ENCLOSURE .

FIELD OF THE INVENTION

The invention relates to enclosures and electrical sockets comprising such enclosures.

BACKGROUND OF THE INVENTION

An enclosure usually comprises walls and a door which can be rotated opened or closed with respect to the walls. Bistable systems have also been provided so as to prevent the door from staying in an intermediate position.

Whatever the position of the door, such systems will urge the door opened or closed.

Such systems are for example provided to close the access to the fuel tank of vehicle cars. In order to fuel the car, the bistable door will be placed open in order to access to the closing cap of the tank.

Due to their autonomy still lower than that of fuel cars, electrical cars need to be powered more often over their life time. There is therefore a need to provide for an enclosure with an increased life time (in terms of number of opening/closing cycles). SUMMARY OF THE INVENTION

It is provided an enclosure comprising a wall, and a door which is mounted to rotate with respect to the wall between an opened position and a closed position around a rotation axis. An intermediate position can be defined between the opened and closed positions.

The enclosure comprises a bistable urging system which urges the door, with respect to the wall, toward the closed position when the door is between the closed and the intermediate positions. The bistable urging system urges the door toward the opened position when the door is between the intermediate and opened positions.

The bistable urging system comprises:

a guide fixed to the wall,

a urging spring,

- an integral body mounted to slide on the guide under urging action of the urging spring, and having a top face,

an actuator integral with the door, and comprising a cam surface facing the top face of the integral body.

The top face of the integral body forms a cam follower which cooperates with the actuator so that, upon a movement of the door between the opened and closed positions, the actuator causes a movement of the integral body along the guide.

The actuator has an apex and two lateral faces, one on each side of the apex so that, when the apex is in contact with the cam follower, the door is in its intermediate position and the urging spring urges the body.

The cam surface of the actuator and the cam follower both have a profiled surface which is cylindrical with an axis parallel to the rotation axis as generatrix.

With these features, it is provided an enclosure which can cope with the stringent requirements described above. Further, this enclosure, although beneficial for this specific requirement, could also be provided for other applications than closing the charge interface for the electrical vehicle car application.

In some embodiments, one might also use one or more of the features defined in the dependant claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics and advantages of the invention will readily appear from the following description of two of its embodiments, provided as a non- limitative example, and of the accompanying drawings.

On the drawings :

Fig. 1 is a schematic view of a possible application of the invention,

- Fig. 2 is a perspective side view of an embodiment of an enclosure,

Fig.3 is a perspective top view of a door for the embodiment of Fig. 2,

Figs. 4a and 4b are partial sectional views through the housing along line IV-IV of Fig. 2, respectively in an uncompressed and a compressed condition of the spring,

Fig. 5 is a partial sectional view through the housing along line V-V of Fig. 4a,

- Fig. 6a and 6b are partial views of the locking system respectively in locked condition and ongoing locking condition, and

Fig. 7 is a view similar to Fig. 2 for a second embodiment .

On the different Figures, the same reference signs designate like or similar elements.

DETAILED DESCRIPTION

Figure 1 schematically shows an electrical car 1 having a power charge socket 2 closed by a door 3. A powering system is schematically shown, having a cable 5 terminating with a power charge plug 6 to be electrically connected to the charge socket 2.

Figure 2 now schematically shows an enclosure 7 located inside the vehicle car 1. The enclosure has a wall 8 located inside the car body. The door 3 is shown in its open condition, and is rotatably movable with respect to the wall 8 in order to alternately open or close the enclosure. As shown in Fig. 2, in the open condition of the door 3, an electrical connector 9 located inside the enclosure is accessible for powering by the powering system. The electrical connector 9 comprises a housing 10 defining a plurality of pathways, and electrical contacts 28 located inside these pathways.

Turning to Fig. 3, the door 3 is mounted to rotate with respect to the wall 8 about a rotation axis XI defined for example by an axis 4 of the wall 8 passing through a sleeve 11 of the door.

The door 3 further comprises part of a bistable mechanism on one side, and part of a locking system on the other side, as will be discussed below in more details in relation to Figs. 4a to 5, and 6a and 6b, respectively.

As can be seen on Fig. 4a, a housing 12 is defined in the enclosure, in particular fixed with respect to the wall. The housing 12 has a bottom wall 13 from which guiding walls 14 extend upward toward the axis 4. The bottom wall 13 and guiding walls 14 together define a cavity .

