DE102015220432B4 - Secured insulation displacement connector and printed circuit board equipped with it - Google Patents

Abstract

Insulation displacement connector (1) for bringing an electrical line into contact with a printed circuit board (2)
- An insulation displacement contact (3) which has at least one contact foot (5) for electrically contacting the printed circuit board (2) and a insulation displacement connector (4) pointing away from it for electrically contacting the electrical line, and
- An electrically insulating housing (6), in which the insulation displacement contact (3) is held, the housing (6) having a fastening flange (10) for non-positive and / or positive fastening to the printed circuit board (2) by a fastening means, characterized that the fastening flange (10) has at least one joining aid element (21, 22) for pushing through with the printed circuit board (2).

Description

Technical field

The present invention relates to an insulation displacement connector for electrically contacting an electrical line with a printed circuit board. The invention further relates to a printed circuit board with such an insulation displacement connector.

State of the art

Insulation displacement contacts for contacting an electrical line with a printed circuit board are already known from the prior art. For example, the DE 10 2011 112 821 A1 for the field of vehicle technology, a possibility to attach insulation displacement contacts on a printed circuit board and to use them to make contact between an electrical line and the printed circuit board. The insulation displacement contacts are attached by soldering connections between the insulation displacement contacts and the printed circuit board. This means that the insulation displacement contacts contact the printed circuit board directly via the soldered connection and are also fastened to the printed circuit board via this contact point. The electrical line is then contacted by pressing the line into the insulation displacement contacts, as a result of which insulation of the line penetrates as far as the electrical conductor and the line is clamped for fastening in the insulation displacement contact.

In practice, however, it has been shown that simple, soldered insulation displacement connections between an electrical line and a printed circuit board can only partially meet the mechanical requirements in a vehicle under extreme conditions. For example, it has been shown that these insulation displacement connections can fail in terms of vibration resistance and durability in a vibration test during the development phase, in which the insulation displacement connections are exposed to vibrations of different frequencies and amplitudes. On the one hand, depending on the mechanical load, the soldered connection between the insulation displacement contact and the printed circuit board or the clamping connection between the electrical line and the insulation displacement contact can become loose. Therefore, these insulation displacement connections are only of limited use, i.e. for some applications, for use in vehicle technology.

US 6 050 845 A discloses an electrical connector for connecting an electrical lead to a circuit board. A correspondingly shaped housing is connected to the circuit board. The housing has a movable part which, after an insulated cable has been inserted, is movable in the direction of the printed circuit board in order to establish an electrical connection between the cable and the printed circuit board.

DE 10 2006 002 323 A1 describes a connection contact element for connecting an electrical conductor to a printed circuit board with a section that can be connected to the circuit board - designed as an SMD soldering region - and a section that can be connected to the electrical conductor - shaped as a selective soldering region.

The DE 10 2013 012 251 A1 discloses a terminal comprising an insulating housing with an elongated opening accessible from above for inserting the electrical conductor and with at least one insulation displacement connector which is arranged laterally on the housing and can be moved from the side and essentially perpendicular to the elongated opening and thereby the electrical conductor contacted by insulation displacement and fixed in the housing.

Description of the invention

It is therefore an object of the invention to provide a particularly robust possibility for insulation displacement connection of an electrical line to a printed circuit board using means that are structurally as simple as possible.

The object is solved by the subject matter of the independent claims. Advantageous developments of the invention are specified in the dependent claims, the description and the accompanying figures.

An insulation displacement connector according to the invention for electrically contacting an electrical line with a printed circuit board has an insulation displacement contact which has at least one contact foot for electrically contacting the printed circuit board and a cutting terminal pointing away from it for electrically contacting the electrical line. In addition, the insulation displacement connector has an electrically insulating housing in which the insulation displacement contact is held firmly. According to the invention, the housing additionally has a fastening flange for non-positive and / or positive fastening to the printed circuit board by means of a fastening means.

