EP0547970B1 - Floating electrical connection element mountable on support piece - Google Patents

Description

The present invention relates to improvements made to electrical connectors made up of two connector elements of polygonal cross section which are supported by respective support members and which are mutually couplable or decouplable when the two support members are brought together or distant from one another. the other in a direction approximately parallel to the direction of coupling of said connector elements.

More specifically, the invention aims to improve an electrical connector element designed to be fixed in a floating manner to a support member, said connector element comprising a body of polygonal cross section and couplable or decouplable with a body of connector element. complementary integral with another support member when the two support members are respectively brought closer or distant from each other in a direction approximately parallel to the direction of coupling of the two connector elements, said connector element comprising, interposed between the body of the connector element and the support member, connecting means arranged to give the body of the connector element six degrees of freedom, namely three degrees of freedom in translation in three mutually substantially orthogonal directions one of which substantially coincides with the mating direction and t three degrees of freedom in rotation around the above three directions, elastic return means being associated with said connecting means to return the body of the connector element in a position of equilibrium for each degree of freedom.

When the coupling of the two connector elements is carried out during the bringing together and docking of their respective support members, the correct realization of this coupling is dependent on the relative positioning of the support members. When these can have a mutual transverse offset and / or inclination situated in predetermined value ranges, the coupling of the two connector elements should be able to be obtained correctly despite these unfavorable circumstances. This case arises in particular when the connectors are located in critical or hostile environments (spatial environment for example) and when the connection or disconnection of the connector elements must be controlled remotely (remote handling) and carried out for example using a manipulator arm (robot).

The solution to this problem is known in its general aspect and consists in giving at least one of the two connector elements to be coupled a relative freedom of movement relative to its support, so that its movement, when it reaches the contact of the other connector element, brings the axes of the two connector elements substantially coincident as described, for example, in document EP-A-0 371 835.

Practical solutions have been developed for connectors of general cylindrical conformation of revolution and these solutions, which combine several housings or parts of coaxial housings held by springs, make it possible to ensure effective coupling even when the two connector elements are presented. 'one in front of the other without being rigorously coaxial.

However, in the case of such cylindrical connectors, the number of degrees of freedom to be controlled is relatively limited due to the geometry with axial symmetry of the connector and the solutions known in this field remain technologically simple.

On the other hand, the problem which arises is notably complicated when it is a question of connector with polygonal section in which a transverse offset which can be combined with a mutual inclination of the two elements of connectors to be coupled requires controlling up to six degrees of freedom (three degrees of freedom in translation and three degrees of freedom in rotation). The complexity of the problem is further increased when it is a connector with a very elongated polygonal section (in a common case: of rectangular section with large sides of dimension much greater than that of the short sides): an attempt to couple the two connector elements presented with their respective large dimensions mutually inclined leads to an almost certain jamming of the two connector elements one inside the other, or even to their deterioration.

The high number of parameters to be checked in the case of connectors with a polygonal section, in particular very elongated, means that the known solutions for connectors of cylindrical shape are then ineffective and therefore cannot be repeated in this case.

The invention therefore essentially aims to propose a concrete solution for an arrangement of connector element of polygonal section mounted in a floating manner with six degrees of freedom (namely three degrees of freedom in translation and three degrees of freedom in rotation) on a support member in such a way as to ensure the effective and correct coupling of two connector elements presented to each other by having their large dimensions inclined to each other, even when they are connector elements of very elongated section.

For these purposes, an electrical connector element as defined above, being arranged in accordance with the invention, is essentially characterized in that a first of the connecting means interposed between the body of the connector element and the member support is arranged to give the body of the connector element a possibility of rotation about an axis which is substantially perpendicular to the direction of coupling and to give the body of the connector element a possibility of translation relative to the support member in the direction approximately parallel to the mating direction,
and in that one of the elastic return means for returning the body of the connector element to an equilibrium position in which it is spaced from the support member is calibrated to be triggered when the body of the element connector is subjected to a force in the coupling direction which is greater than the coupling force of the two connector elements.

Thanks to the arrangement according to the invention, the body of the connector element has a degree of freedom in rotation about an axis approximately perpendicular to the direction of coupling (and therefore to the long sides of the body when this- ci is of rectangular section) and it is possible to couple it correctly with the complementary connector element when they are presented inclined with respect to each other transversely to said axis (in particular with the long sides mutually inclined in the case of bodies of rectangular sections). The body of the connector element also has a degree of freedom in translation along approximately the coupling direction, which constitutes a safety overtravel - adding to the connection stroke proper - traversed under the action of a force greater than the normal connection force and thus making it possible to be assured of the effective completion of the connection.

In a preferred embodiment, the connector element comprises at least one single intermediate connecting piece which is freely connected to the body of the connector element by at least one pivot substantially transverse to the direction of coupling and which is freely connected by guide means to the support member. Advantageously, in this case, the connecting and guiding means of the intermediate piece comprise a passage secured to the support member in which the intermediate piece is freely engaged and a system of protruding finger and elongated light approximately in the direction of coupling, which is interposed between the intermediate piece and the support member.

In addition, preferably the connector element comprises at least one spring leaf bearing, in its central region, against the pivoting link pivot of the intermediate piece and of the body of the connector element and bearing, by its two ends, against the support member. A remarkable structure is thus obtained by its compactness.

