DE102012103599A1 - Insulation displacement connector for connecting with circuit board and for attaching electric conductor, has overload protection device to suppress the movement of spring element along extending direction of cutting edge portion - Google Patents

Abstract

The connector (10) has a cutting edge portion (20) that is arranged such that an electric conductor (14) for connecting to the connector, is moved along the edge portion. A supporting portion (24) is arranged to press the conductor against cutting edge portion when the conductor is moved such that an electrical insulation portion (18) of conductor is severed. The cutting edge portion is formed on a spring element (22). An overload protection device (34) is arranged to suppress the movement of spring element along the extending direction (S) of cutting edge portion.

Description

The invention relates to a insulation displacement connector, which is designed for connection to a carrier and for connecting an electrical insulation having electrical conductor, with at least one cutting edge and at least one support device, in particular a support edge, wherein the cutting edge is arranged so that the conductor for connection to the insulation displacement connector along the cutting edge is movable and wherein the support device is arranged for pressing the conductor against the cutting edge when the conductor is moved along the cutting edge, so that the electrical insulation of the electrical conductor is severable.

Such insulation displacement connector is from the DE 101 49 815 A1 known. The insulation displacement connector described therein comprises two rigid pairs of cutting edges arranged in parallel. A disadvantage of such an insulation displacement connector is that only conductors with a diameter in a narrow predetermined diameter interval can be used. If too thin conductors are used, the cutting edges are unable to cut through the insulation. If too thick conductors are used, the arms deform, on which the cutting edges are formed. This leads to a significant weakening of the cross section of the conductor, which is undesirable.

From the DE 40 33 366 A1 For example, an insulation displacement connector is known in which oppositely oriented tabs have a cutting edge at their respective free end, such that insulation of a conductor which is forced between the two cutting edges is cut. Even with this connection element, it is disadvantageous that only conductors with small deviations from a nominal diameter can be used.

An electrical fork contact is at least partially out of the DE 10 2008 045 810 B4 in which the problem described above also occurs.

The invention has for its object to provide a cutting-clamp connector, which reduces disadvantages in the prior art.

The invention solves the problem by a generic insulation displacement connector in which the cutting edge is formed on a spring element and the insulation displacement connector has an overload safety device for suppressing movement of the spring element in the direction of extension of the cutting edge.

An advantage of this insulation displacement connector that electrical conductors of different diameters can be contacted. The fact that the insulation displacement connector is formed on the spring element, the cutting edge can recede so far that the insulation of conductors with large diameters can be cut. In other words, it is possible to form the cutting edge so that in its zero position, that is, when no conductor is contacted, it is arranged close to the support device, in particular at the support edge. In this way, electrical conductors can be contacted with a small diameter. As described above, the formation of the cutting edge on the spring element means that even conductors with a large diameter can be contacted.

It is another advantage that the conductor can be safely removed from the insulation displacement connector without damaging it. Since the cutting edge is formed with a spring element, it must have a low rigidity in at least one degree of freedom, since otherwise too high forces would occur during introduction of the conductor. However, such a spring element can be easily damaged if the conductor is to be removed again. However, damage is prevented by the overload safety device. The advantage of being able to contact electrical conductors of different diameters is therefore not due to the disadvantage that the wire can not be removed again without danger to the insulation displacement connector.

It is also advantageous that the insulation displacement connector can be designed as a stamped and bent part. It is thus a joint-free production possible, which allows a cost-effective mass production.

In the context of the present description, the cutting edge is understood to mean, in particular, an edge of a cutting element which is of such sharp-edged design that at least one lacquer insulation of an electrical conductor can be cut through. In particular, the cutting edge is formed so that a plastic insulation of an electrical conductor is cut through. Of course, it is always possible to form an insulation so stable that the insulation at a given cutting edge is not severable. In particular, however, the cutting edge is designed so that it can sever insulation.

Under the electrical conductor is understood in particular a flexible electrical conductor, such as a einrähtiger electrical conductor.

