DE1219109B - Branch terminal for connecting individual insulated wires of a multi-conductor cable with insulated branch conductors - Google Patents

Description

Branch terminal for connecting individual insulated wires of a multi-conductor cable with insulated branch conductors Addition to the additional patent: 1195 386 The invention relates on a branch terminal for connecting individual insulated wires of a multi-conductor cable with stripped branch conductors by means of contact pieces that can be pressed onto the wires, the teeth for piercing the core insulation and means for connecting to the branch conductor exhibit.

A branch terminal of this type is proposed in patent 1195 386, in which the contact pieces are designed as segments of a sleeve surrounding the cable and can be pressed on by means of shells which can be connected to one another without pressing to form an outer sleeve, with insulating material wedges that can be driven in between the wires.

These insulating wedges have smooth wedge surfaces that are used in sheaths the cores made of a material with insufficient compressive strength, e.g. plastic, can not prevent when compressing the clamp and later, in particular as a result of the cable heating up, a shift between the wedge and the sheath or sheath flow away occurs. These pressure reliefs can do so become large that the entire terminal is loose and the contact between the wires and the branch conductors go bad. This condition cannot be remedied afterwards because when the clamp is attached, the shells are closed until a closed one is formed Sleeve are compressed.

The invention is based on the object of providing branch terminals of this type to be improved so that even cables with plastic core sheaths are loosened the clamp cannot occur. According to the invention, this object is achieved by that the insulating wedges have teeth on their surfaces facing the adjacent cores have, the height of which is at least equal to the thickness of the core sheaths.

These teeth penetrate the casing and are directly supported on the wires of the veins. The pressure to be absorbed by the insulation wedges is thus transmitted through their teeth and not through the cable sheathing, their Pressure resistance is therefore irrelevant for a consistently tight fit of the clamp is. It does not matter whether the outer sleeve of the clamp is detachable or non-detachable consists of interconnected shells.

The teeth of the insulating wedges are advantageous in the driving direction of the wedges arranged to run. As a result, the teeth are essentially vertical to the axes of the wires forming the veins, so that they are supported on the veins, without penetrating into them.

To prevent the wedges as a result of the relatively small Friction between the tooth tips and the wires of the veins pressed radially outwards which would also loosen the clamp, they can in profile the greatest width at a distance from that opposite to the tip of the wedge Have wedge end. In such a training occurs only in the one between the largest Width and the wedge tip lying part of the wedge is a radially outwardly directed Force component, while in the remaining part of the wedge an oppositely directed Force component is present.

The invention is explained in detail in the following description using an exemplary embodiment shown in the drawing. It shows F i g. 1 shows an end view of an embodiment of a branch terminal according to the invention in the loose state, the cable being shown in section, FIG. 2 shows an end view of the exemplary embodiment according to FIG. 1 in the state pressed onto a multi-conductor cable, FIG. 3 shows a side view of an insulating wedge, FIG. 4 shows a section through an insulating wedge along the line IV-IV of FIG. 3, fig. 5 is a view of the profile of an insulating wedge according to FIGS. 3 and 4. The junction terminal shown in the drawing for connecting the wires 1 of a three-wire cable with branch conductors 2, each provided with a sheath 10 made of plastic, has three contact pieces, which are designed as identically designed segments 3 of an imaginary sleeve encompassing the cable. On the inner surface of the segments facing the cable, teeth 4 are provided for piercing the sheathing 10 of the cores 1 and a recess 5 each for inserting the associated branch conductor 2.

With the interposition of an insulating layer 6, each segment 3 is with a shell 7, which can be assembled to form an outer sleeve. The same = shaped shells 7 are dimensioned so that the mutually facing Areas 7 'of adjacent shells 7 before the segments 3 are pressed against the veins 1 stand at a distance from each other (FIG. 1) and rest against each other after pressing (Fig. 2).

Connecting screws 8 are arranged in holes in the shells 7, by means of which the terminal in the FIG. 2 shown state in which the teeth 4 of the segments 3 are pressed into the wires 1, can be held.

Furthermore belong to the branch terminal shown between the Cores 1 drive-in insulating wedges 11 made of durable, duroplastic Plastic or hard paper, the surfaces resting on the veins 1 on their surfaces Have teeth 12, the height of which is greater than the thickness of the sheaths 10 of the Cores 1. These teeth 12 are arranged to run in the driving direction of the wedges 11. As the F i g. 1, 2 and 5 show the insulating wedges 11 in profile largest width not at the wedge end 14 opposite the wedge tip 13, but near the chisel tip 13.

When a branch connection is made, the insulating material wedges 11 are first driven in between the wires 1 and the clamp is placed around the cable (FIG. 1). The pressure exerted by the wedges 11 on the casing 111 is generally not so great that the teeth 12 pierce the casing. If, however, the shells 7 are pressed together by means of a pressing tool until the surfaces 7 'are in contact with one another, not only the teeth 4 of the segments 3, but also the teeth 12 of the insulating wedges 11 pierce the sheathing 10 of the wires 1 (F i g . 2). In this state, the clamp is held by tightening the connecting screws 8.

The insulating wedges 11 are therefore supported, as is also the case with FIG. 2 shows immediately on the wires of the veins 1, so that the segments 3 on the Cores 1 exerted pressure is absorbed directly by the insulating wedges 11. A deflection of the Isolierstöffkeile radially outward as a result of this pressure is thereby preventing the greatest width of the wedge profile in the vicinity of the wedge tip 13 is provided. The pressure prevailing in the sleeve after the pressing process can therefore do not decrease, even if the sheathing 10 of the wires 1 from a Plastic with low compressive strength is made.

Claims (3)

Claims: 1: Junction clamp for connecting individual insulated wires of a multi-conductor cable with stripped branch conductors by means of contact pieces which can be pressed onto the wires and which have parts for piercing the wire insulation as well as means for connecting to the branch conductor and in which the contact pieces are designed as segments of a sleeve encompassing the cable , in which teeth are provided on the inner surface of the segments facing the cable for piercing the insulation, in which the outer surfaces of the segments are insulated and in which the segments can be pressed by means of shells which can be connected to one another to form an outer sleeve without pressing, with between the Insulating wedge inserts are provided for veins, according to patent 1195 386, characterized in that the wedges (11) have teeth (12) on their surfaces facing the adjacent veins (1), the height of which is at least equal to the thickness of the wire sheaths (10) . 2. Branch clamp according to claim 1, characterized in that the teeth (12) in the driving direction the insulating wedges (11) are arranged to run. 3. Branch terminal according to claim 1 or 2, characterized in that the insulating wedges (11) in their profile greatest width between the tip of the wedge (13) and the opposite end of the wedge (14) exhibit.