The invention relates to a housing for an electrical connector.

Electrical connectors, such as network connectors, usually comprise a cable outlet arranged at a rear side of the electrical connector. For physical and electrical protection, a housing is provided for receiving the electrical connector. As the cable exits the cable outlet, sufficient space is necessary to install the cable, which is a rare commodity in various applications. Therefore, there is a demand for space-saving housings, which redirect the cable in such a way that minimal space is occupied when installed. However, depending on the application, the cable should be redirected in different directions resulting in a large stock of different housings, increasing the production costs and storage costs.

Therefore, it is an object of the invention to provide a housing that can be easily adapted for different application requirements and occupies less space.

The invention solves the above-mentioned problem by providing a housing for an electrical connector, the housing comprising a housing body having an opening configured to receive an electrical cable in an insertion direction. The housing further comprises a pair of cable covers hinged to the housing body at one proximal end of the cable covers extending away from the opening, wherein, in a cable mounting position, each cable cover of the pair of cable covers is pivoted away from the other cable cover of the pair of cable covers, and, in an operating position, each cable cover of the pair of cable covers is pivoted towards each other forming a cable support sleeve configured to support the cable.

The pair of cable covers can be adapted to the application requirements, so that the cable can be redirected as desired. The cable installation may vary depending on the available space. Thus, by having a pair of cable covers, which can be hinged to the housing body, the orientation of the cable cover can be adapted to the application surroundings. Furthermore, the pair of cable covers form a cable support sleeve in the operating position configured to support the cable, particularly directly. Hence, the pair of cable covers further provides a strain relief for the cable, securing the electrical and mechanical integrity and overall performance of the electric connector. The cable covers directly prevent mechanical force applied to the exterior part of the cable from being transferred to the electrical terminations of the cable within the electrical connector. The inventive housing provides a two-part cable support sleeve for strain relief, which can easily be adapted to be oriented in different directions relative to the opening.

The invention can further be improved by the following features, which are independent from one another with respect to their respective technical effects and which can be combined arbitrarily.

According to a first embodiment of the invention, each cable cover of the pair of cable covers may be adapted to be pivoted around a respective axis of rotation, which is orientated perpendicular to the insertion direction. The respective axis of rotation may be arranged parallel to each other at opposing sides of the opening. Therefore, in the mounting position, wherein each cable cover of the pair of cable covers is pivoted away from the other cable cover of the pair of cable covers, the cable covers may also be pivoted away from the opening, hence, facilitating the mounting of the electrical cable.

The electrical cable may be installed in the electrical connector, which can be inserted into the opening in the mounting position. The electrical connector may comprise a wire organiser in which the single wires of the cable may be inserted at predetermined positions. The electrical connector may be a termination unit in which the wires of the cable may be terminated. The termination unit may be inserted into the opening of the housing body and may be connected to a further connector element, such as a plug terminal.

The housing body may preferably be formed of an electrically insulating material. The housing body may be formed by injection moulding allowing for a cost efficient production, particularly for mass scale. The housing body may comprise a cavity, the cavity opening towards an open end of the housing body in the insertion direction, for receiving the electrical cable and/or the electrical connector.

The pair of cable covers may be attached to the housing body at the open end of the housing body. Therefore, the cable covers do not have to extend over the length of the housing body and thus require less material for the production of the cable covers.

In a further advantageous aspect, at least one cable cover of the pair of cable covers, preferably each cable cover of the pair of cable covers, may comprise at least one grounding spring configured to contact and ground a cable braid of the cable in the operating position. The at least one grounding spring may be mounted to an interior side of the respective cable cover of the pair of cable covers facing the other cable cover of the pair of cable covers.

Multiple grounding springs may be arranged around the inner circumference of the respective cable cover, so that a uniform contacting of the cable braid is achieved in the operating position.

At least one cable cover of the pair of cable covers, preferably each cable cover of the pair of cable covers, may comprise at least one fixation latch for locking the cable and/or electrical connector in the opening in the operating position. The fixation latch may be formed as a fixation spring that may at least partially extend into the opening in the operating position being adapted to compensate vibrations. The fixation latch may at least partially overlap with a cross section of the opening perpendicular to the insertion direction when in the operating position, blocking a movement of the cable and/or electrical connector parallel to the insertion direction. Preferably, the fixation latch may be pivoted away from the opening in the mounting position allowing an easy insertion of the electrical connector and/or cable into the opening.

