DE9004819U1 - Electrical insulation displacement contact element - Google Patents

Description

5730/V/ro

Electrical insulation displacement contact element

The invention relates to an insulation displacement contact element according to the preamble of claim 1.

With an insulation displacement contact element, contact is made with the wire of the insulated electrical cable by inserting the electrical cable into the insulation displacement slot, whereby the electrical cable slides on the edges that delimit the insulation displacement slot. The existing insulation is cut through under the simultaneous clamping voltage so that the opposing boundary edges of the insulation displacement slot contact the wire. The contact can be impaired by longitudinal movements of the electrical cable, which can be triggered by tensile forces acting on the cable.

In order to counteract this disadvantage, a strain relief for the electrical cable is provided in an electrical connector with an insulation displacement contact element housed in a housing, as can be seen in DE-PS 23 14 330. The strain relief is formed by the fact that, when the housing, which consists of a housing base and a housing cover, is folded together, projections arranged on the underside of the housing cover press the cable against the base surfaces of the receiving notches that receive it.

The invention is based on the object of creating a strain relief for an insulation displacement contact element of the type specified at the beginning, which acts independently of a housing.

This object is solved by the features of claim 1.

In the design according to the invention, the strain relief is implemented on the insulation displacement contact element, whereby this strain relief is independent of other components, such as a housing that accommodates the insulation displacement contact element. The strain relief according to the invention is formed as one piece on the insulation displacement contact element and can be manufactured simply, quickly and therefore inexpensively. It is formed by a web that is connected as one piece to the insulation displacement contact element and that protrudes into the space that the electrical line takes up in its contact end position, so that the strain relief edge of the strain relief web that extends transversely to the electrical line protrudes into a bend in the line or penetrates the insulation of the electrical line and thus becomes a counterweight against axial movements of the electrical line. Due to the fact that the strain relief edge extends into the space occupied by the electrical cable in its contact end position, the electrical cable can be bent at an angle or in an S shape at the strain relief edge, which is the basis for the strain relief effect of the strain relief bar.

Within the scope of the invention, it is possible to provide one or two strain relief bars each on the outside of the associated insulation displacement bar. A simple strain relief as mentioned first is sufficient for the side from which the electrical cable is fed. On the other side, no strain relief needs to be provided if the electrical cable ends there. If, however, it is a continuous electrical cable, then it is recommended to provide a strain relief bar on both sides.

Advantageous further developments of the invention are characterized in the subclaims.

The invention is explained in more detail below using preferred embodiments and a drawing. It shows, in an enlarged view,

Fig. 1 shows an insulation displacement contact element according to the invention in the front view;

Fig. 2 shows the insulation displacement contact element in side view; Fig. 3 shows the insulation displacement contact element in top view;

Fig. 4 shows an insulation displacement contact element according to the invention in the front view as a second embodiment;

Fig. 5 shows the insulation displacement contact element according to Fig. 4 in side view;

Fig. 6 shows the insulation displacement contact element according to Fig. 4 in plan view;

Fig. 7 the insulation displacement contact element according to Fig. 1 in a modified design and in front view;

Fig. 8 shows the insulation displacement contact element according to Fig. 7 in side view;

Fig. 9 shows the insulation displacement contact element according to Fig. 7 in plan view;

Fig. 10 the insulation displacement contact element according to Fig. 4 in a modified design;

Fig. 11 the insulation displacement contact element according to Fig. 10 in side view;

Fig. 12 shows the insulation displacement contact element according to Fig. 10 in plan view.

The insulation displacement contact element 1 made of a stamped sheet metal part, which is symmetrical with respect to its longitudinal center plane 4 extending from its front end 2 to its rear end 3, consists of a base part 5, two insulation displacement webs 6, 7 extending from the base part 5 to the rear on both sides of the longitudinal center plane 4 and parallel thereto.

a plug contact element extending forwards from the base part 5, preferably in the form of a flat contact spring 8 with two flat spring arms 9 arranged symmetrically to the longitudinal center plane 4, which extend convergently forwards and touch each other at a contact point 11 or are spaced apart from each other. The front ends of the flat spring arms 9 are bent away from each other in a manner known per se in the form of an insertion funnel 12 open to the front. A plug axis 13 extends between the flat spring arms 9 in the longitudinal direction of the insulation displacement contact element 1, along which a mating plug contact pin (not shown) can be inserted between the flat spring arms 9 and pulled out again.

