The present invention relates to a connector that includes a first body that includes a first body having a through- passing channel for at least one cable, and a second body that includes a recess which is dimensioned to receive the first body and a cable end-part that is folded back against the mantle surface of the first body.

Connectors of this kind are known from U.S. 1,458,247 for instance. A connector of this kind can be used either to enclose and electrically insulate conductor end-parts of an electric cable that have been stripped of their insulation, or to establish mutual electrical connection of several conductor end-parts.

In the known technique, the end-parts are clamped between two matching conical surfaces of which one is in screw coaction with a central screw. In order to insulate the connector, it is necessary to encase the connector in an electrically insulating cover.

Connectors of this known kind have many drawbacks. One drawback can be said to lie in the dependency of conductor attachment in the intrinsic elasticity of the conductor. Another drawback is that a pressure joint is required between the elements that fasten the end of the conductor. It is also impossible to seal the cable transit through the first body in a simple manner. Furthermore, there is no simple way in which the stripped end-part can be sealed within the connector.

Accordingly, one object of the invention is to provide a connector which will enable the conductor to be fastened in a simple fashion and to enable different sized conductors or a

plurality of conductors to be fastened in the absence of a screw joint.

A further object is to provide a connector which enables the stripped end-parts of the cable/cables to be tightly enclosed within the connector.

These objects are achieved totally or partially with a connector according to the following main Claim.

Further embodiments of the inventive connector are set forth in the dependent Claims .

The inventive connector comprises basically a first tubular body and a second cupped body that is intended to embrace the first body generally coaxially. One end section of the cable can be fitted through the first tubular body and the stripped conductor section of the cable then folded back against the outer surface of the first tubular body. The cupped second body can now be pushed axially over the tubular first body and the bare conductor end-parts resting thereon, so as to clamp the bare conductor end-parts between the outer mantle surface of the first body and the inner mantle surface of the second body. The first tubular body is constructed so as to be subjected to radial elastic compression when the effective outer diameter of the tubular first body and the conductor end-parts are larger than the effective inner diameter of the second body, therewith ensuring effective clamping of the conductor end-part between said two bodies even when the bare conductor end-part has a varying diameter/effective thickness, and even when the number of conductors to be connected between the two connector bodies vary in number.

According to one favourable embodiment of the invention, the tubular first body may include transit channels that are adapted closely to the outer diameter of the insulated cable

part, such that as the second body is pushed over the first body said first body will be compressed radially and therewith bring the walls of the transit channel into sealing contact with the outer peripheral surface of the cable. The transits through the first body will therewith be completely sealed.

In another preferred embodiment, the second body is constructed so that its edge region will come into contact around the whole of its periphery with a peripheral region of the tubular first body, so as to tightly shield the stripped end-section of the cable from the surroundings. This sealed enclosure is effective in reducing oxidation of the contact surfaces between conductor end-parts and/or contact tabs against which said end-parts lie.

The cable insulation can be brought into sealing contact with the wall of the cable transit as a result of radial compression of the first body by said second body as said second body is fitted onto the first body. Alternatively, the inner end of the first body may be provided with a diametrical slit that intersects the cable transit and divides the inner end-part into tongues that bend towards one another and towards an insulated cable section when fitting the second body. These tongues exert a displacing force onto the cable insulation such that said insulation will tend to flow along the cable and the cable transit in a direction towards the rear or distal end of the first body, such as to cause the cable, or more specifically the cable insulation, to swell at or in that part of the cable that lies adjacent the bottom of the slit.

The tongues formed by slitting the inner end of the first body may be configured so that the tongues and the clamped cables together will assume a preferably circular cross- sectional shape that corresponds to the cross-sectional shape

of the associated part of the second body as the tongues and cables are inserted therein.

The second body may typically include on its inner wall surface a peripheral part of an electrically conductive material that provides a bridge between several stripped conductor end-parts located in the peripheral gap between the first and the second bodies. According to one embodiment, the second body may have an outer surface that is at least partially comprised of electrically conductive material and that is in conductive connection with the conductors located within the connector, such that the second body in principle forms a male plug on the end of the cable concerned, wherein the male plug may be adapted to be plugged into a corresponding female socket. Naturally, the second body may alternatively form a female socket connected electrically conductively to the conductor end-parts in the connector.

Cable tension is relieved effectively by virtue of the stripped conductor end-sections being folded back through 180 degrees and therewith may be bent over 90 degree edges.