The at least one fixation latch may be adapted to press against the electrical connector in the operating position, further guiding the electrical connector through the opening into the housing body. A normal force may act upon the fixation latch pressing against the electrical connector. The normal force may be transferred via the respective cable cover to respective bearings at which the cable cover is hinged to the connector body. The bearings may comprise an electric conductive element at the side facing the opening of the connector body. The conductive element may thus be pressed onto the electrical connector with said normal force providing further shielding to the connector.The at least one fixation latch and the at least one grounding spring may be formed integrally with one another as a monolithic component. The at least one fixation latch and at least one grounding spring may, for example, protrude from a main spring body that is securely fastened to the respective cable cover of the pair of cable covers. Further reducing the amount of separate parts in the housing. The cable covers may be adapted for a predetermined cable diameter, meaning that in the operating position, the formed cable support sleeve is adapted to receive the cable in an essentially precise fit. However, in order to have a pair of cable covers applicable for a wider range of cable diameters, such as from about 3.8 mm to about 8.0 mm, at least one cable cover of the pair of cable covers, preferably each cable cover of the pair of cable covers, may be provided with at least one strain relief spring biased towards the opposing cable cover of the pair of cable covers in the operating position. The at least one strain relief spring may be adapted to compensate for different cable diameters, by defining a resilient effective cross section in the operating position, that adjusts to the cable diameter.

The at least one strain relief spring and the at least one grounding spring may be formed integrally with one another as a monolithic component. The at least one strain relief spring and at least one grounding spring may be formed as a stamped metal sheet that is bent into a form. The at least one strain relief spring and the at least one grounding spring may be formed as bent latches from a main spring body that may be fastened to the respective cable cover.

The at least one strain relief spring and the at least one fixation latch may be formed integrally with one another as a monolithic component. The at least one strain relief spring and the at least one fixation latch may be formed as a stamped metal sheet that is bent into form. The at least one strain relief spring and the at least one fixation latch may be formed as bent latches from a main spring body. The at least one strain relief spring and the at least one fixation latch may be formed on opposing ends of the main spring body, whereby the at least one fixation latch may be arranged at the proximal end of the respective cable cover.

Preferably, the at least one grounding spring, the at least one fixation latch and the at least one strain relief spring may be formed integrally with one another as a monolithic component. Each of the three may protrude from a main spring body that can be fixed to the cable cover towards the opposing cable cover of the pair of cable covers in the operating position. The at least one grounding spring may be formed as a wing that protrudes from a lateral side of the main spring body while the at least one fixation latch may preferably be arranged at the proximal end of the respective cable cover. The at least one strain relief spring may preferably be positioned at a distal end of the respective cable cover. In this advantageous embodiment, fixation, grounding and strain relief are all provided by a monolithic component, reducing the amount of separate parts in the housing. The at least one strain relief spring may comprise an arch formed by bending the at least one strain relief spring. The arch may form a deflection section at which the at least one strain relief spring is deflected away from the opposing cable cover of the pair of cable covers in the operating position in order to adapt to the cable diameter. The arch may preferably be arranged in a recess of the respective cable cover, providing space for the arch to be deflected. The recess may for example be formed in the interior side of the cable cover or alternatively be formed as a cutout in the cable cover. This arrangement allows a deflection of the at least one strain relief spring without having to increase the dimensions of the housing, particularly the dimensions of the pair of cable covers. Consequently, the larger the cable diameter the further the strain relief spring may be deflected out of the cable cover through the recess, particularly the cutout, further increasing the variety of cable diameters that can be received in the cable cover.At least one of the cable covers from the pair of cable covers may comprise at least one positioning rib protruding from the interior side of the cable cover and reducing the effective width between a top and a bottom of the cable cover. Preferably, each cable cover is provided with a positioning rib at the top and at the bottom of said cable cover forming a central opening. The positioning rib may provide an abutting surface that may be abutted by the insulation of the cable facing away from the opening of the housing body. Therefore, the insertion depth of the cable can be limited. The at least one positioning rib may further increase the preciseness of the cable braid within the pair of cable covers ensuring a contact between the at least one grounding spring and the cable braid.