The insulation displacement connector according to the invention is thus fastened to the printed circuit board by means of two different fastening mechanisms, namely, for example, by a soldered connection between the insulation displacement contact and the printed circuit board and - additionally - by the force-fitting and / or positive fastening of the housing via its fastening flange on the printed circuit board. This makes the insulation displacement connector particularly vibration-proof and permanently attached to the circuit board. The electrical line to be brought into electrical contact with the printed circuit board is made by means of insulation displacement technology (SKT for short), that is to say directly and without cost-intensive and production-technically complex interposition of a plug connection with a plug connector to be attached to the line. The contact-free contacting minimizes installation space by eliminating a plug connection and optimizing processes by eliminating manufacturing steps for attaching connectors to the electrical line. To make contact with the electrical line, it is pressed into the insulation displacement terminal, which tapers preferably in one direction, as a result of which the conductor insulation is first cut and the conductor is clamped by the predetermined cutting edge geometry. The line can have a comparatively small line cross section of approximately 0.13 mm ² or less, but also a larger line cross section of greater than 0.13 mm ² , for example from 0.25 mm ² up to 4 mm ² or more.

Thus, the insulation displacement connector combines the advantage of direct electrical contacting of the circuit board, that is, contacting without a plug connection with mating connector, with a particularly robust fastening of the insulation displacement connector via two fastening mechanisms on the circuit board. This improves the suitability for the use of the insulation displacement connector in a vehicle, in particular with regard to the vibration resistance and other mechanical stress during the vehicle life.

So-called hot caulking has proven to be suitable and advantageous as a fastening means for fastening the housing to the printed circuit board. Because the hot caulking enables an extremely robust and easy to automate fastening. To use this manufacturing method, the fastening flange can have at least one thermoplastic plastic dome for the passage and hot caulking with the printed circuit board. The thermoplastic is, for example, PA (polyamide), PP (polypropylene), PBT (polybutylene terephthalate), POM (polyoxymethylene), PC (polycarbonate) and PE (polyethylene), a composite material made on this basis or another suitable thermoplastic. The plastic dome or domes can be formed in one piece with the fastening flange and / or the housing, that is to say they can be produced in a common manufacturing step by, for example, an injection molding process.

An embodiment variant provides that the plastic dome extends away from the fastening flange in a direction that is opposite to the open side of the insulation displacement terminal. In other words, the insulation displacement connector can be placed on the printed circuit board, in which case the plastic dome or domes extend downward through the printed circuit board and the insulation displacement connector is oriented upward. To push the plastic dome through, the printed circuit board has through holes which are preferably manufactured inexpensively by punching. The hot caulking itself can be carried out by means of a stamp which heats an end of the plastic dome protruding beyond the penetrated printed circuit board and, if necessary, deforms it by force such that the printed circuit board is undercut by the deformed end of the plastic dome. Alternatively, the plastic dome can be heated and deformed by means of laser hot caulking, as a result of which the manufacture and / or assembly of the insulation displacement connector can be automated in a simple manner.

Additionally or alternatively, the fastening flange can have at least one through hole for the passage of a rivet or a spacer rivet as fastening means. The riveting can also be implemented inexpensively and allows simple automation of the production and / or assembly. In particular, a spacer rivet connection as a fastening means offers the advantage that two insulation displacement connectors arranged in opposite directions on the circuit board can also be fastened to the circuit board by a common spacer rivet connection.

The fastening flange has at least one joining element for clinching (also referred to as clinching) with the printed circuit board. The fastener is thus realized by a clinching connection. The fastening flange preferably has a number of through holes corresponding to the fastening means in order to use a tool stamp used for the push-through joining to reshape the joining aid element through the fastening flange and thus fasten it to the printed circuit board. The joining aid element can be, for example, a sheet metal part that has good deformability. It is also conceivable that the auxiliary joining element is a plastic part, the tool being adapted to this material.

For the simplest possible manufacture and / or assembly, it has proven to be advantageous if the joining aid element is embedded in the fastening flange, in particular injected with a housing material. This can be achieved, for example, by an injection molding process.

A development of the invention that is particularly advantageous with regard to vibration resistance and durability provides that the housing has a locking device for fixing the has electrical line in the insulation displacement terminal. The locking device can be designed, for example, as a housing cover which, in the closed state, presses or additionally clamps the line held in the insulation displacement terminal. For this purpose, the locking device can also grip around and clamp the line in the form of a fork. For example, the locking device can be formed like a hinge on the housing, so that it can be moved between an open and a closed state. The locking device can preferably be latched to the housing in the closed state and thus secured against unintentional opening.