The base part 5 has a flat, rectangular base web 14, which is arranged in a plane extending in the longitudinal direction of the insulation displacement contact element 1 and at right angles to the longitudinal center plane 4 and whose rear edge is designated 15, whose front edge is designated 16 and whose side edges are designated 17. At the side edges 17, inner base legs 18, 19 are connected in one piece to the base web 14 and angled towards the same side, so that the base web 14 and the base legs 18, 19 result in a middle part of the base part 5 with a U-shaped cross section. At the side edges 21 of the base legs 18 facing away from the base web 14, outer base webs 22 are angled outwards at right angles so that they extend parallel to the middle base web 14. Outer base legs 24, 25 are integrally connected to the side edges 23 of the outer base webs 22 facing away from the inner base legs 18, 19 and are angled at right angles so that they extend parallel to the inner base legs 18, 19 and at a distance from them. The base part 5 comprising the middle and outer base webs 14, 22 and the inner and outer base legs 18, 19, 24, 25 is thus M-shaped in cross section, with the front edges and rear edges of these parts each lying in a transverse plane. The base part 5 thus has a box-like shape.

The two insulation displacement webs 6, 7 arranged parallel to the longitudinal center plane 4 are connected in one piece to the rear ends of the inner base legs 18, 19 and are of the same width, and thus represent rearwardly extending extensions of the inner base legs 18, 19. The insulation displacement webs 6, 7 each have a central insulation displacement slot 26, 27 that opens out at their rear ends and extends forwards, which protrude slightly forwards beyond the connection point 28 of the insulation displacement webs 6, 7 or the rear edge 16 of the base part 5. The front ends of the insulation displacement slots 6, 7, which are closed by a rounding, are designated 29. The insulation displacement slots 26, 27 are at the rear open ends.

27 in the form of an insertion funnel 31. The insulation displacement slots 26, 27 thus extend in a plane El, which extends from the back to the front and at right angles to the longitudinal center plane 4 and centrally through the base part 5. The rear edges of the insulation displacement webs 6, 7 are sharpened on both sides in the shape of a cutting edge. At the connection points

28, the insulation displacement webs 6, 7 are slightly cut on their two side edges 17, 21, preferably by semicircular curves 32.

The outer base legs 24, 25 each form with their rear edges a strain relief bar 33 arranged parallel to the insulation displacement bars 6, 7 with a strain relief edge 34 extending transversely to the insulation displacement slots 26, 27 and also transversely to the insulation displacement slot plane El, which the front ends

29 of the insulation displacement slots 26, 27 protrudes to the rear by the amount indicated by a. The sheet thickness of the insulation displacement contact element 1 formed by a one-piece punched/bent part is less than 1 mm. As a result, "edges" are formed at the rear ends of the strain relief webs 33. As Fig. 1 shows, these "edges" can preferably be sharpened by external or one- or two-sided beveled surfaces 35 or edge breaks.

Sawtooth-shaped locking teeth 38 are arranged one behind the other on the free end edges 36 of the outer base legs 24, 25, which serve to lock or fix the insulation displacement contact element 1 in a chamber of a housing (not shown), in particular a plastic housing. The locking teeth 38 are directed forwards.

In the present design, the flat spring arms 9 of the flat contact spring 8 are connected in one piece to the front ends of the outer base legs 24, 25. They are not arranged centrally, but offset parallel to the free end edges 36 of the outer base legs 24, 25 or to the middle base web 14, so that the plug-in axis 13 is at a distance from the insulation displacement slot plane El. In addition, the flat spring arms 9 are narrower than the outer base legs 24, 25.

To contact the insulation displacement contact element 1 with an insulated electrical cable 39, the latter is pushed or pressed from behind into the insulation displacement slots 26, 27 up to their front ends 29, whereby the insulation displacement slot edges 41 cut into the insulation 42 of the cable 39 and clamp the wire 43 of the cable 39 between them, thereby establishing electrical contact with the wire 43. Since the strain relief edges 34 protrude beyond the front ends 29 of the insulation displacement slots 26, 27 by the dimension a, the cable 39 is bent in the area of the strain relief edges 34, as shown in Figure 1. This creates a strain relief for the cable 39, which protects the insulation displacement contact points against tensile stresses directed outwards (see arrows 44, 45). This means that the tensile stresses are at least largely introduced into the strain relief webs 33, so that the insulation displacement contact points in the area of the insulation displacement slots 26, 27 are essentially free from tensile stresses. The strain relief edges 34 can also penetrate into the insulation 42. This further increases the strain relief.