The housing body may be provided with a polarisation element, such as a guiding notch adapted to receive a protrusion formed on the connector or a guiding rail. The at least one guiding notch or guiding rail may face the opening of the housing body and be distanced from a central axis of the housing body perpendicular to an insertion direction. Therefore, the opening may comprise an asymmetrical cross-section in a plane perpendicular to the insertion direction.

According to a further advantageous aspect, at least one of the cable covers from the pair of cable covers, preferably each cable cover of the pair of cable covers, may comprise a guiding protrusion adapted to be guided into a receiving notch on the other cable cover of the pair of cable covers in the operating position. The guiding protrusion may circumferentially protrude towards the other cable cover of the pair of cable covers in the operating position. The receiving notch may preferably be formed complementary to the respective guiding protrusion. The guiding protrusion and the receiving notch may form a guiding assembly for guiding the movement between the cable covers, particularly from the mounting position to the operating position, preventing misalignment of the pair of cable covers.

A locking nut may be provided, the locking nut being adapted to lock the pair of cable covers in the operating position. The pair of cable covers may be adapted to be received in the locking nut at least when the pair of cable covers are in the operating position. The locking nut may be sleeved around the pair of cable covers at least partially in a locking position preventing the pair of cable covers from pivoting away from one another.

The distal ends of the cable covers may be tapered to allow for an easy insertion into the locking nut, even when the cable covers are not completely in the operating position. Thus, the locking nut may be shoved over the cable covers without needing to press the cable covers together with one hand. By inserting the cable covers into the locking nut, the locking nut automatically pushes the cable covers towards each other, bringing them into operating position. Consequently, an easy single-handed installation is possible, which further decreases the space requirements for installation.

The locking nut and the cable covers may form a locking assembly to lock the locking nut to the cable covers. For example, the cable covers may comprise a threaded section on which the locking nut may be screwed onto.

However, an easy and space-saving locking assembly may be formed by a bayonet locking assembly. The bayonet locking assembly allows for an easy locking with a simple twist action and ensures not exceeding the offered space in an existing application. In contrast to threaded components, the cable covers do not have do be in exact orientation when pressed together.

At least one locking protrusion may be provided for securing the locking engagement of the nut to at least one of the cable cover of the pair of cable covers. Preferably, the at least one locking protrusion may be formed on the inner surface of the locking nut. The locking protrusion may engage a complementary formed locking recess on the cable cover locking the locking nut to the cable cover. In a further advantageous embodiment, the locking nut may be provided with at least two locking protrusions protruding radially from the inner surface of the locking nut. The at least two locking protrusions may preferably be arranged diametrically to one another. Each locking protrusion may be adapted to be engaged to a different cable cover of the pair of cable covers. Therefore, the locking nut may be locked to each cable cover, further securely locking the cable covers to one another in the operating position via the locking nut.

Each cable cover of the pair of cable covers may comprise a guiding groove on their respective outer surface facing away from each other, at least in the operating position. The guiding groove may extend from the distal end of the respective cable cover towards the proximal end and may taper towards the proximal end. Therefore, the guiding groove may form a mouth at the distal end to catch the respective locking protrusion, allowing for an easy insertion of the respective cable cover into the locking nut, even when the respective cable cover and the locking nut are not perfectly aligned. By pushing the locking nut over the respective cable cover, the locking protrusion slides along the tapering guiding groove, resulting in an automatic realignment of the locking nut relative to the cable cover.

The guiding groove and the locking recess may be arranged adjoining to each other along the circumference of the at least one cable cover forming an essential L-shape, whereby the vertical arm of the L-shape is formed by the locking recess and the horizontal arm of the L-shape is formed by the guiding groove. Once the locking protrusion is inserted in the locking recess, a positive fit is formed, blocking relative motion of the respective cable cover and the locking nut in a direction parallel to the insertion direction.