For simple manufacture and assembly of the insulation displacement connector, it has proven to be advantageous if the housing has a holding chamber for the insulation displacement contact, which opens into a line insertion opening that is open toward the top or to the side of the printed circuit board, towards which the insulation displacement terminal is oriented, and into one PCB contact opening open towards the printed circuit board, towards which the contact foot is aligned. For this purpose, the insulation displacement contact is injected into the housing, for example in an injection molding process. The cable insertion opening allows, for example, the insulation displacement to spring open in order to be able to insert the cable. The circuit board contact opening allows great flexibility for contacting the insulation displacement contact with the circuit board.

For the most efficient production of the insulation displacement connector, it has proven to be advantageous if the insulation displacement contact is surface-mountable on the printed circuit board, in particular by means of SMT (short for surface mounted technology). For this purpose, the at least one contact foot has a solderable connection surface. For assembly, a solder paste is applied to the contact foot before the insulation displacement connector is applied to the printed circuit board, which is then soldered in an oven by reflow soldering to a solder pad on the printed circuit board. In order to avoid floating the insulation displacement contact on the melted solder paste during soldering, it has proven to be advantageous if the insulation displacement connector is fastened to the printed circuit board by means of the fastening means before the soldering. If the fastening means is a spacer rivet connection, two insulation displacement contacts can even be soldered on different sides of the circuit board in a single method step.

As an alternative to this, the contact foot of the insulation displacement contact can be configured such that it can be pushed through, that is to say for push-through mounting on the printed circuit board, in particular for mounting by means of THT.

The invention also relates to a printed circuit board for a vehicle, with an insulation displacement connector according to one or more of the embodiment variants described above. The insulation displacement connector has an insulation displacement contact with at least one contact foot for electrically contacting the printed circuit board and a insulation displacement connector pointing away therefrom for electrically contacting an electrical line. In addition, the insulation displacement connector has an electrically insulating housing that holds the insulation displacement contact. According to the invention, the housing is non-positively and / or positively fastened to the printed circuit board by means of a fastening flange. The advantageous fasteners are described above. With this configuration, the printed circuit board enables a robust, vibration-proof and at the same time direct contact through an electrical cable.

list of figures

• 1 in einer schematischen Schnittansicht eine Schneidklemmverbindung für eine Leiterplatte mit einem erfindungsgemäßen Schneidklemmverbinder gemäß einem ersten Ausführungsbeispiel, gemäß dem Stand der Technik
• 2 in einer schematischen Schnittansicht eine Schneidklemmverbindung für eine Leiterplatte mit einem erfindungsgemäßen Schneidklemmverbinder gemäß einem zweiten Ausführungsbeispiel, gemäß dem Stand der Technik
• 3 in einer schematischen Schnittansicht eine Schneidklemmverbindung für eine Leiterplatte mit einem erfindungsgemäßen Schneidklemmverbinder gemäß einem dritten Ausführungsbeispiel, gemäß dem Stand der Technik
• 4 in einer schematischen Schnittansicht eine Schneidklemmverbindung für eine Leiterplatte mit einem erfindungsgemäßen Schneidklemmverbinder gemäß einem vierten Ausführungsbeispiel,
• 5 in einer Seitenansicht eine Schneidklemmverbindung für eine Leiterplatte mit einem erfindungsgemäßen Schneidklemmverbinder gemäß einem vierten Ausführungsbeispiel, und
• 6 eine Schnittansicht der Schneidklemmverbindung aus 5.

Advantageous exemplary embodiments of the invention are explained below with reference to the accompanying figures. Show it:

• 1 a schematic sectional view of an insulation displacement connection for a printed circuit board with an insulation displacement connector according to the invention according to a first embodiment, according to the prior art
• 2 a schematic sectional view of an insulation displacement connection for a printed circuit board with an insulation displacement connector according to the invention according to a second embodiment, according to the prior art
• 3 a schematic sectional view of an insulation displacement connection for a printed circuit board with an insulation displacement connector according to the invention according to a third embodiment, according to the prior art
• 4 1 shows a schematic sectional view of an insulation displacement connection for a printed circuit board with an insulation displacement connector according to the invention in accordance with a fourth exemplary embodiment,
• 5 in a side view an insulation displacement connection for a printed circuit board with an insulation displacement connector according to the invention according to a fourth embodiment, and
• 6 a sectional view of the insulation displacement connection 5 ,

The figures are merely schematic representations and serve only to explain the invention. The same or equivalent elements provided with the same reference numbers throughout.

