DE3912955C2 - - Google Patents

Description

The invention relates to a in a chamber of a Kunststoffge house to be arranged, from a flat sheet metal stamping curved electrical contact element using insulation displacement technology an electrical cable connector, with a fork spring between their fork spring legs an insertion slot for the insulation displacement contact of an electrical cable defines whose electrical conductor is insulated is surrounded, the two fork spring legs of the fork spring in the area of this insertion slot in a common Level.

Electrical contact elements in the so-called insulation displacement technology for electrical cable connectors are known. They are punched out of a sheet and according to the given shape bent. An elec manufactured in this way trical contact element is then in a corresponding Chamber of a plastic housing of the cable connector arranged, after which the corresponding electrical cable on the electrical contact element in insulation displacement contact is tiert. For this purpose, the electrical contact has ment at least one fork spring, one between them Insertion slot defined, the facing Kan ten of the two fork spring legs are sharpened. To do that To contact electrical cables, this is in the insertion slot of the fork spring inserted so that the cutting of the the fork insulation in both fork spring legs  zen that they with the electrical conductor in electrical con clock. The two fork spring legs practice one Clamping force on the electrical conductor, so that this in the insertion slot is held.

Since in the known electrical contact element, the Gabelfe the leg of the fork spring by punching out a slot are formed, the spring travel of the two legs is due the small effective spring length is low. So since the two Only slightly deflect the fork spring leg from its position Chen and thus the width of the insertion slot only in can be enlarged to a small extent, thereby introducing the difficult to contact electrical cable. this applies especially if the same type of elec trical contact element electrical cables are contacted should have different conductor diameters. In addition comes that the two fork spring legs because of their gerin contact pressure, especially on a strand bundle if the internal stability of the Strand bundle and since the contact pressure of the fork spring legs too small due to material fatigue (relaxation) over time will be poorly maintained. Overall is thus in the known electrical contact elements Insulation displacement contact of the electrical conductors poor. Finally, the width of the known contact elements of the insertion slot is not caused by the punching tools scalable to any size.

For example, DE-AS 12 57 921 is an electrical one Contact element in the so-called insulation displacement technology as Connector known for thin, insulated electrical cables. This known contact element is made of sheet metal punched out and according to the given shape into one "U" bent. An electrical contact element produced in this way is then in the corresponding chamber of an art  used material housing, the corresponding electrical cable to the electrical contact element in the Insulation displacement technology for their electrical connection be contacted. For this purpose, the known electrical contact element a total of four fork springs that are each formed by two fork spring legs that define an insertion slot between each. The mutually facing edges of the fork spring legs are preferably sharpened. When inserting the fork spring legs the fork spring of the electrical contact element in the housing cuts the blades of the fork spring legs Cable insulation so that it with the electrical The conductors come into electrical contact. The two fork spring legs exercise a clamping force on the respective electrical conductor, so that this in the insertion slot is held.

In this known contact element, it is disadvantageous that the travel of the legs due to the low effective Spring length is small. Because the fork spring legs only can dodge slightly from their position and thus the Width of the insertion slot can only be increased to a small extent is the introduction of the to be contacted electrical cable difficult. This is especially true when if with one and the same type of electrical contact element electrical cables to be contacted have different conductor diameters. In addition, the Fork spring legs due to their low travel Contact pressure especially on a strand of strands for longer ones Time decreasing internal stability of the strand bundle and there the contact pressure of the fork spring legs due to material fatigue (Relaxation) becomes too small with time, poorly maintained can be. Overall, the known electrical contact element the insulation displacement contact  electrical conductor bad. After all, with the known contact elements the width of each The insertion slot is not caused by the punching tools scalable to any size.

It is also from DE-AS 16 65 982 a solderless terminal known, punched out of a flat sheet metal strip is, so that three mutually parallel jaws in the form of Fork spring legs are formed, the two fork springs define the middle jaw to both Heard fork springs. The front ends of the jaws are bent backwards. Because also with this terminal only small spring lengths of the fork spring legs are effective, is also the insulation displacement contact of the electrical Head bad.

Finally, from DE-AS 16 40 637 is an electrical Clamp connection between an insulated wire and a Connection element known. The connection element consists of a flat stamped sheet metal part, which at its front end a fork spring formed by two fork spring legs Are defined. There is a between the two fork spring legs Insertion slot for the electrical cable defined, with the Insert this cable into the insertion slot of the insulation is incised by the fork spring legs so that the electrical contact is established. To do so in the Securing fork spring contacted cables is also an additional option a slider, which also has fork springs with a insertion slot defined between the fork spring legs having. The slide is essentially a C-profile formed, with extensions in the region of the opening of the "C" form the fork springs. Even with this electrical clamp connection is the insulation displacement contact of the electrical Conductor bad because the effective spring length is only small.