A locking rib protruding radially from the respective cable cover may be provided between the guiding groove and the locking recess. The locking rib may prevent the locking protrusion from unintentionally exiting the locking recess due to movements such as vibrations. Thus, the locking rib may further secure the locking engagement of the locking nut to the respective cable cover.

The locking rib may be bevelled towards the guiding groove, forming a ramp allowing for easy movement of the locking protrusion from the guiding groove over the locking rib to the locking recess. The locking rib may comprise an abutment surface extending radially from the cable cover, i.e. extending essentially perpendicular to the locking recess, facing the locking recess. Therefore, the locking protrusion abuts the abutment surface when moving from the locking recess towards the guiding groove, restricting any further movement.

In order to further increase the retention-withstanding force of the housing, the locking nut may preferably be adapted to extend parallel to the cable, meaning that at the position of the locking nut, the locking nut does not bend the cable.

The locking nut may preferably have a polygonal cross-section such as a hexagon or octagon, thus being adapted to be handled by a complementary tool such as a wrench. This allows handling of the locking nut, even in tight spaces where the locking nut is not accessible by hand.

The locking nut may comprise a signal for determining the position of the at least one locking protrusion. The signal may, for example, be a visual marking on the outer surface of the locking nut corresponding to the locking protrusion formed on the inner surface of the locking nut. Thus, by looking at the marking, the relative rotational position of the locking nut and pair of cable covers can be determined, allowing an easier installation.

The pair of cable covers and/or the locking nut may preferably be formed from an insulating material, for example by an injection moulding process allowing a cost efficient production of the pair of cable covers and/or the locking nut, especially in large numbers.

The pair of cable covers may be adapted to be hinged on either side perpendicular to the insertion direction of the housing. Consequently, the structurally identical pair of cable covers may be mounted to the housing forming cable support sleeves that are oriented in opposite directions relative to the insertion direction.

The pair of cable covers may be adapted to form a cable support sleeve that is opened in the insertion direction, whereby each cable cover of the pair of cable covers may preferably be formed structurally identical. Therefore, only one form is necessary for producing the pair of cable covers, further facilitating the production process and increasing the production efficiency.

Alternatively, the pair of cable covers may be adapted to form a cable support sleeve having cable outlets oriented in an angular relation to the insertion direction, such as for example in a 90° angle, a 45° angle or anything in between 45° to 90°. The direction of the cable outlet of the cable support sleeve relative to the insertion direction may be determined by the structure of the pair of cable covers. Thus, by providing a pair of cable covers wherein each cable cover of the pair of cable covers may be hinged to the housing, multiple degrees of freedom are provided for adapting the housing to the application surroundings. By simply choosing a specific pair of cable covers, the direction and/or angular orientation of the cable support sleeve’s cable outlet relative to the insertion direction may be determined.

According to a further advantageous embodiment, a set may be provided, the set comprising at least two housings according to the invention, wherein the at least two housings may comprise identically structured housing bodies and different pairs of cable covers, the cable covers forming a cable support sleeve in the operating position with a cable outlet at their distal ends opposite the opening. The cable outlets of the different pairs of cable covers may be oriented differently with respect to the insertion direction.

In the following, the housing, according to the invention, is explained in greater detail with reference to the accompanying drawings in which exemplary embodiments are shown.

In the figures, the same reference numerals are used for elements which correspond to one another in terms of their function and/or structure.

According to the description of the various aspects and embodiments, elements shown in the drawings can be omitted if the technical effects of those elements are not needed for a particular application, and vice versa: i.e. elements that are not shown or described with reference to the figures but are described above can be added if the technical effect of those particular elements is advantageous in a specific application.

In the figures:

Fig. 1 shows a schematic explosion view of a housing according to the invention; Fig. 2 shows a schematic perspective view of the housing according to the invention in a mounting position;

Fig. 3 shows a schematic perspective view of the housing according to the invention in an operating position with different pairs of cable covers; Fig. 4 shows a schematic perspective view of an exemplary embodiment of a cable cover from the housing according to the invention; and

Fig. 5 shows a schematic perspective view of an exemplary embodiment of a locking nut from the housing according to the invention. First, the inventive housing 1 is explained with reference to Figs. 1 and 2. Fig. 1 shows a schematic explosion view of an exemplary embodiment of the housing 1 according to the invention, and Fig. 2 shows a schematic perspective view of the housing 1 in a mounting position 2.

