DE102015100647A1 - Printed circuit board with plug contact element - Google Patents

Abstract

A printed circuit board (1) is equipped with at least one surface-mounted sheet-metal part (2; 18; 22) as a plug-in contact element. A power distributor (31) has at least one printed circuit board (1) inserted in a housing (32). A method is used to produce a printed circuit board (1). The invention is particularly applicable to circuit boards of power distributors, in particular of on-board networks in motor vehicles.

Description

The invention relates to a circuit board which is equipped with at least one plug contact element. The invention also relates to a power distributor which has at least one printed circuit board inserted in a housing. The invention further relates to a method for producing a printed circuit board. The invention is particularly applicable to circuit boards of power distributors, in particular of on-board networks in motor vehicles.

A current distribution in electrical distribution boards is typically via busbars. If a switching element is represented electronically on a printed circuit board, then there is a challenge in contacting the printed circuit board with busbars (supplying and discharging) mechanically safely and with little effort.

For this purpose, it is known to attach contact blades in through-hole technology (also referred to as "through-hole technology", THT, or "pin-in-hole", PIH) to the circuit board, which can engage in corresponding sockets of a respective busbar. Also, the circuit board can be equipped with press-fit contacts.

In addition, it is known to provide holes in the printed circuit board with a metallization for a screw connection. However, placing the printed circuit board in a sandwich construction with bus bars in a screw connection is problematic because typically material used as the base material of the circuit board, such as FR4 or other epoxy-glass fiber composite material, is noticeably compressible and thus loses contact force with the bus bar over time goes. This can lead to a poor electrical connection, with high power loss to a fire. An attempt is made to reduce the compressibility by introducing metallized vias or "vias" (small holes). This is expensive and does not solve the problem in principle.

Furthermore, it is known to provide holes (with a diameter of about 10 mm) in the printed circuit board and to connect busbars to the circuit board via inserts inscribed in the holes. For this purpose, contact sheets are processed by a stamping process so that they form round elevations, which come as inserts in the holes come to rest. In the soldering process, e.g. MOSFETs soldered to the inserts and allow the busbar to the circuit board. The disadvantage here is that any force acting on the contact plates on their leverage acts directly on the solder joint. Furthermore, a large solder thickness for tolerance compensation with the board is necessary, which counteracts a resistance of the solder joint.

Press-fit threaded sleeves or press-in bolts are also used, but are very expensive. In addition, the board for the pressability must meet high tolerance requirements. Because of the leverage there is a risk that the printed circuit board is subjected to high forces.

A major disadvantage of all existing solutions is that the circuit board is accommodated with their power contacts in a housing of a power distribution, that it is bolted to molded in the housing busbars. For tolerance reasons (for example, to take into account a shrinkage of plastic), the contact surfaces are practically never at exactly the same height. If the circuit board is screwed, this results in a permanent mechanical stress in the circuit board, which will lead to a significantly higher probability of cracking of solder joints than with tolerance compensation.

It is the object of the present invention to overcome the disadvantages of the prior art, at least in part, and in particular to provide an improved possibility for connecting printed circuit boards with connectors, in particular high-current connectors, in particular busbars, in particular in power distributors of vehicles, in particular at low cost and / or. or with a low probability of mechanical failures.

This object is achieved according to the features of the independent claims. Preferred embodiments are in particular the dependent claims.

The object is achieved by a printed circuit board or board, which is equipped with at least one surface-mounted sheet metal part as a plug-in contact element.

Such a plug-in contact element or plug-in connection element can be produced with very low material and manufacturing costs. Also, the problems introduced by a screw connection do not occur.

The sheet metal part is therefore an SMD ("Surface Mounted Device") - component or SMT ("Surface Mounted Technology") - suitable. Due to the surface mountability or SMT capability, it can be equipped with other SMD components on the circuit board, e.g. in a common reflow process. Therefore, can be dispensed with a separate attachment process.