In the case of certain embodiments of the invention, particularly when the conductors are multi-wire conductors, it may be appropriate to first twist together the stripped conductor-ends to form a single twisted conductor end-part. This conductor end-part is cut to a suitable length and placed in an axially extending recess on the outer mantle surface of the tubular body. The electrical connection between the conductors is favoured by twisting the conductor- ends together and also by bending the twisted cable end. The groove intended to receive the twisted conductors may be dimensioned to accommodate the number of conductors concerned, particularly when each cable passes through a size-adapted transit in the first body and then clamped

tightly therein when the second body is pushed over the first body.

The tubular first body will preferably have at its cable receiving end a radially and outwardly projecting peripheral flange or lip, and the inner surface of the cupped second body will have on its edge-part a formation that corresponds to said flange or lip and that enables the first and the second body to connect tightly therearound. The connection will preferably have the form of a non-releasable snap connection. The first body may be produced from an elastomeric material, whereas the second body may be much more rigid than the first body and may be produced from a rigid plastic material.

The material from which the bodies are made, however, is of lesser importance than the desired function, and it will be evident to the skilled person that an electrically conductive peripheral part may be provided either on the outside of the first body or on the inside of the second body such as to mutually connect electrically the conductors in the connector.

The invention will now be described in more detail with reference to exemplifying embodiments thereof and also with reference to the accompanying drawings .

Fig. 1 is a schematic axial section view of an inventive connector.

Fig. 2 is a sectional view taken on the line II-II in Fig. 1.

Fig. 3 is a schematic axial section view of another embodiment of an inventive connector.

Fig. 4 is an end view of one component body of an inventive connector, in a modified version of the embodiment illustrated in Fig. 3.

Fig. 5 is an axial section view of the tubular inner part of an inventive connector.

Fig. 6 is a sectional view taken on the line A-A in Fig. 5.

Figs. 7-9 illustrate variants of the Fig. 6 construction.

Fig. 10 illustrates another embodiment of the inner first part of the connector system.

Fig. 11 illustrates a modification to the inner part shown in Fig. 10.

Fig. 12 is a sectional view taken on the line A-A in Fig. 11.

Fig. 13 is a sectional view according to Fig. 12 and shows the inner part compressed by the outer second part of said connector.

Figs. 1 and 2 illustrate a connector that includes a generally tubular first body 1 that has a through-passing opening 2. The body 1 has at one end a peripheral flange or lip 3 provided with a bevelled edge .

The connector also includes a cupped second body 10 that has an inner wall 11 which surrounds the outer mantle wall 5 of the first body 1. Also shown in a cable 20 that includes a conductor 21 having a stripped end-part 23. The cable 20 extends through the opening or transit 2, wherewith the end- section 23 of said conductor is bent around the mantle wall 5. The body 10 is pushed axially over the body 1 and the bent

end-part 23 such as to clamp the end-part 23 radially between the surfaces 5 and 11.

Provided on the inner surface of the free edge-part 12 of the body 10 is a peripherally extending recess 14 which receives the bevelled edge 4 of the ring flange 3. The body 10 can be considered as an essentially rigid body, whereas the body can be considered as being elastically deformable in a radial direction. The body 1 is dimensioned so that conductors 21 of typical sizes will be clamped between the wall surfaces 5 and 11 when the body 10 is fitted over the body 1. The recess 14 is preferably adapted to provide a snap joint in coaction with the bevelled surface 4 when the body 10 is fitted over the body 1, said snap joint preferably being adapted to provide a seal between the edge-part 12 and the flange 3 around its periphery. The joint will also preferably include angles in a known manner, that make opening of the joint difficult to achieve.

The perimeter of the body 1 may include one or more axially extending conductor-receiving grooves or recesses 6, said grooves functioning to distribute engagement deformation of the body 1 around its periphery.

The second body 10 may include a ring of electrically conductive material on its inner cylindrical surface, for contact with the bent end-parts 23 of the conductors 21. Alternatively, that edge-part of the body 1 that lies in contact with the end-parts 23 may be made electrically conductive so as to mutually connect several cables 22 mounted in the connector shown in Fig. 1.

Naturally, the whole of the body 10 may be comprised of an electrically conductive material when the body 10 is to form an electric plug.

The skilled person will also realize that the body 10 may carry an electric plug and that the plug may be connected electrically with the conductors 21 within the connector in a conventional manner.

The opening 2 of the body 1 in Figs. 1 and 2 is shown to be much larger than the cable 20.

In the Fig. 3 embodiment, the body 1 includes an opening or transit 2 for each cable 20 to be connected to the connector.

The dimensions of the opening/transit 2 are closely adapted to the size of the cable 20, and the body 1 includes a part 8 that is intended for powerful coaction with a corresponding peripheral part on the mantle wall of the body 10, such as to generate radial compression of the body 1 so that said body is compressed and respective transit walls are brought into tight abutment around respective cables in this region when said body 10 is mounted properly on the body 1. The body 1 of the Fig. 3 embodiment is also dimensioned to establish elastic clamping of the end-part 23.