According to an exemplary embodiment, a peg 15 projects upward from the bottom wall 13 inside the cavity 16. The peg 15 forms a seat for a coil spring 17. Hence, the coil spring 17 surrounds the peg 15, with one end resting on the bottom wall 13, and the other opposed end receiving a body 18. The body 18 has lateral walls which slidingly cooperate with the guiding walls 14 of the cavity, so that the body 18 moves along a given translation axis Z. The body 18 may be provided with a recess 19 on its bottom side, so as to receive therein the second end on the spring 17. In the open condition of the door, the spring 17 is uncompressed, or might be slightly compressed.

A bistable system is provided for opening or closing the door 3 with respect to the wall 8. In an intermediate position of the door, between its open and closed position, corresponding to the position of Fig. 4b, the spring 17 is in its most compressed state, so that it urges the body 18 along direction Z. In both the open and closed conditions of the door, which correspond to the drawing of Fig 4a, the spring 17 is only slightly compressed, if at all. In the open condition, the door 3 is maintained by a not shown abutment. In the closed condition, the door is maintained by the locking system which will be described later. The degree of compression of the spring in the open and closed conditions might differ .

This bistable system is provided through cooperation of an actuator 20 with the body 18. The actuator is integral with the door 3, for example carried by the sleeve 11, and comprises a cam surface 21 with an apex 22 which projects farthest away from the axis Xi . The actuator 20 further comprises two side surfaces 23a and 23b surrounding the apex. As shown on Fig. 3, the cam surface 21 of the actuator has a profiled surface which is cylindrical with an axis parallel to the rotation axis Xi as generatrix.

The body 18 is provided integral and has a top surface 18a opposite to the bottom surface 18b which receives the spring 17. The top face 18a of the body forms a cam follower which cooperates with the cam surface 21 of the actuator. The cam follower also has a profiled surface which is cylindrical with an axis parallel to the rotation axis Xi as generatrix.

Hence, when the door is in its intermediate position (Fig. 4b) the apex 22 of the cam surface 21 is in contact with the top surface 18a of the body. Any slight deviation from this position will cause the release of the spring, which will push the door in rotation with respect to the wall around the axis Xi . For example, in the closed condition of the door, the top surface 18a of the body 18 cooperates with the line joining the side surface 23a of the actuator with the sleeve 11. In the open position of the door, the geometry of the system would be similar to the one of Fig. 4a, with the top surface 18a of the body cooperating with the other side surface 23b of the actuator 20.

An exemplary locking system will now be described with reference to Figs. 2, 3 and 6a and 6b. A flexible tongue 24 is provided on the door 3 between two parallel walls 25. An axis 26 symmetrical to the axis 4 is provided integral with the wall 8.

The flexible tongue 24 is provided with a recess 27 shaped to receive the axis 26 after a slight deflexion of the tongue 24, as shown on Fig. 6a. In the locked condition of the door 3, the axis 26 is maintained between the flexible tongue 24 and one of the walls 25 facing this tongue. In order to open the door 3, the tongue 24 will be resiliently deformed, as shown on Fig. 6b, thereby enabling the axis 26 to be removed from the recess 27. The wall 25' is provided on the other side of the tongue 24 which has the recess 27, and works as an abutment for the tongue 24 for preventing an additional deflexion thereof beyond the elastic limit of the chosen material.

The spring 17 may be dimensioned so that the closing of the door 3 under the effect of the spring 17 will automatically cause the tongue 24 to trap the axis 26.

The axis 4 and 26 can be provided symmetrical to one another. In particular, the side of the enclosure which has the axis 26 may comprise a housing 12' with a cavity, a bottom wall, a peg and guiding walls similar to the ones which were described above in relation to Figs. 4a, 4b and 5. That will enable to provide easily with a flexible device that would be mountable either with a door opening on the left hand side as shown on Fig. 7, or one the right hand side, as shown on Fig. 2.

Although the above description was performed for the specific application of powering an electrical vehicle, it is believed that the above invention may be applied in other applications. In particular, providing the cam surface and the cam follower with a profiled surface which is cylindrical with an axis parallel to the rotation axis as generatrix enables to dispatch the stresses on a whole surface along a line parallel to the rotation axis, and would thus limit wear of the system, thus enabling it to stand a longer life.

Providing the body 18 integral with a top surface provided with the cam follower, and a bottom surface opposite thereto, and to slide in a cavity receiving the spring mounted on a peg, makes the assembly of the system easy and reliable.