The insulation displacement contact element 1 of the second embodiment according to Figures 4 to 6 also functions in a similar way, in which identical or comparable parts are designated with the same reference numerals. In this embodiment, the middle base web designated 14a extends over the entire width of the base part 5, with the outer base legs 24a, 25a being angled in a U-shape at the side edges 17a of the base web 14a. The outer base webs 22a are integrally connected to the side edges 23a of the outer base legs 24a, 25a facing away from the base web 14a and are angled inwards parallel to the base web 14a, with the inner base legs 18a, 19a being connected to their inner side edges 21a and angled at right angles to the base web 14a, so that here too the outer and inner base legs 18a, 19a, 24a, 25a extend parallel and next to each other at a distance from each other and upright to the middle base web 14a. The base part 5 therefore does not have an M-shaped cross-sectional shape, but rather an essentially E-shaped cross-sectional shape with folded-in free edges.

In the second embodiment, locking teeth 38a comparable to the locking teeth 38 of the first embodiment are arranged on the side edges 17a of the middle base web 14a and the side edges 23a of the outer base legs 24a, 25a. Since these side edges are not free end edges, the locking teeth 38a are cut into the adjacent sheet metal part bent at a right angle, namely the outer base legs 24a, 25a and the outer base webs 22a, whereby they do not participate in the respective bend and remain as locking teeth 38a protruding from the respective side edge. In Figures 4 to 6, only one locking tooth 38a is shown at the front end of the part carrying it.

The inner base legs 18a, 19a are slightly narrower than the

outer base legs 24a, 25a, because they end with their free side edges 46 in front of the inner surface of the middle base web 14a, which can be clearly seen in Fig. 5. Since the inner base legs 18a, 19a are therefore not connected to the inner base web 14a, they are held elastically due to their cantilevered arrangement, even in the longitudinal direction of the line 39 inserted into the insulation displacement slots 26, 27. The inner base legs 18a, 19a can thus follow slight longitudinal movements of the line 39, which reduces the risk of contact difficulties already described at the beginning. This advantage exists in addition to the strain relief, which functions according to the first embodiment.

The insulation displacement webs 6, 7, which also represent extensions of the inner base legs 18a, 19a, are in this embodiment widened in steps in the area of their connection point 28 compared to the inner base legs 18a, 19a, namely to the width of the outer base legs 24a, 25a. The step edges are designated 47 in Fig. 5.

The design of the insulation displacement contact element 1 according to Fig. 7 to 9, in which the same or comparable parts are provided with the same reference numerals, differs from the design according to Fig. 1 to 3 mainly only in that the flat spring arms 9 are not connected in one piece to the front ends of the outer base legs 24, 25, but to the front ends of the inner base legs 18, 19, so that they are spaced closer together at their connection points. The flat spring arms 9 can extend parallel to the front, as shown in Fig. 7. In the area of the contact point 11, the contact spring arms 9 are preferably bent in a rounded manner towards one another and then bent away from one another again in order to form the contact point 11 and the insertion funnel 12 as in the first embodiment.

Instead of the transverse offset of the flat spring arms 9 to the insulation displacement

slot plane El, as is realized in the first embodiment, the flat spring arms 9 in the third embodiment extend obliquely to the insulation displacement slot plane El, whereby they can extend obliquely overall or only obliquely over part of their length and then extend straight again in the area of the contact point 11, as shown in Fig. 8.

In addition, in the third embodiment, support legs 51 are connected to the front ends of the outer base legs 24, 25 and are bent from their forward-projecting position at right angles to the associated flat spring arm 9. The support legs 51 are long enough so that their front edges 51a rest against the outer surfaces of the flat spring arms 9 and thus support them on the outside. In the present embodiment, the support legs 51 border directly with their rear surfaces on the front ends of the outer base legs 24, 25 and the outer base webs 22. The support legs 51 are bent in a slightly rounded manner, which is made possible by cutouts 52 arranged in the outer base legs 24, 25 and adjacent to the side edges 23.

However, within the scope of the invention it is also possible to move the support legs 51 further forward so that they are at a distance from the front end of the base part 5.