1 shows an insulation displacement connector according to the invention 1 according to the prior art, for forming an insulation displacement connection between an electrical line (not shown) and a printed circuit board 2 serves. This insulation displacement connection makes it possible to connect the electrical line directly to the printed circuit board, that is to say without an interposed connector 2 to bring in electrically conductive contact. This insulation displacement connector 1 is suitable for use in a vehicle due to its vibration resistance.

The insulation displacement connector 1 has an electrically conductive insulation displacement contact made of a metal material 3 on the one insulation clamp 4 and at least one contact foot 5 having. The insulation piercing clamp 4 is set up for inserting and clamping the electrical cable. The contact foot 5 is for electrically conductive connection to a solder pad on the circuit board 2 formed by a solder connection, which will be explained in more detail below.

The insulation displacement connector also has 1 via an electrically insulating housing made of a thermoplastic 6 , The insulation displacement contact 3 is in a holding chamber 7 of the housing 6 held positively and / or non-positively. This is the insulation displacement contact 3 in the housing 6 injected, that is embedded in the plastic by injection molding. The holding chamber 7 and the insulation displacement contact received therein 3 open into a cable insertion opening 8th of the housing 6 towards which the insulation piercing clamp 4 the insulation displacement contact 3 is aligned. The line insertion opening 8th is elongated and seen in the longitudinal direction of a line to be inserted laterally through walls of the housing 6 limited. The cable to be inserted can therefore be fed in from above and on the front and into the cable insertion opening 8th insert and into the insulation piercing 4 Push. Through the cable insertion opening 8th the one with the PCB can be passed through it 2 electrical lead to be brought into electrically conductive contact in the insulation displacement terminal 4 Push it in and clamp it positively and / or non-positively in a manner known from insulation displacement technology. In addition, the holding chamber opens 5 of the housing 4 into a circuit board contact opening 9 towards which the contact foot 5 the insulation displacement contact 3 is aligned. The contact foot 5 is through the PCB contact opening 9 directly with a solder pad on the circuit board 2 connected by soldering. In the in 1 The embodiment shown is the insulation displacement contact 3 Surface-mountable as a so-called SMD component (surface-mounted device) and therefore by means of surface-mounting technology (SMT) on the circuit board 2 attached.

Out 1 further shows that the housing 6 also a mounting flange 10 for additional fastening of the housing 6 on the circuit board 2 having. The mounting flange 10 extends in two opposite lateral directions from the insulation displacement contact 3 receiving holding chamber 5 path. In this embodiment, the mounting flange 10 two spaced apart, cone-shaped plastic domes 11 and 12 as a fastener through the circuit board 2 are passed in the thickness direction. For the passage of the plastic domes 11 . 12 has the circuit board 2 via punched through holes on the circuit board side 13 and 14 ,

On one of the insulation displacement contacts 3 opposite side of the guide plate 2 are the plastic domes 11 . 12 with the circuit board 2 heißverstemmt. That means the housing 6 by hot caulking the mounting flange 10 in addition to soldering the insulation displacement contact 3 with the circuit board 2 attached to this. The hot caulking is realized here by means of a stamp (not shown), which holds the axial ends of the plastic domes 11 . 12 melted by the action of heat and deformed by the action of force so that an undercut of the axial ends of the plastic domes 11 . 12 on the circuit board 2 results.

2 shows a further embodiment of the insulation displacement connector 1 according to the state of the art. This corresponds essentially to the embodiment described above. The insulation displacement contact deviates from this 3 on the circuit board 2 but not surface-mounted, but by means of through-hole technology (THT) with the solder pad of the circuit board 2 connected and attached to it by a back solder connection. For this is the contact foot 5 for pushing through two contact holes 15 and 16 the circuit board 2 with two spaced wires and with the circuit board 2 soldered.

