EP0531664A2 - Cutting clamp sleeve contact - Google Patents

Abstract

The invention relates to an insulation displacement contact for contacting a cable wire transverse to the sleeve axis, in particular for cable wires in telecommunications, from a metallic sleeve jacket 12 with a clamping slot 3 for the insulated cable wire 5 and with an insulation piercing contact slot 2 inside the sleeve body 12 for Stripping-free connection of the cable core 5.

To improve the insulation displacement sleeve contact with regard to the independence of the contact slot 2 from movements at the clamping slot 3 and with regard to compliance with precise tolerances, the invention provides that a portion 13 of the sleeve shell 12 is radially bent into the interior of the sleeve body 12 and with the insulation displacement -Contact slot 2 is provided and that the insulation displacement contact slot 2 opposite slot 3 is cut into the sleeve jacket 15.

Description

The invention relates to a insulation displacement sleeve contact for contacting a cable core transverse to the sleeve axis, in particular for cable cores in telecommunications, from a metallic sleeve jacket with a clamping slot for the insulated cable core and with an insulation displacement contact slot inside the sleeve for stripping-free connection of the cable core and to a method for producing the insulation displacement contact.

An insulation displacement contact of the generic type is previously known from DE 37 09 376 C1. In this case, jacket pieces are cut out of the metallic sleeve jacket and bent into the interior of the sleeve as a contact leg to form the insulation displacement contact slot. The clamping slot for holding the insulated cable core is through the end edges of the round, oval or polygonal sleeve body formed at a short distance. The disadvantage here is that widening the clamping slot for the insulated cable wire also causes widening of the insulation displacement contact slot for stripping-free connection of the cable wire. This is particularly the case when the contact legs bent into the interior of the sleeve, which form the insulation displacement contact slot, are bent inwards from the region near the clamping slot, and also particularly when cable cores with a relatively thick insulating sleeve and small wire cross section are connected to the sleeve contact, whereby the thick insulating sleeve expands the clamping slot relatively large, which results in a corresponding widening of the insulation displacement contact slot, which may then no longer be able to contact the thin wire.

Furthermore, it has been shown that the known insulation displacement contact when bending the contact legs to one another and thus when forming the slot width of the insulation displacement contact slot had relatively large tolerances of the slot widths from sleeve contact to sleeve contact, so that it is practically impossible to produce the contact slot with acceptable tolerances .

The invention is therefore based on the object to improve an insulation displacement contact of the generic type in such a way that an influence on the insulation displacement contact slot is prevented by widening of the clamping slot and that the production of the contact slot with narrow tolerances is possible.

To achieve this object, the invention provides that a portion of the sleeve shell is bent radially into the interior of the sleeve and is provided with the insulation displacement contact slot and that the clamping slot opposite the insulation displacement contact slot is cut into the sleeve jacket. As a result, both the insulation displacement contact slot and the clamping slot are each formed by incisions in the sleeve jacket, as a result of which exact tolerances in the formation of the clamping slot and insulation displacement contact slot can be maintained. In addition, the insulation displacement contact slot is located on a section of the sleeve shell which is unaffected by a possible widening of the clamping slot.

Preferably, the insulation displacement sleeve contact is formed from a metal strip into which the clamping slot and the contact slot are cut before bending to the sleeve contact, in particular by stamping. A cutting point with a sharp edge can be punched out at the same time. Only in a second step is the final sleeve shape of the insulation displacement contact made by bending and rolling up. In this case, the section of the sleeve casing which receives the insulation displacement contact slot can be formed in an e-shaped embodiment as the end piece of the sleeve casing and can be bent radially into the interior of the sleeve. In another embodiment, the section receiving the insulation displacement contact slot forms a middle piece of the sleeve shell, the end pieces of the sleeve connecting the clamping slot and also the cutting point, which are connected to the middle section, are bent semicircularly and in opposite directions from the straight middle piece.

Further advantageous embodiments of the insulation displacement contact according to the invention result from the subclaims. The insulation displacement contact can be mounted alone on a printed circuit board or used in a wiring strip together with a contact of the same type or with completely different ones as connection or disconnection configurations will. The cable wires are simultaneously clamped in the clamping slot by means of a pressure movement, contacted in the insulation displacement contact slot and cut off at the sharp cutting point. The wiring can be done with a tool or by closing a housing cover of a housing in which the insulation displacement contact is inserted. This can also be called a round pipe contact. The sleeve contact is self-supporting and does not require a housing to support or clamp the cable wires and can, for example, be mounted directly on a circuit board. The clamping slot of the sleeve contact enables the cable core to be securely clamped without movements of the cable core having an effect on, or being transmitted to, the insulation displacement contact slot. The cable wires to be connected do not have to be cut to a certain length beforehand, but are cut off directly at the sleeve contact using a simple wiring tool without moving parts when wiring at the sharp cutting point. The sleeve contact enables reliable contacting of copper wires between 0.32 mm and 0.80 mm in diameter, which depends on the diameter of the sleeve contact. It is also possible to contact stranded wires. The position of the contact slot in relation to the cable core can be a forked or angular position with contact angles between 45 and 90 °.