A plug contact can by pushing or attaching a plug contact counter element (eg a lamellar contact or a Blade sleeve) on the sheet metal part or - mechanically equivalent - are produced by inserting or inserting the sheet metal part in a plug contact counter element. The sheet-metal part thus has in particular a region (also referred to below as "fastening region" without limitation of generality) for attachment to the printed circuit board and at least one other region (hereinafter also referred to as "contact region" or "plug-in contact region" without restriction of generality) Enabling a plug contact or a plug connection with at least one plug contact counter element. The at least one contact region is exposed on both sides in order to enable plugging by the plug contact counter element, and thus also a two-sided contacting, in particular by a clamping fit.

The sheet metal part may be formed, for example, as a plug, in particular built-in plug, or as a part thereof. The plug contact counter element may in particular be designed as a matching socket or coupling or constitute a part thereof. The plug contact counter-element is hereinafter referred to without limitation of the generality as a "connection element". A connection element in this sense may have a housing or be housing-less.

Due to its SMT soldering to the printed circuit board, the sheet metal part is sufficiently resistant to deformation despite a possibly small sheet thickness and / or higher insertion forces. In addition, the sheet metal part can be soldered over a large area to the circuit board, which allows a high fastening security. Even if the sheet metal part should be torn, a current path is given to the circuit board.

The sheet metal part or its attachment region is connected via an SMT solder contact in particular with a line structure of the circuit board. The line structure may be e.g. have one or more contact pads or contact pads and / or one or more tracks.

The sheet metal part consists of a high electrical conductivity, in particular copper or a copper alloy. The sheet metal part may be silver plated, tinned or galvanized for corrosion protection and / or for a particularly secure mechanical and / or electrical contacting.

A sheet thickness or thickness may, for example, depending on a given current, 0.4 mm to 1.5 mm, in particular 0.6 mm to 1 mm, in particular 0.8 mm, amount.

It is an embodiment that at least one sheet metal part at least partially covers a marginal recess or notch in the (unpopulated) circuit board. As a result, the sheet metal part is contactable on both sides even if it does not have an e. G. rectangular basic shape of the circuit board protrudes.

Generally, at least one sheet metal part may not project beyond the printed circuit board or a basic shape of the printed circuit board, which allows a particularly high rigidity or a particularly low deformability of the sheet metal part. Alternatively or additionally, at least one sheet metal part protrude over the printed circuit board or a basic shape of the printed circuit board, which allows a particularly long contact area.

The recess may be a rectangular recess, which has the advantage that an associated connection element (for example a disk pack) can be pushed into the recess until it abuts against the printed circuit board. In particular, in this case, the sheet metal part may be rectangular, which enables a waste-free production (for example by punching a sheet metal part) of the sheet metal part.

The recess may be dimensioned so that it can accommodate an associated connection element clamped or loose. For example, a receptacle may be characterized by a width of the recess that is 0.5 mm wider than a width of a provided terminal element.

It is also an embodiment that at least one sheet metal part covering a peripheral recess or notch in the (bare) circuit board over the entire surface or completely. As a result, it is possible in a simple manner to reach a connection of the region covering the recess over an entire length of the edge of the recess. This in turn allows its particularly high deformation safety configuration. A particularly deformation-resistant development is achieved in that the sheet metal part also does not protrude beyond the recess.

It is also an embodiment that at least one sheet metal part has a tab-like contact region, in which therefore also the side edges are exposed. As a result, it is also possible to attach a connection element which laterally surrounds the tab-type plug contact area, e.g. a blade receptacle or a 2.8-wire contact.

The tab-like contact area may protrude into a peripheral recess in the circuit board. The sheet metal part then only partially covers the recess, in particular with gaps on both side edges of the recess. This gives us the advantage that the recess can serve as a guide and / or stop for a connection element.

The tab-like plug contact area may in particular serve as a drive pin for relays and lines in a cable set. The tab-like contact region may protrude beyond the recess or a side edge of a basic shape of the printed circuit board, so that a particularly long contact region can be provided.