The fourth embodiment according to Fig. 10 to 12, in which the same or comparable parts are designated with the same reference numerals, differs from the second embodiment according to Fig. 4 to 6 by a different shape or design of the flat spring arms 9 and the locking teeth 38a. Here too, the locking teeth 38a are arranged in the area of the side edges 17a, 23a, whereby they protrude laterally from the base web 14a or from the outer base webs 24, 25a, but the locking teeth 38a in this embodiment are each separated from the adjacent leg by a U-shaped cutout 53.

cut free. The U-shaped cutout 53 with its spaced-apart sections 53a preferably extends beyond the associated side edge 17a, 23a into the area of the wall carrying the associated locking tooth 38a, namely into the area of the outer base legs 24a, 25a, or into the area of the base web 14a. In addition, only one locking tooth 38a is provided on the respective side edge 17a, 23a, which is located in the middle area of this side edge.

Furthermore, in the embodiment according to Fig. 10 to 12, the flat spring arms 9 do not extend straight, but are bent in an arc shape, whereby the arc shape is convex.

Claims (34)

5730/V/ro CLAIMS 1. Insulation displacement contact element with preferably two insulation displacement bars, each with an insulation displacement slot for a cable with insulation, which are connected in one piece to a base part parallel to one another and at a distance from one another, wherein a further connection part for an electrical conductor, e.g. a crimp element or a plug contact element, in particular a flat contact spring, is connected in one piece to the insulation displacement contact element, characterized, that a strain relief bar (33) with a strain relief edge (34) is arranged in one piece on the insulation displacement contact element (1) at a distance next to the insulation displacement bar (6, 7) or on the outside next to both insulation displacement bars (6, 7). 2. Insulation displacement contact element according to claim 1,
characterized, that the distance between the strain relief edge (34) and the edge or slot foot area (29) of the associated insulation displacement slot (26, 27), which surrounds the cable (39) in the position inserted into the associated insulation displacement slot (26, 27), is less than the thickness of the insulation of the cable (39). 3. Insulation displacement contact element according to claim 1 or 2, characterized, that the strain relief edge (34) projects beyond the edge or slot foot area (29). 4. Insulation displacement contact element according to claim 3, characterized in that the strain relief web(s) (33) extend parallel to the insulation displacement webs (6, 7) and the strain relief edges (34) project beyond the slot base (29) of the associated insulation displacement slot (26, 27). 5. Insulation displacement contact element according to one or more of claims 1 to 4, characterized in that the strain relief web(s) (33) are integrally connected to the base part (5). 6. Insulation displacement contact element according to one or more of claims 1 to 5, characterized in that the insulation displacement webs (6, 7) are formed by base legs (18, 19; 18a, 19a) arranged parallel to one another and upright to form a flat base web (14, 14a). 7. Insulation displacement contact element according to claim 6, characterized in that the insulation displacement webs (6, 7) are rear extensions of the base legs (18, 19; 18a, 19a). 8. Insulation displacement contact element according to one or more of claims 1 to 7, characterized in that the strain relief web(s) (33) are each formed by a base leg (24, 25; 24a, 25a) extending parallel to the insulation displacement webs (6, 7) and standing upright to a flat base web (14, 14a). 9. Insulation displacement contact element according to claim 8, characterized in that the strain relief web(s) (33) are each a rear extension of the base legs (24, 25; 24a, 25a). 10. Insulation displacement contact element according to one or more of claims 6 to 9, characterized in that the base legs (24, 25; 24a, 25a) carrying or forming the strain relief webs (33) are offset outwards as outer base legs relative to the inner base legs (18, 19; 18a, 19a) forming or carrying the insulation displacement webs (6, 7). 11. Insulation displacement contact element according to one or more of claims 1 to 10, characterized in that the inner base legs (18, 19) forming or supporting the insulation displacement webs (6, 7) are connected to the side edges (17) of the flat base web (14) and are angled in a U-shape. 12. Insulation displacement contact element according to claim 11, characterized in that outer base webs (22) are connected to the side edges (21) of the inner base legs (18, 19) facing away from the flat base web (14) and are angled away from one another parallel to the central base web (14), to whose side edges (23) facing away from the inner base legs (18, 19) the outer base legs (24, 25) are connected and are angled at a distance parallel next to the inner base legs (18, 19). 13. Insulation displacement contact element according to one or more of claims 1 to 10, characterized in that the outer base legs (24a, 25a) forming or supporting the strain relief webs (33) are connected to the side edges (17a) of the flat base web (14a) and are angled in a U-shape. 