extension plane and are elastically deformed in this plane of extent.

The above explanations serve to explain the inventions as a whole, which further develop the state of the art independently, at least by the following feature combinations, namely:
An electrical module with a printed circuit board, characterized in that the contact portion has two elastically displaced in the direction away fork arms with successive contact projections, which have a distance from each other in a relaxed state of the forks, which is less than the distance between two arranged facing away from each other wide sides of the circuit board, immediately opposite contact fields and are acted upon by an elastic voltage of the forks each against a contact field.

A grounding plate for use on a printed circuit board, characterized in that the contact portion comprises two elastically displaceable in the direction away fork arms with successive contact projections for contacting with arranged on two facing broad sides of the circuit board, immediately opposite contact pads, against which contact fields Contact projections are acted upon by an elastic tension of the fork tines.

An electrical module or grounding plate, which are characterized in that the two contact pads are electrically conductively connected to a conductive wall of a bore.

An electrical module or grounding plate, characterized in that the contact projections engage in the opposite mouths of the bore and are acted upon by the force of the elastically biased forks against the edge of the bore.

An electrical module or grounding plate, characterized in that the contact portion of a flat metal strip and the fork tines are formed by the edge of an inserted into the metal strip Freischnitts and elastically deform when pushed onto a circuit board in the surface extension plane of the metal strip.

An electrical module or grounding plate, which is characterized in that the contact portion is formed by a bent to a U sheet metal strip whose mutually parallel U-legs each form a fork pair.

An electrical module or grounding plate, which is characterized in that the connecting portion is integrally connected to the contact portion.

An electrical module or grounding plate, which is characterized in that the connection section is integrally formed integrally with the U-web of the contact section.

An electrical module or earthing plate, which is characterized in that a web which holds the two pairs of forks at a distance has an incision which continues into a transition region, at which transition region a flag with a bore adjoins.

An electrical module or grounding plate, characterized in that the cutout from a to the narrow side of the fork plate forming sheet metal strip is an open longitudinal slot whose slot width is reduced immediately adjacent to the slot opening of the contact projections.

All disclosed features are essential to the invention (individually, but also in combination with one another). The disclosure of the associated / attached priority documents (copy of the prior application) is hereby also incorporated in full in the disclosure of the application, also for the purpose of including features of these documents in claims of the present application. The subclaims characterize with their features independent inventive developments of the prior art, in particular to make on the basis of these claims divisional applications.

LIST OF REFERENCE NUMBERS

1

 circuit board

2

 Contact field

3

 Contact field

4

 drilling

5

 metallization

6

 edge

7

 edge

8th

9

10

 earth plate

11

 Contact section

12

 connecting section

13

 forks

14

 forks

15

 contact projection

16

 contact projection

17

 Clear cut

18

 incision

19

 web

20

 Transition area

21

 Banner, flag

22

 drilling

23

 drainage slope

a

 distance

b

 material thickness

p

 arrow

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19716137 C1 [0003]
• DE 19710183 C1 [0003]
• DE 3706101 [0005]
• DE 3625476 [0005]

Claims (11)

Electrical module with a printed circuit board ( 1 ), which has at least one contact field ( 2 . 3 ) which is in electrical conduction connection to a contact section ( 11 ) of a grounding plate ( 10 ), wherein the grounding plate ( 10 ) a connection section ( 12 ), with which it is electrically conductively connectable to a grounded conductor, characterized in that the contact portion ( 11 ) two elastically in the direction away from each other displaceable forks ( 13 . 14 ) with successive contact projections ( 15 . 16 ), which in a relaxed state of the fork tines ( 13 . 14 ) have a distance (a) from one another, which is smaller than the distance (b) of two facing away from each broad side of the printed circuit board ( 1 ) arranged directly opposite contact fields ( 2 . 3 ) and that of an elastic tension of the fork tines ( 13 . 14 ) each against a contact field ( 2 . 3 ). Grounding plate ( 10 ) for use on a printed circuit board ( 1 ), with one with a contact field ( 2 . 3 ) of the printed circuit board ( 1 ) can be brought into electrically conductive contact section ( 11 ) and a connectable to a grounded conductor terminal section ( 12 ), characterized in that the contact section ( 11 ) two elastically in the direction away from each other displaceable forks ( 13 . 14 ) with successive contact projections ( 15 . 16 ) has for contacting on two facing away from each other wide sides of the circuit board ( 1 ) arranged directly opposite contact fields ( 2 . 3 ) against which contact fields ( 2 . 3 ) the contact projections ( 15 . 16 ) of an elastic tension of the fork tines ( 13 . 14 ). Electrical module according to claim 1 or grounding plate according to claim 2, characterized in that the two contact fields ( 2 . 3 ) with a conductive wall ( 5 ) of a bore ( 4 ) are electrically connected to each other. Electrical module or grounding plate according to one of the preceding claims, characterized in that the contact projections ( 15 . 16 ) in the opposite mouths of the bore ( 4 ) and by the force of the elastically preloaded forks ( 13 . 14 ) against the edge of the bore ( 4 ) are acted upon. Electrical module or grounding plate according to one of the preceding claims, characterized in that the contact section ( 11 ) of a flat metal strip and the forks ( 13 . 14 ) from the edge of a free-cutting introduced into the metal strip ( 17 ) are formed and deform elastically when pushed onto a circuit board in the surface extension plane of the metal strip. Electrical module or grounding plate according to one of the preceding claims, characterized in that the contact section ( 11 ) is formed by a bent to a U sheet metal strip whose mutually parallel U-legs each have a fork pair ( 13 . 14 ) train. Electrical module or grounding plate according to one of the preceding claims, characterized in that the connection section ( 12 ) of the same material with the contact section ( 11 ) connected is. Electrical module or grounding plate according to one of the preceding claims, characterized in that the connection section ( 12 ) the same material as the U-web of the contact section ( 11 ) is formed. Electrical module or earthing plate according to one of the preceding claims, characterized in that one of the two pairs of forks ( 13 . 14 ) at a distance holding web ( 19 ) an incision ( 18 ), which extends into a transitional area ( 20 ) to which transition area ( 20 ) a flag ( 21 ) with a bore ( 22 ). Electrical module or earthing plate according to one of the preceding claims, characterized in that the free cut ( 17 ) from one to the narrow side of the forks ( 13 . 14 ) forming sheet metal strip is an open longitudinal slot whose slot width is immediately adjacent to the slot opening of the contact projections ( 15 . 16 ) is reduced. Device characterized by one or more of the characterizing features of one of the preceding claims.

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