The housing 1 is adapted for an electrical connector 4, having a housing body 6 and an opening 8 configured to receive an electrical cable 10 in an insertion direction I. A pair of cable covers 12 is hinged to the housing body 6 at a proximal end 14 of the respective cable cover 16 of the pair of cable covers 12 extending away from the opening 8. In the cable mounting position 2 as shown in Fig. 2, each cable cover 16 of the pair of cable covers 12 is pivoted away from the other cable cover 16 of the pair of cable covers 12 allowing the insertion of the electrical cable 10 into the opening 8 in the insertion direction I.

The housing body 6 may be provided with a polarisation element 9. In this exemplary embodiment, the polarisation element 9 is formed by two guiding notches 11 extending from the entrance of the opening 8 in the insertion direction I. The electrical connector 4 may comprise protrusions adapted to be received in the respective notches 11. Therefore, the electrical connector 4 can only be inserted into the opening 8 in the insertion direction I, when the protrusions are aligned with the guiding notches 11. The guiding notches 11 are preferably arranged opposite to one another and spaced apart from a middle axis essentially perpendicular to the insertion direction I, so that the opening 8 comprises an asymmetrical cross section in a plane essentially perpendicular to the insertion direction I. Due to the asymmetrical cross section, the orientation of the electrical connector 4 in which it can be inserted into the opening 8 is predetermined. This may further fool-proof the connection system. Of course, different embodiments of the polarisation element 9 may be envisioned, such as guiding rails or ribs. The cable 10 may comprise an insulation 18 and a cable braid 20 arranged coaxially under the insulation 18. The cable 10 may further be comprised of multiple wires 22, which are terminated in a wire organiser 24 that is inserted in the opening 8 of the housing body 6.

The cable 10 preferably has a predetermined cable diameter 26, so that the pair of cable covers 12 may provide a strain relief in an operating position (see Fig. 3). The housing body 6 comprises a bearing 28 in the form of two holes 30 arranged on opposing sides of the opening 8, whereby the holes 30 are arranged coaxially to one another forming a pivoting axis 32 essentially perpendicular to the insertion direction I. A second bearing 28 is provided on the other side of the opening 8 forming a second pivoting axis 32 extending essentially parallel to the first pivoting axis 32. Each cable cover 16 of the pair of cable covers 12 comprises pins 34 adapted to be fittingly inserted into the respective holes 30 formed on opposing latches 36. Therefore, a cable cover 16 of the pair of cable covers 12 may be hinged to either of the bearings 28 and the other cable cover 16 of the pair of cable covers 12 to the other bearing 28.

The holes 30 may be closed towards the opening 8. At the closed hole 30 on the side facing the opening 8, an electrically conductive element 37 may be provided, the conductive element 37 forming a bulge and being adapted to contact the electrical connector 4, when the connector 4 is inserted. Thus, the electrically conductive element 37 may act as a further shielding for the connector 4. The electrically conductive element may be formed onto the closed hole 30 or may close the hole 30 itself. The bearings 28 are formed in a depression 38 of the housing body 6 forming a blocking surface 40, which may block the cable cover 16 from pivoting too far away from the other cable cover 16. Preferably, the hinged cable cover 16 may be pivotable at an angle of about 90° from the mounting position 2 shown in Fig. 2 to the operating position as shown in Fig. 3. Thus, in the mounting position 2, the pair of cable covers 16 do not block the insertion of the cable 10 into the opening 8.