It is still an embodiment that the edge-side recess has a metallization on the surface provided with the associated sheet metal part and the sheet metal part or its attachment area is soldered onto the metallization. This allows a particularly simple and large surface mounting. The metallization is therefore designed in particular as a solder pad or solder pad and may be e.g. go into a track. In particular, the metallization may be formed as an edge completely (i.e., gapless) bounding the recess. If the recess is rectangular, the edge may be e.g. Be U-shaped.

It is a further embodiment that at least one sheet metal part is a flat or planar sheet metal part. This can be particularly easily produced and may make it particularly easy to attach a matching connection element. Also, a flat sheet metal part by placement is particularly easy to handle and also can not overturn lying in the solder paste.

It is yet another embodiment that at least one sheet metal part has a bent up from the circuit board portion as a plug contact area. As a result, the sheet metal part, for example, be mounted over a circuit board, which has no recess there.

It is also an embodiment that at least one sheet metal part has at least one through-pin or "through-hole-pin" which is inserted into a hole in the circuit board. The at least one push-through pin allows avoiding a twist after a placement of the sheet metal part before a subsequent SMT soldering. Also, such a direct transfer of (often unique) insertion forces on the solder joint or solder joint is reduced or even completely avoided. The sheet metal part may e.g. have more than one push-through pin, e.g. two or three push-through pins. It is advantageous for a force absorption during insertion that at least one insertion pin is arranged with respect to a contact region of the sheet metal part in the insertion direction.

It is also an embodiment that at least one sheet metal part is surrounded by a housing. As a result, a mechanical load on the sheet metal part is reduced after plugging a connection element or even completely avoided. The remaining mechanical load when inserting the connecting element may be generated in particular by friction and acts in particular in the insertion direction. The housing may be attached to the circuit board or may be formed by a portion of a housing receiving the circuit board.

It is also an embodiment that the circuit board is equipped with at least one electronic component which is electrically connected to at least one of the sheet metal parts. This allows the circuit board to take on additional functions in addition to a power distribution. The at least one electronic component may be a circuit or a part of a circuit. The at least one electronic component is, in particular, an SMD component for simple and cost-effective production.

The at least one electronic component may in particular be configured to have a bus interface (eg for a LIN ("Local Interconnect Network") bus, a CAN ("Controller Area Network") bus or another field bus), a relay control, to provide electronic switching and protection and / or a diagnostic function.

The printed circuit board may in particular be a printed circuit board of a power distributor, in particular of vehicle electrical systems in motor vehicles.

The object is also achieved by a power distributor, having at least one printed circuit board inserted in a housing of the power distributor as described above. The power distributor can be designed analogously to the printed circuit board and gives the same advantages.

The printed circuit board may in particular have been plugged into the housing. The printed circuit board can thus be plugged in a development as a "plug-in" in the electrical power distribution. This allows a simple way an effective tolerance compensation.

It is a development that at least one connection element is attached to the housing, in particular integrated in the housing, for example, is cast in it. As a result, the housing can be handled particularly easily. In particular, by integrating into the housing, the at least one connection element can also be fastened in a particularly accurate position.

It is an embodiment that is cast in the housing at least one busbar with an associated connection element and the inserted circuit board via at least one Sheet metal part is in plug connection with at least one such connection element. This allows a particularly easy to implement and mechanically secure connection between the circuit board and the busbar. Especially if a connection element of a busbar is designed as a lamellar contact, a particularly effective tolerance compensation can be achieved.

It is still an embodiment that in addition at least one further (in particular differently shaped) connecting element is cast in the housing and the printed circuit board is connected via at least one other (in particular differently shaped) sheet metal part in plug connection with such a further connection element.

The object is further achieved by a method for producing a printed circuit board as described above, wherein the solder paste is applied to serving as a support area for at least one sheet metal part metallization of a circuit board, at least one sheet metal part is placed on a respective occupied with the solder paste support area and at least a sheet metal part is soldered in a reflow process. The method thus describes applying the at least one sheet metal part to the printed circuit board in an SMT process. In particular, a flat shape of the sheet metal part is very favorable for the SMT assembly, since such a sheet metal part is easily handled by a placement machine and lying in the solder paste lying can not tip over.