Fig. 4 illustrates an embodiment having a body 1 that corresponds essentially to the body of the Fig. 3 embodiment but with the difference that the openings 2 open out into a radial channel 9 on the inner short end of the body 1. The conductor end-parts 23, particularly in the case of multi- wire conductors, can be twisted together and then laid into the groove 9 and thereafter laid down in the axially extending outer groove 6 on the outer mantle surface 5 of the body 1.

In the Fig. 3 embodiment, the body 10 has internally a conductor sleeve 14 that enables the conductors 21 of cables 2 to be mutually connected electrically even when the

conductors are mutually spaced around the perimeter of the body 1.

Fig. 5 illustrates a further development of the body 1. Thus, Figs. 5 and 6 illustrate a body 1 that has a single through- passing channel which receives the insulated end-parts of the cables 20 in an inlet part of the channel. The channel 2 has a cross-sectional shape that corresponds to the resultant outer contours of the tightly combined cables 20. The channel 2 will preferably have a slightly larger cross-section at the insertion end of the body 1 than the resultant cross-section of the tightly compressed cables 20, although the channel will preferably decrease in size in a direction towards the outlet end of the channel 2.

The outlet end of the channel has a cross-sectional shape (preferably a circular shape) and a cross-sectional size that is adapted so as to enable the stripped conductor end-parts 21 of the cables to pass through said channel part 17 after being twisted together, while preventing the insulated cables from passing through said opening 17.

The opening 17 is conveniently centred with respect to the common cross-section of the combined cables (the cross- section of that part of the channel 2 which receives the insulated cables 20) .

When connecting two or more cables 20 to a body adapted thereto, the ends of the cables are stripped and the conductor end-parts 21 twisted together, whereafter the twisted conductor line 25 is threaded through the channel 2 and through its outlet opening 17, wherewith a pulling force is preferably applied to the twisted conductor line so that the cables will be drawn into the channel while being sealingly clamped against one another and against the channel wall 2. The conductor line 25 is then bent and laid into a

groove 6 when such a groove is provided on the outer mantle surface of the body 1, prior to fitting the second body 10 and bringing said body into tight engagement against the edge flange 3 of the body 1.

The body 1 of the embodiment illustrated in Figs. 5 and 6 is also elastically deformable under the influence of the body 1, said body 1 being pressed into abutment around the total perimeter of the cables 20 such that adjacent cables 20 will seal against each other and together sealingly shield the channel 2.

Figs. 7, 8 and 9 are sectional views taken on the line A-A and illustrate schematically the cross-sectional shapes of the channel 2 for bodies 1 that are adapted to accommodate different numbers of cables 20. A particular advantage afforded by the embodiment according to Figs. 5-9 is that the conductors 21 obtain an effective electric connection in longer time perspectives, as a result of twisting the conductors together, bending the twisted conductors and optionally subjecting the twisted conductor line to a pulling force.

Figs. 10-12 illustrate an alternative embodiment and the first part 5, wherein Figs. 12 and 13 illustrate the part 5 with cables 20 inserted in the channel 2.

As will be seen from Figs. 10-12, the upper part 51 of the first part 5 includes a diametric slot 30 which divides the part 51 into two tongues 52, 53 which clamp the cables 20 therebetween when the outer second body 10 is fitted, by virtue of the fact that the inner cross-section of the body 10 at the bottom is smaller than the non-loaded outer cross- section of the part 5 at the top.

The cable insulation 22 is caused to flow when the tongues 52, 53 are bent towards one another as a result of the wedge effect that is generated between the parts 5, 10.

Because the tongues have a natural tendency to stretch at the bottom 31 of the slot, the insulation will flow from the region between the tongues in a direction towards the rear end of the first part, therewith causing the cable insulation to "swell" at or in the transition between the slotted part and the non-slotted part of the channel, this swelling 33 generating an effective seal between the perimeter wall of the imperforate channel-part and the cable/cables with the cables effectively sealing against one another at the same time.

The tongues 52, 53 will preferably be made of a material that is much stiffer than the cable insulation 22. The recess in the body 10 may taper towards the bottom, so as to force the tongues 52, 53 to stretch through its contact with the tongues or through its contact solely with the free ends of the tongues.

The recess in the body 10 is suitably rotationally synergetic. The slotted part 51 of the part 5 is suitably larger along the slot 30 than transversely to the slot 30 when no load acts on the part 51, wherein the tongues 52, 53 have a cross-section such that in the state shown in Fig. 13 they will have a generally circular cross-section at their front ends .