As can be seen in Fig. 2, each cable cover 16 of the pair of cable covers 12 may comprise a grounding spring 42, a fixation latch 44 and a strain relief spring 46 mounted to an interior side 48 facing towards the other cable cover 16 in the operating position. The grounding springs 42, fixation latch 44 and strain relief spring 46 are each formed integrally with one another as a monolithic component 50, for example as a leaf spring. The monolithic component 50 comprises a main spring body 52 which is rigidly mounted to the interior side 48 of the respective cable cover 16. The main spring body 52 may extend from the proximal end 14 of the respective cable cover 16 of the pair of cable covers 12 to a distal end 55 of the respective cable cover 16. At the proximal end 14, the main spring body 52 may be provided with the fixation latch 44, which may be bent at about 90° from the main spring body 52. The fixation latch 44 is adapted to extend into the opening 8 such that the fixation latch 44 overlaps with a cross section 54 of the opening 8 in a plane perpendicular to the insertion direction I. Therefore, the electrical connector 4, e.g. a cable organizer 56, can be secured in the opening 8 by the fixation latch 44 during operation blocking a disengagement of the electrical connector 4 and the housing 1 due to vibrations or similar.

The fixation latch 44 may preferably be adapted to be pivoted away from the opening 8 in the mounting position 2, allowing a free passage of the cable 10 and/or electrical connector 4 into the opening 8. In an operating position 64, in which the pair of cable covers 12 are pivoted towards one another, the fixation latch 44 may abut the electrical connector 4 pushing the electrical connector 4 further into the opening 8 along the insertion direction I. Consequently, the fixation latch 44 is pressed against the electrical connector 4 with a normal force, which may be transferred via the cable cover 16 to the pins 34 pressing into the bearings 28. Therefore, the electrically conductive element 37 is pressed towards the electrical connector 4 with said normal force providing a further shielding feature for the connector 4.

For grounding the electrical cable 10, grounding springs 42 are provided at each cable cover 16 of the pair of cable covers 12. The grounding springs 42 may extend from the main spring body 52 as wings from the lateral sides of the main spring body 52 at the proximal end 14 of the respective cable cover 16. In this exemplary embodiment, each cable cover 16 is provided with two grounding springs 42 that are arranged along a circumference so that each grounding spring 42 can be pushed under the cable braid 20 of the cable 10 for grounding. The grounding springs 42 may extend from the proximal end 14 towards the distal end 55 projecting obliquely towards the other cable cover 16 of the pair of cable covers 12 at least in the operating position so that the grounding springs 42 are biased towards the cable 10 when inserted. Consequently, the grounding springs 42 may be resiliently deflected by the cable 10 adapting to the cable diameter 26. This allows for grounding of a wider range of cable diameters 26, such as from about 3.8 mm to about 8.0 mm.

At the distal end 55 the main spring body 52 may be arched back towards the proximal end 14 forming the strain relief spring 46. The main spring body 52 may be arched at about 120° so that the strain relief spring 46 may be formed as a spring tongue that extends obliquely towards the opposing cable cover 16 of the pair of cable covers 12. Thus, the strain relief spring 46 may be adapted to be biased towards the cable 10 providing a strain relief for a wider range of cable diameters, such as from about 3.8 mm to about 8.0 mm. A compact design may be achieved by providing a cutout 58 in the respective cable cover 16, so that the arch 60 forming a deflection section 62 of the strain relief spring 46 is arranged in the cutout 58. In this formation, the space is provided for the strain relief spring 46 to be deflected without increasing the overall dimensions of the housing 1, particularly the pair of cable covers 12. Consequently, the greater the cable diameter, the further the strain relief spring 46 is deflected radially outwards through the cutout 58.

The strain relief spring 46 is adapted to provide a strain relief for a wider range of cables 10 increasing the applicability of the housing 1, preventing mechanical force applied to the exterior of the cable 10 from being transferred to the electrical terminations within the housing 1 , which could lead to failure. To ensure the correct position of the electrical cable 10 within the housing 1, the cable cover 16 may comprise at least one positioning rib 63 protruding from the interior side 48 of the cable cover 16. Preferably each cable cover 16 of the pair of cable covers 12 comprises two positioning ribs 63 arranged opposite to one another, whereby the positioning ribs 63 reduce the light diameter of the pair of cable covers 16, at least when they are pivoted towards one another. Therefore, the at least one positioning rib 63 may provide an abutment surface 65 facing away from the opening 8, which may be abutted by the insulation 18 of the electrical cable 10. Limiting the insertion depth of the cable 10 and ensuring that the grounding springs 42 contact the cable braid 20 in the operating position 64. In Fig. 3, two exemplary embodiments of the housing 1 according to the invention are shown in the operating position 64. In the first embodiment shown with solid lines, the pair of cable covers 12 form a cable support sleeve 66 having a cable outlet 67 that opens parallel to the insertion direction I and the opening 8. For guiding the movement of the cable covers 16 towards each other, a guiding protrusion 68 is provided circumferentially extending from one cable cover 16 of the pair of cable covers 12. The guiding protrusion 68 may be adapted to be guided into a, preferably complementary formed, receiving notch 70 on the other cable cover 16 of the pair of cable covers 12.