The method can be designed analogously to the printed circuit board and gives the same advantages.

The circuit board can be soldered in the reflow process, in particular with other SMD components such as electrical and / or electronic components.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following schematic description of an embodiment which will be described in detail in conjunction with the drawings.

1 shows a plan view of a sketch of a not yet equipped circuit board and a still separate sheet metal part;

2 shows a plan view of a sketch of the now equipped printed circuit board 1 ;

3 shows a sectional view in side view of the assembled circuit board 2 before connection to a busbar;

4 shows a sectional view in side view of the assembled circuit board 2 after connection to the busbar;

5 shows a sectional view in plan view connected to the busbar, populated printed circuit board in more detail;

6 shows a sectional side view of the connected to the busbar, populated circuit board in more detail view;

7 shows in plan view a sketch of another not yet equipped printed circuit board and another of them still separate sheet metal part and a section of the printed circuit board then populated;

8th shows in a view obliquely from the front of a power distributor;

9 shows in a view obliquely from behind the power distributor with the rear side open with a printed circuit board inserted into the housing;

10 shows in a view obliquely from the front the power distributor without housing; and

11 shows in a view obliquely from behind the power distribution without housing.

1 shows a plan view of a sketch of a not yet equipped circuit board 1 and one of these still separate sheet metal part 2 , The circuit board 1 has a plate-shaped base body 3 from eg FR4 with a rectangular basic form. On the flat side shown is a line structure 4 in the form of a metallization, of which two sections are drawn here. In both sections of the line structure 4 each leaves a trace 5 in a U-shaped area 6 over, as an edge of an associated rectangular recess or notch 7 the circuit board 1 is trained. The notch 7 has a width b.

The sheet metal part 2 is a flat, rectangular sheet metal part and may have been made for example by simply punching out of a metal sheet. The sheet metal part 2 may consist of copper or a copper alloy. It may be silver plated, tinned, galvanized or otherwise surface treated.

For fastening the sheet metal part 2 by means of a surface mount or SMT process on the circuit board 1 First, solder paste is applied to the U-shaped areas 6 applied and then a respective sheet metal part 2 on the solder paste-coated U-shaped areas 6 hung up. This can also be carried out with further SMD components, eg with at least one electrical and / or electronic SMD component 8th to 10 (please refer 2 ). The U-shaped areas 6 So serve as supporting areas of the line structure 4 for at least one sheet metal part 2 ,

The following are the sheet metal parts 2 and the other SMD components 8th to 10 soldered by means of a reflow process, for example by passing through a reflow oven. As a result, the sheet metal parts 2 firmly with the respective u-shaped area 6 the management structure 4 soldered, and the SMD components 8th to 10 with other parts or sections (not shown) of the line structure 4 ,

The SMD components 8th to 10 are about the governance structure 4 with at least one of the sheet metal parts 2 electrically connected. The SMD components 8th to 10 For example, they may be configured to provide a bus interface, a relay driver, an electronic switch and fuse, and / or a diagnostic function.

The sheet metal parts 2 cover the notches 7 completely and thus reach to the edge of the respective notch 7 or the rectangular basic shape of the now equipped printed circuit board 1 , The sheet metal parts 2 Thus, have a peripheral, U-shaped mounting portion, with the line structure 4 is soldered, and a the notch 7 overlapping, flat side on both sides free contact area. The sheet metal parts 2 can therefore serve as plug-in contact elements, as will be explained in more detail below. The sheet metal parts 2 may be surrounded by a housing (not shown), in particular plug housing.

3 shows a sectional view through a notch 7 in side view the assembled printed circuit board 1 (without the components 9 and 10 ) in front of a connection to a busbar 12 , The sheet metal parts 2 serve as plug contact elements for connection to a respective blade contact 11 a busbar 12 , The busbar 12 likes with one or more lamellar contacts 11 be provided.

The lamellar contacts 11 may be, for example, "dLAM DRÄXLMAIER lamellar contacts" of the company DRÄXLMAIER Group. Such lamellar contacts 11 provide a scalable contact system for high currents, low contact resistances and small installation spaces.