Fig. 1

Eine Draufsicht auf einen e-förmigen Schneidklemm-Hülsenkontakt in der ersten Ausführungsform,

Fig. 2

die Abwicklung des den Hülsenmantel bildenden Metallstreifens des Schneidklemme-Hülsenkontaktes mit eingestanztem Kontaktschlitz, eingestanzter Schneidstelle und eingestanzter Klemmstelle,

Fig. 3 bis 12

verschiedene Ausführungsformen des e-förmigen Hülsenkontaktes und

Fig. 13 und 14

zwei Ausführungsformen eines S-förmigen Hülsenkontaktes.

The invention is explained in more detail below with the aid of several embodiments. Show it:

Fig. 1

A top view of an e-shaped insulation displacement contact in the first embodiment,

Fig. 2

the development of the metal strip forming the sleeve jacket of the insulation displacement contact with the stamped contact slot, stamped Cutting point and stamped clamping point,

3 to 12

different embodiments of the e-shaped sleeve contact and

13 and 14

two embodiments of an S-shaped sleeve contact.

The insulation displacement contact in the first embodiment according to FIGS. 1 and 2 consists of a flat metal strip 1 of an electrically conductive material, in which, according to FIG. 2, a contact slot 2 on the left and a clamping slot 3 on the right and a cutting point 4 in the middle by punching are introduced in one operation. The contact slot 2 has a certain width W, which depends on the core diameter of the cable wires 5 to be connected, and is provided with a V-shaped input area 6. The clamping point consists of a clamping slot 3 of width Z, which is regularly larger than the width W of the contact slot 2, and is also provided with a V-shaped input area 7. To form elastic spring tabs 8 on both sides of the clamping slot 3, a U-shaped free cut 9 is punched into the metal strip 1, the base 10 of which intersects at right angles at the inner end of the clamping slot 3 and its leg 11 parallel to the clamping slot 3 in the direction of whose input area 7 extend, as shown in Fig. 2.

As shown in FIG. 1, after the punching process according to FIG. 2, the metal strip 1 is bent or rolled into a sleeve body 12 which is round in cross section, a portion 13, which in FIG. 2 is shown by the dashed line 14 from the remaining sleeve jacket 15 is divided, is bent radially into the interior of the sleeve body 12, as shown in Fig. 1 is. The contact slot 2 lies in the center of the sleeve body 12 and is oriented at an angle α to the transverse axis 16 of the sleeve body 12. In the perpendicular axis 17 of the sleeve body 12, the clamping slot 3 and the cutting point 4 are arranged opposite this, as shown in Fig. 1. This embodiment of the insulation displacement contact forms an e-shape with an insulation displacement contact slot 2 oriented at an angle α obliquely to the axis 17 of the cable wire 5 to be connected, the cable wire 5 lying in the direction of the axis 17 (FIG. 1). In this embodiment, the section 13 receiving the contact slot 2 is not connected to the sleeve jacket 12 at the free end 18, as is shown in FIG. 1.

FIGS. 3 to 12 show embodiments modified from the e-shape shown in FIG. 1. Figures 3 and 4 show a pure fork contact, the portion 13 of the sleeve shell 12 is arranged exactly in the transverse axis 16, so that the contact slot 2 is parallel to the perpendicular axis 17, as shown in Fig. 3. The insulation displacement contact according to FIG. 4 corresponds to that shown in FIG. 3 and is only bent or rolled in the opposite direction.

The insulation displacement contact shown in FIG. 5 corresponds to that of FIG. 1, the angle α being specified as 70 °. The insulation displacement contact according to FIG. 6 corresponds to that of FIG. 5 and is only bent or rolled in the opposite direction.

The insulation displacement contacts shown in FIGS. 7 and 8 have an angle α of 45 °, at which the part 13 bent into the interior of the sleeve body 12 is bent relative to the axis 17 of the cable core 5.