Under the spring element is in particular a spring tab understood, which has a tab length, said tab length at least three times is as large as a tab width of the tab and / or dam at least fifteen times a sheet thickness of that sheet corresponds, from which the tab is made.

The feature that the insulation displacement connector has an overload safety device for suppressing movement of the spring element in the direction of extension of the cutting edge could also be formulated such that the cutting edge recedes in a back-softening direction upon insertion of the electrical conductor and that the overload safety device is arranged so that it prevents movement of the spring element in the direction perpendicular to the return direction.

According to a preferred embodiment, the overload safety device is also designed to suppress a movement of the spring element in the direction perpendicular to the extension of the cutting edge over a predetermined Maximalfederweg addition. Preferably, the maximum spring travel is chosen so that the spring element deforms only elastically when it covers only the maximum spring travel. An advantage of this is that the user is given a haptic feedback when he tries to introduce an electrical conductor with a large diameter in the insulation displacement connector.

Preferably, the insulation displacement connector comprises a latching connection, which is designed for fixing the conductor, wherein the latching connection is arranged so that the electrical conductor for connection to the insulation displacement element along the cutting edge to the latching device is movable. In other words, the cutting edge, the support device and the latching device are arranged relative to each other, that the conductor must first necessarily be guided along the cutting edge for connection to the insulation displacement connector, and then that it engages in the latching device. For connecting the electrical conductor to the insulation displacement connector, it is thus sufficient to move the conductor, in particular perpendicular to its longitudinal axis.

The locking device may be formed, for example, by a recess adjacent to the cutting edge. Such a locking device is particularly easy to manufacture and also robust.

Preferably, the support device is arranged on a second spring element, wherein the support device preferably has a second cutting edge. In other words, the insulation displacement connector preferably comprises two opposing cutting edges, each formed at one end of a spring element. This results in a particularly large range of diameters for the electrical conductor, which are suitable for contacting.

It is particularly favorable if the two spring elements bring about a force flow closed like a clamp, if a conductor is arranged between the cutting edges or the cutting edge and the supporting device. In other words, the two spring elements have a foot region which faces away from the cutting edges, wherein the two foot regions are directly adjacent to one another. On the electrical conductor then act in the clamped state to a good approximation no shear forces, which makes insertion and removal very easy.

According to a preferred embodiment, the overload-securing device has a first overload tab, which surrounds the first spring element in a clip-like manner, and a second overload tab, which surrounds the second spring element like a clip. In particular, the overload straps are bent in a C-shape, so that the spring element can initially retreat by the maximum spring deflection during insertion of the electrical conductor, until it abuts the middle section of the C-shaped overload strap, so that further movement is prevented. Such overload protection device is particularly easy to produce.

Preferably, the cutting clamp connector has a bottom portion which is arranged so that the conductor from the latching device to the bottom portion to be pressed and thereby fixable.

Preferably, the bottom portion extends along a ground plane and the at least one spring element is arranged so that a reverse direction forms an angle of at most 25 ° with the ground plane. In particular, the reverse direction is parallel to the ground plane. That is, an imaginary point on the cutting edge moves substantially parallel to the bottom portion when an electrical conductor is inserted into the insulation displacement connector.

According to a preferred embodiment, the insulation displacement connector is integrally formed, wherein it is in particular a stamped and bent part.

Preferably, the insulation displacement connector comprises a fastening device for attachment to a printed circuit board. The fastening device comprise solder straps and / or at least one press-fit pin. Further, the bottom portion may be formed as an SMD soldering surface. Further, the bottom portion may provide on its side facing away from the carrier suction surfaces for automated assembly.

It is favorable if the cutting edge has a first cutting edge section and at least one second cutting edge section, which enclose an angle of at least 15 ° with one another. In this way, an insulation of an electrical conductor can be cut particularly well. But it is also possible that an insertion funnel is formed on the side facing away from the latching device, which is optionally formed not cutting.

According to the invention is also an insulation displacement connection comprising a cutting terminal connector according to the invention and an electrical conductor having an electrical insulation, wherein the electrical conductor has a severed insulation and in the region of the severed insulation is in electrical contact with the at least one cutting edge and wherein the electrical conductor is clamped between the cutting edge and the support device.