The lamellar contacts 11 can serve as connecting elements as such or in conjunction with an associated housing (then in particular as "connection sockets"). They can be designed in particular as laminated cores.

4 shows a sectional view in side view of the assembled circuit board 1 after plugging engagement with the lamellar contact 11 , This is the lamellar contact 11 in the notches 7 been introduced (or vice versa), so that the contact area of the sheet metal part 2 with its free edge ahead in the lamellar contact 11 is plugged in. Through the two arms of the lamellar contact 11 becomes the sheet metal part 2 held in a tight fit. For a smooth introduction of the lamellar contact 11 in an associated notch 7 is the width b of the notch 7 slightly wider than a width of the lamellar contact 11 , for example, about 0.5 mm wider.

By the three-sided attachment of the sheet metal part 2 over the entire length of the U-shaped (pad) area 6 is the notch 7 overlapping contact area of the sheet metal part 2 very firm and stiff (even if the sheet metal part 2 is comparatively thin), so that a plug connection can be performed safely. The sheet metal part 2 does not deform or does not deform significantly.

5 shows a sectional view in plan view one with two busbars 12 connected, populated printed circuit board 13 in more detailed view. The cut runs here parallel to the circuit board 13 on an outside of the now two lamellar contacts 11 , The components 8th to 10 are not shown.

The lamellar contacts 11 are of a front side in the plug-in direction open housing (hereinafter without limitation of the general public as a "socket housing" 14 surrounded). The socket housing 14 are in respective, sheet metal parts 18 (please refer 6 ) enclosing housings (hereinafter referred to as "plug housings" without limitation to the general public) 15 designated) inserted. The use of the housing 14 and 15 causes the inserted lamellar contacts 11 not against the sheet metal parts 18 can twist and therefore can not exert any leverage that a solder joint of the sheet metal parts 18 with the line structure 4 could solve. On the sheet metal parts 18 Thus, essentially acts only when inserting the lamellar contacts 11 applied force.

The socket housing 14 and / or the connector housing 15 can directly on the circuit board 13 or on the power rail 12 be attached. The socket housing 14 or the connector housing 15 Alternatively, for example, as a region (s) of a common housing for the whole circuit board 13 be educated.

In the circuit board 13 is also spaced from all three sides of the notches 7 (not shown) one small hole each 16 intended. In the holes 16 can be like a punch pin 17 (see also 6 ) shaped areas of a sheet metal part 18 be plugged in. You do not need to be soldered there. This will be a positive connection of the sheet metal part 18 with the circuit board 13 generates, which is a rotation of the sheet metal part 2 prevented in the surface mounting and / or a power input when inserting the lamellar contact 11 on the sheet metal part 2 causes. Such a sheet metal part 18 like, for example, like the sheet metal part 2 be configured, but to provide each of the push-through pins 17 a corresponding extension 19 have, the end-side bending area as a push-through pin 17 serves (see 6 ).

It may alternatively only one, two or more than three holes 16 per notch 7 and / or one, two or even more than three push-through pin 17 per sheet metal part 18 to be available.

6 shows the components 5 as a sectional view through a lamella contact 11 in side view. The sheet metal part 18 shows here one of the on the PCB 13 resting, but not necessarily soldered, extensions 19 , the end in the form of a push-through pin 17 is bent and through an associated hole 16 in the circuit board 13 is plugged in.

7 shows in plan view a sketch of another not yet equipped circuit board 21 and another of these still separate sheet metal part 22 , The sheet metal part 22 is at a notch 23 by means of a surface mounting technique, similar to the sheet metal part 2 at the notch 7 , However, the notch likes 23 have a different shape and / or size than the notch 7 , eg here a larger width.