In the insulation displacement sleeve contacts shown so far, the radial length of the section 13 corresponds to the inside diameter of the sleeve body 12. In the embodiments shown in FIGS. 9 and 10, the length of the section 13 'bent into the interior of the sleeve body 12 is longer than the inside diameter of the sleeve body 12, receptacles in the form of an opening 19 (FIG. 9) or in the form of a bulge 20 (FIG. 10) are provided for the lateral support of the radial section 13 '. In this, the radial section 13 'is supported laterally. In the embodiments according to FIGS. 11 and 12, the length of the radially inwardly curved section 13 in turn corresponds to the inside diameter of the sleeve body 12, with receptacles 18 again being provided for the section 13, which are designed in the form of inwardly curved tabs 21 which are cut out from the sleeve jacket 15 of the sleeve piece 12 in a U-shape.

In the embodiment according to FIGS. 13 and 14, the insulation displacement sleeve contact has an S shape in plan view, the portion 13 ″ of the sleeve shell 12 ″ that receives the contact slot 2 being the middle piece of the metal strip 1 ″ of the sleeve shell 12 '' forms. The jacket pieces 22, 23 of the sleeve body 12 ', which are arranged on both sides of the middle piece 13' 'and are integrally formed with the latter, are each semicircular and bent opposite to one another, so that these jacket pieces 22,23 form the actual sleeve body 12, which is traversed radially. Here, the center piece 13 ″ lies at a large angle α to the axis 3, in which the cable core 5 runs. The cutting point 4 is also diametrically opposite the clamping slot 3.

Claims (10)

Insulation displacement sleeve contact for contacting a cable wire transverse to the axis, in particular for cable wires in telecommunications, made of a metal sleeve jacket with a clamping slot for the insulated cable wire and with an insulation displacement contact slot in the interior of the sleeve body for stripping-free connection of the cable wire,

characterized,

that a section (13, 13 ', 13'') of the sleeve shell (15) in the interior of the sleeve body (12, 12', 12 '') is radially bent and provided with the insulation displacement contact slot (2) and that the Insulation displacement contact slot (2) opposite slot (3) is cut into the sleeve shell (12). Insulation displacement sleeve contact according to Claim 1, characterized in that the section (13) is an end piece of the sleeve shell (15) and in that the sleeve shell (15) is bent into an e-shaped sleeve body (12, 12 '). Insulation displacement sleeve contact according to claim 1, characterized in that the section (13 '') forms a central piece of the sleeve shell (15) and that the sleeve shell (15) is bent into an S-shaped sleeve body (12 ''). Insulation displacement sleeve contact according to one of Claims 1 to 3, characterized in that the radial length of the section (13, 13, 13 '') is equal to the inside diameter of the sleeve body (12, 12 ', 12' '). Insulation displacement sleeve contact according to one of Claims 1 to 3, characterized in that the radial length of the section (13 ') of the sleeve shell 15) is greater than the inside diameter of the sleeve body (12, 12', 12 '') and in a receptacle ( 18) is supported in the sleeve jacket (12). Insulation displacement sleeve contact according to one of Claims 1 to 3, characterized in that the radial length of the section (13 ') of the sleeve casing (15) is equal to the inside diameter of the sleeve body (12, 12', 12 '') and that the section ( 13) is supported on a cut-out, inwardly bent tab (21) of the sleeve shell (12 '). Insulation displacement sleeve contact according to one of the preceding claims, characterized in that the sleeve casing (12) is bent to form an S-shaped sleeve body (12 '') and that the middle section (13 '') is straight and the radial section is for receiving of the insulation displacement contact slot (2) and that the two adjoining jacket pieces 22, 23) form the curved sleeve jacket (12 ''). Insulation displacement sleeve contact according to one of the preceding claims, that the area of the sleeve jacket (12) opposite the clamping slot (3) forms a sharpened cutting point (4) for cutting the cable core (5) to length. Insulation displacement sleeve contact according to one of the preceding claims, characterized in that the clamping slot (3) is surrounded by a free cut (9) in an inverted U-shape whose base (10) intersects the clamping slot (3) vertically and whose legs (11) are directed parallel to the clamping slot (3) in the direction of its entrance area (7). A process for producing an insulation displacement contact according to one of claims 1 to 12 from a metal strip, characterized in that the insulation displacement contact slot (2) and the clamping slot (3) are cut, in particular punched, in the metal strip (1) and that Metal strip (1) in e- or S-shape is bent into a sleeve body (12, 12 ', 12' '), the portion (13, 13', 13 '') receiving the insulation displacement contact slot (2) being radially in Is arranged inside the sleeve body (12).

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