According to the invention is also a circuit board, which extends along a plane and on which at least one inventive insulation displacement connector is arranged, whose cutting edge extends to the plane.

In the following the invention will be explained in more detail with reference to the accompanying drawings. It shows

1 A top view of an insulation displacement connector according to the invention,

2 - a view from the side,

3 - a view from the front and

4 - An application example for a cutting terminal connector according to the invention.

1 shows an insulation displacement connector according to the invention 10 which is adapted for connection to a carrier 12 , For example, a printed circuit board, and for connecting an electrical conductor 14 , The electrical conductor 14 has a soul 16 and the soul 16 surrounding insulation 18 , The insulation displacement connector 10 has a first cutting edge 20 attached to a first spring element 22 is trained.

The insulation displacement connector also includes a support device 24 that has a second cutting edge 26 and on a second spring element 28 is trained. The two spring elements 22 . 28 have respective foot areas 30.1 . 30.2 which are immediately adjacent and in the present case even merge. The foot areas 30.1 . 30.2 are the respective cutting edges 20 . 26 away. The spring elements 22 . 28 together form a bracket, resulting in a dashed line, convex force flow 32 between the two cutting edges 20 . 26 , leads. The foot areas 30.1 . 30.2 extend under an at least approximately right angle to a bottom portion 38 ,

Will be the leader 14 in the insulation displacement connector 10 introduced, so gives way to the first cutting edge 24 in a first reverse direction R1 and the second cutting edge 26 in a second backsize R2 back.

The insulation displacement connector 10 includes an overload safety device 34 that a first overload tab 36.1 that is the first spring element 22 clasps like a clip, and a second overload flap 36.2 that the second spring element 28 encompasses like a clamp. In 1 is the second overload tab 36.2 shown cut so that a maximum spring travel W can be seen.

It can be seen that the first spring element 22 would be deflected further if a leader 14 with a larger diameter would be introduced. From a certain diameter of the conductor 14 would the spring element 22 have to deflect more than the maximum travel W, so it to the second overload tab 36.2 strikes. A further movement in the direction of the respective backsweep direction R, ie R1 or R2, is thus suppressed.

2 shows the insulation displacement connector 10 in a side view. It can be seen that the spring elements 22 . 28 in the field of overload safety device 34 have a tab width B. In the foot area 30.1 is the second spring element 28 thickened running. The second spring element 28 is designed as a spring tab and has a tab length L, which is at least twice the tab width.

The spring elements 22 . 28 have a thickness D, which in the present case corresponds to a thickness D of a metal sheet from which the insulation displacement connector 10 made by punching and bending. The tab length L is at least six times this thickness D and / or at most fifteen times this thickness D.

2 shows that the overload safety device 34 also suppresses a movement in direction S, which denotes the extension of the cutting edge. In other words, the overload safety device prevents 34 a movement perpendicular to the respective reverse direction R and to the longitudinal extent of the spring elements 22 . 28 ,

2 also shows the bottom section 38 which extends along a ground plane E, which in the present case is the xy plane. The bottom section has on the carrier 12 opposite side a suction surface 39 , The carrier 12 facing side forms an SMD soldering surface. The reverse direction R forms an angle of 0 ° with the ground plane E, that is, that it lies in the ground plane E. 2 also shows a fastening device 40 , the two solder straps 42.1 . 42.2 includes.

3 shows the insulation displacement connector 10 in a front view. It is a catch device 44 to recognize, in the present case by two recesses 46.1 . 46.2 in the spring elements 22 . 28 is formed. By means of the locking device 44 becomes the dashed line 14 on the bottom section 38 too pressed and so fixed.

To insert the conductor 14 this is on a first cutting edge portion 50 the first cutting edge 20 and / or a first cutting edge portion 54 placed and, for example, with a screwdriver on the bottom section 38 too pressed. This is the insulation 18 also by a second cutting edge section 52 the first cutting edge 20 and / or a second cutting edge portion 56 the second cutting edge 26 cut up and the soul 16 so contacted.