The sheet metal part 22 has a U-shaped mounting area 24 put on the SMT-mounting on a the notch 23 At the edge surrounding, U-shaped (support) area 6b the management structure 4 is provided. The attachment area 24 has a base section 25 and two of these ends outgoing legs 26 on. From the base portion is centrally a tab-shaped plug contact area 27 which is longer than the thighs 26 , This results in two parallel columns 28 between the plug contact area 27 and a respective leg 26 ,

After the SMT soldering, as shown in the dashed section A, the sheet metal part 22 with its attachment area 24 so on the u-shaped support area 6b the management structure 4 attached that the tab-shaped contact area 27 in plan view in the notch 23 protrudes. He even sticks out over the notch 23 or on the rectangular basic shape of the circuit board 1 out.

8th shows in a view obliquely from the front of a power distributor 31 , The power distributor 31 has a plastic housing 32 on, whose open back with a lid 33 is covered. In the case 32 are multiple execution or reception areas 34 to 36 formed, in which a respective external power connector (not shown) can be used. So likes in the recording area 34 from the outside a bus connection and into the reception area 36 from the outside a high current line, in particular a busbar use. The reception areas 34 to 36 For this purpose, have respective electrical contacts that are connected to a connector 39 or to connection elements 40 and 41 belong (see 10 and 11 ).

The connection elements 40 and 41 are with the associated recording areas 35 to 36 positively sealed.

9 shows the power distributor 31 in a view obliquely from behind with missing cover 33 with one in the case 32 inserted circuit board 37 , The circuit board 37 is on guided tours 38 of the housing 32 in the case 32 been plugged in.

10 shows the power distributor 31 without housing 32 and without lid 33 in a view from diagonally behind. 11 shows the power distributor 31 without housing 32 and without lid 33 in a view from diagonally forward. The circuit board 37 is shown here without further SMD components and without line structure.

The circuit board 37 has three as plug contact elements serving sheet metal parts, namely two sheet metal parts 22 and a sheet metal part 2 , In addition, the connector 39 having a plurality of contact pins, by means of a PIH soldering with the circuit board 37 connected.

Furthermore, the three connection elements 40 and 41 shown in the housing 32 are cast and which the sheet metal elements 2 respectively. 32 contact by means of a plug connection.

The connection element 40 is designed as a busbar, on which a blade contact 11 is attached. The sheet metal part 2 is by an insertion movement of the circuit board 37 in the case 32 in the lamellar contact 11 been plugged in. The two connection elements 41 are designed as Aufsteckhülsen or Aufsteckkontakte. The tab-like contact areas 27 the sheet metal parts 22 are due to the insertion movement of the circuit board 37 in the case 32 in a respective connection element 41 been plugged in. The through the casting of the connection elements 40 and 41 reached exact position to the channels 38 of the housing 32 allows easy mating. In addition, due to the nature of the circuit board 37 as "plug-in card" allows a secure tolerance compensation of the contacts. Bending forces are applied to the sheet metal parts 2 and 22 practically not exercised.

The connection elements 40 and 41 protrude with their the sheet metal parts 2 respectively. 32 remote sections (eg the busbar 40 as such) through the housing 32 in the reception areas 36 respectively. 35 and represent their electrical contacts. The pins of the male element 39 protrude as electrical contacts directly into the receiving area 35 ,

Of course, the present invention is not limited to the embodiment shown.

Thus, at least one sheet metal part may have a portion bent up from the printed circuit board as a plug contact area.

Generally, "on", "an", etc. may be taken to mean a singular or a plurality, in particular in the sense of "at least one" or "one or more" etc., unless this is explicitly excluded, e.g. by the expression "exactly one", etc.

Also, a number may include exactly the specified number as well as a usual tolerance range, as long as this is not explicitly excluded.