Another embodiment of the insulation displacement connector 1 according to the prior art is in 3 shown. In contrast to the embodiments described above, the guide plate has 2 two insulation displacement connectors attached to it in mirror symmetry 1 on, i.e. on every flat side of the circuit board 1 one insulation displacement connector each 1 , With this configuration, two lines can be placed in one insulation displacement terminal 4 simultaneously with the circuit board 2 bring in contact. Everyone points to this mounting flange 10 of the housing 6 two in the surface direction of the circuit board 2 spaced-apart, through-flange through holes 17 and 18 on. Through each of the through holes 17 . 18 as well as through holes on the PCB side 13 . 14 a distance rivet extends 19 and 20 as a fastener. Out 3 shows that the heads of the spacer rivets 19 . 20 with both yourself in relation to the circuit board 2 opposite mounting flanges 10 the housing 6 are in undercut contact, creating the insulation displacement connector 1 by clamping on the circuit board 2 are held. For manufacturing reasons, the insulation displacement contacts 3 here surface-mounted using SMT.

In 4 is another embodiment of the insulation displacement connector 1 shown. The housing is different from the embodiments explained above 6 by means of a clinching connection, which is also referred to in the technical language as clinching, as a fastening means on the printed circuit board 2 attached. For this purpose, the mounting flange 10 again the through holes 17 . 18 for passing a tool stamp required for clinching in the direction of the printed circuit board 2 on. To the housing materials made of plastics or fiber-reinforced plastics 6 and the circuit board 2 To be able to connect with each other are in the mounting flange 10 two joining aids 21 and 22 embedded. For the joining elements 21 . 22 it is just an example of two stamped sheet metal parts, as are common for clinching. These are for passing through the through holes on the circuit board side 13 . 14 to the circuit board 2 are open on one of the circuit boards 2 facing side of the mounting flange 10 not completely surrounded by the housing material.

As in 4 is also recognizable, are on the insulation displacement connector 1 opposite, flat side of the circuit board 2 two mating elements 23 and 24 to engage with the joining elements 21 . 22 arranged. According to the representation 4 are the joining elements 21 . 22 as well as the mating elements 23 . 24 to form the clinching connection already deformed by the clinching method used, in particular by a tool die interacting with the tool stamp. By pushing through the housing 6 the insulation displacement connector 1 positive and / or non-positive on the circuit board 2 held.

In the 5 and 6 is another embodiment of the insulation displacement connector 1 shown. Here are again two insulation displacement connectors 1 mirror-symmetrical on the guide plate 2 attached, the two insulation displacement terminals 4 of the two insulation displacement connectors 1 point away from each other. Both insulation displacement connectors 1 are on a common fastener in the form of a mushroom catch with each other and on the circuit board 2 attached. To lead the fastener through, the two insulation displacement connectors 1 the through holes explained above 17 . 18 , and the circuit board 2 the through holes 13 . 14 on.

According to 5 , which shows a side view, the mushroom catch essentially consists of a mushroom-shaped expansion element 25 and a conical spreader pin 26 for driving into the expansion element 25 to spread it out. The spreading element 25 has a plurality of spaced-apart spreader bars 27 as well as a foot section 28 and a head portion axially spaced therefrom 29 , The spreader bars 27 hang on the foot section 28 together and point in the area of the head section 29 a free end so that they can either squeeze inwards or through the spreader pin 26 spread outwards. When compressed, that is to say not expanded, the outer diameter of the head section is 29 slightly smaller than the inside diameter of the through holes 13 . 14 and the through holes 17 . 18 , so that the head section can be passed through it. In 5 can be seen that the conically shaped expansion pin 26 in the area of the head section 29 has a smaller outer diameter than in the area of the foot section 28 ,

The spreader bars 27 feature in the area of the head section 29 over an outwardly projecting contact surface 30 for the undercut support on one (here upper) mounting flange 10 and a sliding surface 31 for sliding on the inner surfaces of the through holes 13 . 14 and the through holes 17 . 18 , 5 shows a state in which the expansion element 25 through the mounting flanges 10 is inserted through it, the spreader pin 27 but not (yet) driven in and the expansion element 25 is not (yet) spread.