For example, by sliding the screwdriver blade between the bottom section 38 and the leader 14 this can be removed again without the insulation displacement connector 10 to damage.

4 shows a circuit board according to the invention 12 with three insulation displacement connectors 10.1 . 10.2 . 10.3 ,

LIST OF REFERENCE NUMBERS

10

Insulation displacement connector

12

carrier

14

ladder

16

soul

18

insulation

20

first cutting edge

22

spring element

24

support device

26

second cutting edge

28

second spring element

30

footer

32

power flow

34

Overload safety device

36

Overload tab

38

bottom section

40

fastening device

42

Lötlasche

44

locking device

46

return

50

first cutting edge portion

52

second cutting edge portion

54

first cutting edge portion

56

second cutting edge portion

W

maximum travel

R

Receding direction

B

Laschenbreiteh

L

Flange length

D

thickness

S

Extension direction of the cutting edge

e

level

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 10149815 A1 [0002]
• DE 4033366 A1 [0003]
• DE 102008045810 B4 [0004]

Claims (10)

Insulation displacement connectors ( 10 ) which is designed for connection to a carrier ( 12 ) and for connecting an electrical insulation ( 18 ) having electrical conductor ( 14 ), with - at least one cutting edge ( 20 ) and - at least one support device ( 24 ), in particular a support edge, - wherein the cutting edge ( 20 ) is arranged so that the conductor ( 14 ) for connection to the insulation displacement connector ( 10 ) along the cutting edge ( 20 ) is movable and - the supporting device ( 24 ) is arranged for pressing the conductor ( 14 ) against the cutting edge ( 20 ), if the leader ( 14 ) along the cutting edge ( 20 ) is moved so that the electrical insulation ( 18 ) of the electrical conductor ( 14 ) is severable, characterized in that - the cutting edge ( 20 ) on a spring element ( 22 ) is formed and - the insulation displacement connector ( 10 ) an overload safety device ( 34 ) for suppressing a movement of the spring element ( 22 ) in the direction (S) of an extension of the cutting edge ( 20 ) having. Insulation displacement connectors ( 10 ) according to claim 1, characterized in that the overload safety device ( 34 ) for suppressing also a movement of the spring element ( 22 ) in a reverse direction (R) perpendicular to the extension of the cutting edge ( 20 ) is formed beyond a predetermined maximum spring travel (W). Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized by a latching device ( 44 ), which is designed to fix the conductor ( 14 ), wherein the latching device ( 44 ) is arranged so that the electrical conductor ( 14 ) for connection to the insulation displacement connector ( 10 ) along the cutting edge ( 20 ) on the locking device ( 44 ) is too movable. Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized in that the supporting device ( 24 ) on a second spring element ( 28 ) is arranged, wherein the supporting device ( 24 ), in particular a second cutting edge ( 26 ) having. Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized in that the overload safety device ( 34 ) - a first overload flap ( 36.1 ), which the first spring element ( 22 ) at least partially surrounds in a clamp-like manner, and - a second overload flap, which surrounds the second spring element ( 28 ) at least partially surrounds in a clip-like manner. Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized by a bottom section ( 38 ), which is arranged so that the conductor ( 14 ) of the locking device ( 44 ) on the bottom section ( 38 ) To be pressed and thereby fixable. Cutting-clamping device according to claim 6, characterized in that the bottom portion ( 38 ) extends along a ground plane (E) and the spring element ( 22 ) is arranged so that its reverse direction (R) forms an angle of at most 45 °, in particular at most 25 °, with the ground plane (E). Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized in that the latching device ( 44 ) by at least one return ( 46 ) in the spring element ( 22 ) is formed. Insulation displacement connectors ( 10 ) according to one of the preceding claims, characterized in that the insulation displacement connector ( 10 ) is integrally formed. Printed circuit board ( 12 ) extending along a plane and on which at least one insulation displacement connector ( 10 ) according to one of the preceding claims, wherein the cutting edge ( 20 ) to extend to the plane.

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