LIST OF REFERENCE NUMBERS

1

circuit board

2

sheet metal part

3

base body

4

management structure

5

Track of the line structure

6

U-shaped contact area of the line structure

6b

U-shaped contact area of the line structure

7

notch

8th

SMD

9

SMD

10

SMD

11

laminated contact

12

conductor rail

13

circuit board

14

socket housing

15

plug housing

16

hole

17

By plug pin

18

sheet metal part

19

Extension of the sheet metal part

21

circuit board

22

sheet metal part

23

notch

24

fastening area

25

base section

26

leg

27

Plug contact area

28

gap

31

power distribution

32

casing

33

cover

34

Receptacle for connectors

35

Receiving area for slip-on sleeve

36

Pickup area for busbar

37

circuit board

38

guide

39

Connectors

40

slip-on

41

conductor rail

A

neckline

b

Width of the notch

Claims (13)

Printed circuit board ( 1 ; 13 ; 21 ; 37 ) with at least one surface-mounted sheet metal part ( 2 ; 18 ; 22 ) is fitted as a plug-in contact element. Printed circuit board ( 1 ; 13 ; 21 ; 37 ) according to claim 1, wherein at least one sheet metal part ( 2 ; 18 ) a peripheral recess ( 7 ; 23 ) in the printed circuit board ( 1 ; 37 ) completely covered. Printed circuit board ( 21 ; 37 ) according to one of the preceding claims, wherein at least one sheet metal part ( 22 ) a tab-like plug contact area ( 27 ), which in a peripheral recess ( 23 ) in the printed circuit board ( 21 ; 37 protrudes. Printed circuit board ( 1 ; 13 ; 21 ; 37 ) according to one of claims 2 or 3, wherein the edge-side recess ( 7 ; 23 ) at the with the associated sheet metal part ( 2 ; 18 ; 22 ) provided a metallization ( 4 ) and the sheet metal part ( 2 ; 18 ; 22 ) on the metallization ( 4 . 6 ; 4 . 25 ) is soldered. Printed circuit board ( 1 ; 13 ; 21 ; 37 ) according to one of claims 2 to 4, wherein at least one sheet metal part ( 2 ; 18 ; 22 ) is a flat sheet metal part.  Printed circuit board according to one of the preceding claims, wherein at least one sheet metal part has a bent-up from the printed circuit board portion as a plug contact region. Printed circuit board ( 13 ) according to one of the preceding claims, wherein at least one sheet metal part ( 18 ) at least one push-through pin ( 17 ), which is in a hole ( 16 ) in the printed circuit board ( 13 ) is inserted. Printed circuit board ( 13 ; 37 ) according to one of the preceding claims, wherein at least one sheet metal part ( 18 ; 2 . 22 ) of a housing ( 15 ; 32 ) is surrounded. Printed circuit board ( 1 ; 13 ; 21 ; 37 ) according to one of the preceding claims, wherein the printed circuit board ( 1 ; 13 ; 21 ; 37 ) with at least one electronic component ( 8th - 10 ) equipped with at least one of the sheet metal parts ( 2 ; 2 . 22 ) is electrically connected, wherein the at least one electronic component ( 8th - 10 ) is adapted to - a bus interface, - a relay control, - an electronic switching and protection and / or - to provide a diagnostic function. Power distributor ( 31 ), comprising at least one in a housing ( 32 ) inserted circuit board ( 1 ; 13 ; 21 ; 37 ) according to any one of the preceding claims. Power distributor ( 31 ) according to claim 10, wherein in the housing ( 32 ) at least one busbar ( 41 ) with an associated connection element ( 11 ) is poured and the inserted circuit board ( 37 ) via at least one sheet metal part ( 2 ) in plug connection with at least one such connection element ( 11 . 40 ) stands. Power distributor ( 31 ) according to claim 11, wherein in the housing ( 32 ) at least one further connection element ( 40 ) is poured and the inserted circuit board ( 37 ) over at least one other sheet metal part ( 22 ) in plug connection with at least one such further connection element ( 40 ) stands. Method for producing a printed circuit board ( 1 ; 13 ; 21 ; 37 ) according to one of Claims 1 to 9, in which solder paste is applied to a support area ( 6 ; 6b ) for at least one sheet metal part ( 2 ; 18 ; 22 ) serving metallization of the circuit board ( 1 ; 13 ; 21 ; 37 ) is applied, - at least one sheet metal part ( 2 ; 18 ; 22 ) on a respective with the solder paste occupied area ( 6 ; 6b ) and - the at least one sheet metal part ( 2 ; 18 ; 22 ) is soldered by means of a reflow process.

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