14. Insulation displacement contact element according to claim 12, characterized in that outer base webs (22a) are integrally connected to the side edges (23a) of the outer base legs (24a, 25a) facing away from the central base web (14a). and are angled inwards parallel to the central base web (14a), to whose side edges (21a) facing away from the outer base legs (24a, 25a) the inner base legs (18a, 19a) are connected and are angled at right angles to the central base web (14a). 15. Insulation displacement contact element according to one or more of claims 1 to 14, characterized in that the side edges (17, 21) of the insulation displacement webs (6, 7) are slightly incised at their connection points (28) by preferably circularly rounded incisions (32). 16. Insulation displacement contact element according to one or more of claims 1 to 15, characterized in that the width of the insulation displacement webs (6, 7) behind their connection points (28) corresponds to the width of the inner base legs (18, 19; 18a, 19a) carrying them or of the base part (5). 17. Insulation displacement contact element according to one or more of claims 1 to 16, characterized in that sawtooth-shaped locking teeth (38, 38a) are arranged on the free side edges of the outer base legs (24, 25) and/or on the side edges (17a, 23a) opposite these side edges, which preferably face away from the insulation displacement webs (6, 7). 18. Insulation displacement contact element according to claim 17, characterized in that on each side edge (17a, 23a, 36) one or more locking teeth (38, 38a) are arranged one behind the other in the longitudinal direction of the edge. 19. Insulation displacement contact element according to claim 17 or 18, characterized in that the locking tooth (38a) is arranged in the front region of the associated side edge. 20. Quick-clamping contact element according to claim 17 or 18, characterized in that the locking tooth (38a) is arranged in the middle region of the associated side edge. 21. Insulation displacement contact element according to one or more of claims 17 to 20, characterized in that the locking teeth (38a) arranged on the non-free side edges (17a, 23a) are cut or cut free in the respectively adjacent angled leg or web parts (24a, 25a; 22a) and are bent out of these parts. 22. Insulation displacement contact element according to one or more of claims 17 to 21, characterized in that the locking teeth (38, 38a) are arranged on the outer base legs (24, 25) and/or on the outer side edges of the central base web (14a) and each extend in the plane thereof. 23. Cutting-clamp contact element according to one or more of claims 17 to 22, characterized in that the height of the locking teeth (38) lying one behind the other is greater in the forward-directed sequence from locking tooth to locking tooth. 24. Insulation displacement contact element according to one or more of claims 1 to 23, characterized in that the further connection part is connected to the end of the base part (5) facing away from the insulation displacement webs (6, 7) and points in the direction opposite to the insulation displacement webs (6, 7). 25. Insulation displacement contact element according to one or more of claims 1 to 24, characterized in that the contact flat spring (8) is connected with its two flat spring arms (9) to the ends of the outer base legs (24, 25; 24a, 25a) facing away from the insulation displacement webs (6, 7). 26. Insulation displacement contact element according to one or more of claims 1 to 24, characterized in that the contact flat spring (8) is connected with its two flat spring arms (9) to the ends of the inner base legs (18, 19; 18a, 19a) facing away from the insulation displacement webs (6, 7). 27. Insulation displacement contact element according to claim 26, characterized in that support legs (51) are connected to the front ends of the outer base legs (24a, 25a), which are bent towards one another and rest on the outer surfaces of the flat spring arms (9) of the contact flat springs (8). 28. Insulation displacement contact element according to claim 27, characterized in that the support legs (51) are bent at right angles. 29. Insulation displacement contact element according to claim 27 or 28, characterized in that the front edges of the support legs (51) resting on the flat spring arms (9) are arranged immediately in front of the connection points of the flat spring arms (9). 30. Insulation displacement contact element according to one or more of claims 24 to 29, characterized in that the contact flat spring (8) is arranged offset parallel to the insulation displacement slot plane (El) towards the central base web (14, 14a). 31. Insulation displacement contact element according to one or more of claims 25 to 29, characterized in that the flat spring arms (9) are connected centrally to the insulation displacement slot plane (El) and extend at least with a portion of their length obliquely to the side of the base part (5) on which the base web (14) is located. 32. Insulation displacement contact element according to claim 31, characterized characterized in that the flat spring arms (9) extend obliquely up to the vicinity of their contact point (11) and then extend straight with their free ends. 33. Insulation displacement contact element according to one or more of claims 24 to 32, characterized in that the flat spring arms (9) with convexly curved flanks or with straight extending flanks are bent convergently towards one another. 34. Insulation displacement contact element according to one or more of claims 24 to 33, characterized in that the flat spring arms (9) extend parallel to one another up to the vicinity of their contact point (11) and are then bent in.