6 shows the mushroom locking in a sectional view in a spread state of the expansion element 25 , The spreader pin is in this state 26 for spreading between the spreader bars 27 passed through. By filling in the distance between the spreader bars 27 through the spreader pin 26 these are spread out. In addition, this also compresses the expansion rods 27 prevented inside. The contact surface lies in the expanded state shown 30 on the upper mounting flange 10 open, undercuts it and thereby holds the two insulation displacement connectors 1 on the circuit board 2 , That means that the two mounting flanges 10 between the foot section 28 and the head section 29 are held. In addition, in 6 recognizable that the insulation displacement contact 3 is surface-mounted here.

Based on the illustrated embodiments, the insulation displacement connector according to the invention can 1 be modified in many ways. So it is possible in the vicinity of the cable insertion opening 9 to provide a fixing element, in particular a housing cover. This is, for example, a hinge with the housing 6 connected and presses against the electrical line to be fastened in order to fix it in addition to insulation displacement. It is also possible for the fixing element to grip around the line in a fork-like manner in the manner of an insulation displacement contact and thus also to fix it undercutting in the longitudinal direction of the line.

LIST OF REFERENCE NUMBERS

1

Insulation displacement connector

2

circuit board

3

IDC

4

insulation displacement terminal

5

contact foot

6

casing

7

holding chamber

8th

Line insertion opening

9

PCB contact opening

10

mounting flange

11.12

plastic dome

13.14

Through hole (PCB side)

15.16

contact hole

17.18

Through hole (mounting flange side)

19.20

Distance rivets

21.22

Add auxiliary element

23.24

Against joining auxiliary member

25

spreading element

26

Arrowhead

27

spreader

28

foot section

29

header

30

contact surface

31

sliding surface

Claims (9)

Insulation displacement connector (1) for bringing an electrical line into contact with a circuit board (2), with - an insulation displacement contact (3), the at least one contact foot (5) for electrically contacting the circuit board (2) and an insulation displacement terminal (4) pointing away therefrom for electrically contacting the electrical line, and - an electrically insulating housing (6) in which the insulation displacement contact (3) is held, the housing (6) having a fastening flange (10) for non-positive and / or positive fastening to the printed circuit board ( 2) by a fastening means, characterized in that the fastening flange (10) has at least one joining aid element (21, 22) for pushing through with the printed circuit board (2). Insulation displacement connector (1) Claim 1 , characterized in that the fastening flange (10) has at least one thermoplastic plastic dome (11, 12) for the passage and hot caulking with the printed circuit board (2). Insulation displacement connector (1) Claim 1 or 2 , characterized in that the fastening flange (10) has at least one through hole (13, 14) for the passage of a rivet or a spacer rivet (19, 20). IDC connector (1) according to one of the Claims 1 to 3 , characterized in that the joining aid element (21, 22) is embedded in the fastening flange (10). IDC connector (1) according to one of the preceding claims, characterized in that the housing (6) has a locking device for fixing the electrical line in the IDC (3). Insulation displacement connector (1) according to any one of the preceding claims, characterized in that the housing (6) has a holding chamber (7) for the insulation displacement contact (3), which in a line insertion opening (8) to which the insulation displacement connector (4) is aligned , and opens into a circuit board contact opening (9), towards which the contact foot (5) is aligned. Insulation displacement connector (1) according to one of the preceding claims, characterized in that the insulation displacement contact (3) is surface-mountable on the printed circuit board (2). IDC connector (1) according to one of the Claims 1 to 6 , characterized in that the contact foot (5) of the insulation displacement contact (3) for Push-through installation on the circuit board (2) is set up. Printed circuit board (2) for a vehicle, with an insulation displacement connector (1) which has an insulation displacement contact (3) with at least one contact foot (5) for electrically contacting the circuit board (2) and a insulation displacement connector (4) pointing away from it for electrically contacting an electrical one Cable, and an electrically insulating housing (6) holding the insulation displacement contact (3), the housing (6) being fastened non-positively and / or positively to the printed circuit board (2) via a fastening flange (10), characterized in that that the fastening flange (10) has at least one joining aid element (21, 22) for pushing through with the printed circuit board (2).

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