Based on this prior art, the invention lies Task based, for example, from DE-AS 12th 57 921 known electrical contact element in insulation displacement technology an electrical cable connector to develop further that the insulation displacement contact of the electrical cable is improved.

The invention proposes as a technical solution that the one fork spring leg of the fork spring regarding the other fork spring leg of this fork spring starting from the flat sheet metal stamped part by 180 ° in the area the bending edge to form the fork spring in its given position is bent.

The bending edge can be vertical or parallel run to the longitudinal extent of the insertion slot.

Finally, the two fork spring legs are preferably located the fork spring in the area of the insertion defined by it slot in a common plane.

An electrical trained according to this technical teaching Contact element in insulation displacement technology of an electrical Ka Belsteckverbindung has the advantage that in terms of known fork springs with increased clamping force the travel is enlarged, so that the insulation displacement contact of the electrical cable is improved. This is it establishes that the two fork spring legs in the area of Ba are folded and lie there against each other, so that the effective spring length is increased. This is the lever arm of the spring extended accordingly, so that larger Deflections and thus longer spring travel are possible. There there beyond the clamping force u. a. by the width of the base of the respective fork spring leg is given and by  the formation of a bending edge from which the two fork spring legs run out, this base compared to the be Known fork springs is enlarged, this results in a greater clamping force, so that overall through the interaction between clamping force and effective spring length or the result thereof resulting travel the insulation displacement contact of the electrical cable is improved. In addition, the slot wide with preload practically going to zero too to contact even thinnest cables.

According to the first embodiment, the bending edge runs vertically right to the longitudinal extent of the insertion slot, so forms the Bend the base of the two fork spring legs with one greatest possible spring length. However, with this version approximately disadvantageous that the bending edge in the rolling direction of the Sheet metal stamping runs, which leads to an increased breakage or Risk of cracking. Instead, in a second out the parallel course of the bending edge to the longitudinal Extension of the insertion slot proposed, so that here Bending edge runs laterally. By aligning the bie edge runs perpendicular to the rolling direction of the sheet stamped part, so that there is an increased risk of breakage or cracking the bending edge is avoided.  

The training, in which the two fork spring legs in Area of the insertion slot in a common plane lie, has the advantage that optimal Schneidklemmver relationships are created. For this purpose the one Fork spring leg by a corresponding bending process in its level so that it is in the level of the other ren fork spring leg lies.

The electrical contact element according to the invention in cutting technology of an electrical cable connector below with reference to the drawings in two embodiments play described. In the drawings shows

Figure 1 is a perspective view of a first embodiment of an electrical contact element.

FIG. 2 shows a partial section of the contact element in FIG. 1 in the region of the bending edge of the two fork spring legs;

Fig. 3 shows the electrical contact element of Figure 1 as a flat sheet metal stamping before bending, the bending edges are shown in dashed lines Darge.

Fig. 4 is the electrical contact element of Figure 1, but with the contacted cable.

Fig. 5 is a schematic representation of a Gabelfe in an electrical contact element from the prior art;

Fig. 6 is a corresponding schematic representation of the fork spring of the electrical Kontaktele element in Figures 1 to 4.

Fig. 7 is a perspective view of a second embodiment of an electrical contact element;

FIG. 8 shows a detail from the end view of the electrical contact element in FIG. 7;

FIG. 9 shows the electrical contact element from FIG. 7 as a flat sheet metal stamping before bending, the bending edges being shown in broken lines in Darge;

Fig. 10 shows the electrical contact element from Fig. 7, but with contacted cable.

In Figs. 1 to 4, a first embodiment is shown of an elec trical contact element in an elec trical insulation displacement plug-in cable connection and in FIGS. 7 to 10 a second embodiment. Referring to Figs. 5 and 6, the particular characteristics of the electrical contact elements of the first embodiment will be explained.

Both the electrical contact element of the first embodiment and the electrical contact element of the second embodiment each consist of a stamped sheet metal part 1 , as shown in Fig. 3 and in Fig. 9, with this flat stamped sheet metal part 1, the contact element by successive bending processes is bent. The corresponding bending lines 2 are shown in dashed lines. Correspondingly, both embodiments continue to consist of spring tongues 3 , between which, for example, the contact pin of a plug of the electrical connector for electrical contact can be inserted. These spring tongues 3 are formed in a conventional manner.

In order to be able to contact an electrical cable 4 in the so-called insulation displacement technique on the electrical contact element, both embodiments each have two fork springs 5 . Each of these fork springs 5 consists of two fork spring legs 5 ', 5 '', which define an insertion slot 6 between them for the electrical cable 4 . The fork springs 5 are formed in a special way in the arrangement of the fork spring legs 5 ', 5 ''to each other.