The second embodiment depicted with the dotted lines show the pair of cable covers 12 forming a cable support sleeve 66 that is angled at about 90° having a cable outlet 67 oriented essentially perpendicular to the insertion direction I and the opening 8. Depending on the orientation relative to the insertion direction I in which the cable 10 should enter the cable support sleeve 66, a respective pair of cable covers 12 may be provided. The housing body 6 may remain structurally identical in each embodiment allowing for an easy and cost efficient production of the housing 1 in mass scale. By having identically structured hinges, i.e. the bearings 28 of the housing body 6 and the pins 34 of the respective cable covers 16, each cable cover 16 may be attached on either side of the housing body 6 changing the orientation of angled pairs of cable covers 16. Consequently, by switching the position of each cable cover 16 of the second embodiment shown in Fig. 3 the cable support sleeve 66 may be oriented in the opposite direction with respect to the second embodiment shown in Fig. 3.

For maintaining the pair of cable covers 12 in the operating position 64, a locking nut 72 may be provided. The locking nut 72 may be adapted to receive the pair of cable covers 12 at least partially in the operating position 64 blocking the cable covers 16 from pivoting away from one another.

In order to further increase the retention-withstanding force of the housing 1 , the locking nut 72 may preferably be adapted to extend parallel to the cable 10, meaning that the locking nut 72 does not bend the cable 10. In other words, the locking nut 72 may extend coaxially with the cable 10 at the position of the locking nut 72. Preferably, the locking nut 72 and the pair of cable covers 12 comprise a bayonet locking assembly 74 for locking the locking nut 72 to the pair of cable covers 12.

The bayonet locking assembly 74 may ensure an easy locking with a simple twist and an exact orientation of the final position of the locking nut 72, which ensures not exceeding the offered space in an existing application. In particular, in comparison to a threaded locking assembly, the bayonet locking assembly 74 allows for an easier locking, especially in tight spaces. In the threaded locking assembly 74, the pair of cable covers 12 have to be perfectly aligned for the locking nut 72 to be able to engage the threads of the cable covers 12. Thus, the pair of cable covers 12 have to be pushed and held together in exact alignment with one hand while screwing on the locking nut 72.

The bayonet locking assembly 74 is further explained in detail with reference to Figs. 3, 4 and 5. Fig. 4 shows a perspective view of a cable cover 16 of the pair of cable covers 12 and Fig. 5 shows a perspective view of a locking nut 72 according to the invention.

As can be seen in Figs. 3 and 4 the cable cover 16 may preferably comprise a tapered distal end 55 allowing the locking nut 72 to slide over the distal end 55, even when the cable covers 16 of the pair of cable covers 12 are not completely pushed together. By pushing the locking nut 72 over the pair of cable covers 12, the cable covers 16 of the pair of cable covers 16 may automatically be pushed together, further facilitating the locking of the housing 1 in the operating position 64.

Each cable cover 16 of the pair of cable covers 12 may comprise a guiding groove 76 on their respective outer surface facing away from each other at least in the operating position 64. The guiding groove 76 may extend from the distal end 55 of the respective cable cover 16 towards the proximal end 14 and may taper circumferentially towards the proximal end 14. Therefore, the guiding groove 76 may form a mouth at the distal end to catch a respective locking protrusion 78, allowing for an easy insertion of the respective cable cover 16 into the locking nut 72, even when the respective cable cover 16 and the locking nut 72 are not perfectly rotationally aligned. By pushing the locking nut 72 over the respective cable cover, the locking protrusion 78 slides along the tapering guiding groove 76 resulting in an automatic realignment of the cable cover 16 relative to the locking nut 72.

The cable cover 16 may further comprise a locking recess 80 arranged circumferentially adjoining to the guiding groove 76 at its end closer to the proximal end 14 of the cable cover 16. Therefore, the locking protrusion 78 of the locking nut 72 may be pushed along the guiding groove 76 until abutment, and then by a simple twist movement, be brought into the locking recess 80. The locking protrusion 78 and the locking recess 80 may form a positive fit locking movement in a direction parallel to the insertion direction I. A locking rib 82 protruding radially from the respective cable cover 16 may be provided between the guiding groove 76 and the locking recess 80. The locking rib 82 may prevent the locking protrusion 78 from unintentionally exiting the locking recess 80 due to movements such as vibrations. Thus, the locking rib 82 may further secure the locking engagement of the locking nut 72 to the respective cable cover 16.

The locking rib 82 may be bevelled towards the guiding groove 76, forming a ramp allowing for an easy movement of the locking protrusion 78 from the guiding groove 76 over the locking rib 82 to the locking recess 80. The locking rib 82 may comprise an abutment surface 84 extending radially form the cable cover 16, i.e. extending essentially perpendicular to the locking recess 80, facing the locking recess 80. Therefore, the locking protrusion 78 abuts the abutment surface 84 when moving from the locking recess 80 towards the guiding groove 76 restricting any further movement.

The locking nut 72 preferably comprises two locking protrusions 78 protruding from an inner surface of the locking nut 72 radially inwards. The locking protrusions 78 and the locking nut 72 may be formed integrally with one another. Thus, the locking protrusions 78 and the locking nut 72 may be produced cost efficiently in a single production step such as injection moulding.

The two locking protrusions 78 are arranged diametrically to one another and each locking protrusion 78 may be adapted to be inserted in the locking recess 80 of different cable covers 16 of the pair of cable covers 12. In other words, each cable cover 16 of the pair of cable covers 12 may be adapted to receive one of the two locking protrusions 78. Thus, both cable covers 16 of the pair of cable covers 12 may be locked to the locking nut 72.

The locking nut 72 may comprise a polygonal outer contour such as an octagon as shown in Figs. 3 and 5 or a hexagon. Alternatively or additionally, the locking nut 72 may comprise handle bars, i.e. ribs protruding from the outer surfaces of the locking nut 72 having a gripping function for easier handling of the locking nut 72. With the polygonal outer contour an easy handling of the locking nut 72 is possible, for example with a tool such as a complementary wrench. Thus, enabling locking and/or unlocking of the locking nut 72 when the locking nut 72 is not reachable by hand for example due to space constraints.

In order to determine the relative rotational position of the locking nut 72 relative to the pair of cable covers 12, the locking nut 72 may comprise a marking 86 on the outer surface of the locking nut 72. Hence, the state, i.e. locked or unlocked, of the locking nut 72 and the pair of cable covers 12 may be easily determined. Furthermore, the locking nut 72 may be arranged in a correct rotational position relative to the pair of cable covers 12 for the locking protrusion 78 to be sliding along the guiding groove 76.

REFERENCE NUMERALS

1 housing

2 mounting position

4 electrical connector 6 housing body

8 opening

9 polarisation element

10 electrical cable

11 guiding notch 12 pair of cable covers

14 proximal end

16 cable cover

18 insulation

20 cable braid 22 wires

24 wire organiser

26 cable diameter

28 bearings

30 hole 32 pivoting axis

34 pins

36 latches

37 electrically conductive element

38 depression 40 blocking surface

42 grounding spring

44 fixation latch

46 strain relief spring

48 interior side 50 monolithic component

52 main spring body

54 cross section 55 distal end

56 cable organizer

58 cutout

60 arch 62 deflection section

63 positioning rib

64 operating position

65 abutment surface

66 cable support sleeve 67 cable outlet

68 guiding protrusion

70 receiving notch

72 locking nut

74 bayonet locking assembly 76 guiding groove

78 locking protrusion

80 locking recess

82 locking rib

84 abutment surface 86 marking insertion direction