In the to 6 shown first in Figs. 1 execution form the two fork spring legs 5 ', 5' 'from the flat stamped sheet metal part 1 are bent such that the Gabelfe of the legs 5', 5 '' about a bending edge 7 by 180 ° in such a way are folded that the two fork spring legs 5 ', 5 ''lie flat against each other in the region of this bending edge 7 . The bending edge 7 extends at the base of the fork spring 5 perpendicular to the longitudinal extent of the insertion slot 6 . One Gabelfe derschenkel 5 '' is slightly offset in its plane of art bent that both fork spring legs 5 ', 5 ''lie in the area of the insertion slot 6 in a common plane, as can be seen in particular in Fig. 2.

To contact the electrical cable 4 , this is inserted into the insertion slot 6 from above, as can be seen in FIG. 4. Since the mutually facing edges of the two fork spring legs 5 ', 5 ''are sharpened, the fork spring legs 5 ', 5 '' cut into the insulation 8 of the cable 4 until the fork spring legs 5 ', 5 ''on the electrical conductor 9th come to the plant and thus establish the electrical contact.

The special properties of the electrical contact element designed in this way are explained below with reference to FIGS. 5 and 6:

In Fig. 5, a conventional fork spring 10 is Darge, the two fork spring legs 5 ', 5 ''define a guide slot 6 . The effective spring length 1 is predetermined by the deepest point of the insertion slot 6 . This effective spring length 1 defines the spring travel f of the fork spring legs 5 ', 5 '', the greatest possible deflection being indicated by dashed lines.

The clamping force F is defined, inter alia, by the width h _{o of} the base of the fork spring leg 5 'or 5 ''.

In Fig. 6, the corresponding physical quantities are shown in the electrical contact element according to the invention. Since the two fork spring legs 5 ', 5 ''extend from the bending edge 7 , this is also the effective spring length 1 ' be true. With fork legs of equal length 5 ', 5 ''results in comparison to the fork spring in Fig. 5, a ver larger effective spring length 1 ', which results in a correspondingly larger ver spring travel f '. Here, too, the maximum male evasive movement of the fork spring legs 5 'or 5 ''is indicated by dashed lines.

In addition, since the bending edge 7 defines the base width h _o 'of the two fork spring legs 5 ', 5 '' and this base width h _o 'is approximately twice as large as the base width h _o in the fork spring in Fig. 5, increases ent speaking clamping force F '. Due to the thus increased spring away f 'and the increased clamping force F' the insulation displacement contact of the electrical cable 4 is improved with respect to the known fork spring from FIG .

The embodiment in FIGS. 7 to 10 differs from the previously described embodiment only in the arrangement of the bending edge 7 . While this is approximately perpendicular to the longitudinal extent of the insertion slot 6 in the first embodiment, in this embodiment it is parallel to the longitudinal extent of the insertion slot 6 , that is to say laterally to the latter. This has the advantage that - as can be seen in Fig. 9 - all bending lines 2 run parallel to each other and thus all bends can be carried out transversely to the rolling direction of the sheet metal stamped part 1 , which reduces the risk of breakage or cracking. Otherwise, the spring length and thus the spring travel is also increased in this embodiment. In addition, the extended base width, which corresponds to the length of the bending edge, results in an increased clamping force, so that here, too, the insulation displacement contacting of the cable is improved with respect to the known fork spring.

Claims (3)

1. In a chamber of a plastic housing to be arranged, from a flat sheet metal stamped part ( 1 ) bent electrical contact element in insulation displacement technology an electrical cable connector, with a fork spring ( 5 ) between its fork spring legs ( 5 ', 5 '') an insertion slot ( 6 ) for the insulation displacement contact of an electrical cable ( 4 ), the electrical conductor ( 9 ) of which is surrounded by insulation ( 8 ), the two fork spring legs ( 5 ', 5 '') of the fork spring ( 5 ) in the area of this A guide slot ( 6 ) lie in a common plane, characterized in that one fork spring leg ( 5 ') of the fork spring ( 5 ) be relative to the other fork spring leg ( 5 '') of this fork spring ( 5 ) starting from the flat sheet metal stamped part ( 1 ) by 180 ° by one in Area of the base lying bending edge ( 7 ) to form the fork spring ( 5 ) is bent into its predetermined position. 2. Electrical contact element according to claim 1, characterized in that the bending edge ( 7 ) extends perpendicular to the longitudinal extension of the insertion slot ( 6 ). 3. Electrical contact element according to claim 1, characterized in that the bending edge ( 7 ) extends parallel to the longitudinal extension of the insertion slot ( 6 ).