It can also be provided that an intermediate plate is associated with the body of the connector element, this plate extending substantially perpendicular to the direction of coupling; that the body of the connector element is fixed to said plate by a second connecting means which has three degrees of freedom, namely a degree of freedom in rotation about an axis parallel to the direction of coupling and two degrees of freedom in translation along two axes perpendicular to each other and to the direction mating; and that the aforesaid second connecting means cooperates with said intermediate plate connected to the body of the connector element.

In a practical embodiment, the second connecting means comprises at least a second pivot approximately parallel to the direction of coupling and integral with the plate or the body of the connector element and second elastic return means deformable transversely to the direction d 'coupling and interposed between said pivot and respectively the connector element or the plate. Preferably then, the second elastically deformable means comprise at least one spiral spring.

Finally, it is also possible to provide that an intermediate cradle is associated with the support member, this cradle extending approximately perpendicular to the direction of coupling; that said cradle is fixed to the support member by a third of the connecting means which has a degree of freedom in rotation about an axis substantially perpendicular to the direction of coupling; and that the aforesaid first of the connecting means cooperates with said cradle connected to the support member.

In practical terms, the third of the connecting means comprises at least a third pivot approximately perpendicular to the direction of coupling and to the first pivot and integral with the cradle or the support member and third elastic return means interposed between the cradle and the support member for returning said cradle to a position of equilibrium relative to the support member.

A system is then obtained which is normally centered, in the absence of opposing forces, under the action of the elastic means associated with the connecting means in translation or in rotation while the body of the connector element has all the degrees of freedom desirable in order to be able to cooperate with the complementary connector element whatever their relative position when they are presented to each other.

• la figure 1 est une vue partielle éclatée en perspective d'un élément de connecteur de section rectangulaire agencé conformément à l'invention ;
• la figure 2 est une demie-vue en coupe, selon la ligne II-II de la figure 1, d'une partie de l'élément de connecteur de la figure 1 ;
• la figure 3 est une vue partielle en coupe, selon la ligne III-III de la figure 1 ; et
• la figure 4 est une vue éclatée en perspective montrant une partie de l'élément de connecteur de la figure 1.

The invention will be better understood on reading the following detailed description of a preferred embodiment given solely by way of purely illustrative example; in this description, reference is made to the appended drawings in which:

• Figure 1 is a partial exploded perspective view of a connector element of rectangular section arranged in accordance with the invention;
• Figure 2 is a half sectional view along the line II-II of Figure 1, of a portion of the connector member of Figure 1;
• Figure 3 is a partial sectional view along line III-III of Figure 1; and
• FIG. 4 is an exploded perspective view showing part of the connector element of FIG. 1.

By first considering FIG. 1, the reference 1 generally designates a connector element body of polygonal cross section - here rectangular by way of example - which is supported by a support member 2 (represented by very fragmentary).

Between a plate 3, associated with the body 1 of the connector element and substantially perpendicular to the axis Z of the connector (corresponding approximately to the direction F of coupling), and a cradle 4, associated with the support member 2 and substantially parallel to the plate 3, there are interposed first connecting means 5 constituted as follows.

As can be seen in particular in FIGS. 1 and 2, an intermediate piece 6, for example in the form of a wafer, is joined freely to the plate 3 by a pivot 7 (coinciding with the Y axis perpendicular to the long sides 8) substantially at the level from the middle of the long side 8 of the body 1, the pivot 7 extending substantially transversely to said long side 8. The opposite end of the intermediate piece 6 is engaged in a guide passage 9 integral with the cradle 4 (this passage being here pierced in an upright of the cradle 4) and supports a protruding finger 10 engaged in a guide light 11 pierced in the cradle 4, said light extending substantially parallel to the axis Z.

A curved leaf spring 12 bears in the middle against the pivot 7 and bears at its ends against the cradle 4.

The connecting means 5 are double and arranged on either side, along the Y axis, of the body 1 of the connector element.

Using the references mentioned in FIG. 1, the assembly which has just been described confers on the body 1 of the connector element a degree of freedom in rotation β around the axis Y (pivot 7) associated with a degree of freedom in translation along the Z axis (light 10), that is to say approximately parallel to the direction F of the coupling. When the body 1 is inclined around the axis Y, the plate 3 bears on the concavity of the spring 12 adjoining the pivot 7 and tends to elastically deform this spring: for small pivot angles, the spring provides a return to the position balance by reacting on the plate 3. In addition, the spring 12 is calibrated to be deformed when the body 1 of the connector element is subjected to a force in the direction of coupling which is greater than the force d coupling of the two connector elements: this results in the possibility of overtravel in the event of excessive effort which ensures that the coupling of the two switch elements is correct. The spring 12 ensures, by itself, the return to the equilibrium position both in rotation and in translation.

Furthermore, there are interposed, between the body 1 and the plate 3, second connecting means 13 which are the better visible in Figures 3 and 4. For this purpose, at the base of its short sides 14, the body 1 has projecting lugs 15 which are provided with a threaded hole 16. Opposite, the plate 3 has a housing 17 which is crossed by a shoulder screw 18 screwed into the bore 16. The housing 17 houses a spiral spring 19 interposed between the rod of the screw 18 forming a pivot and the wall of the housing. The connecting means 13 are double and arranged on either side, along the axis X, of the body 1 of the connector element.

According to the conventions given in FIG. 1, the connection means 13 give the body 1 three degrees of freedom, namely two degrees of freedom in translation along the axes X (perpendicular to the axes Y and Z) and Y (plane displacement on plane of the body 1 relative to the plate 3) and a degree of freedom in rotation Γ around the axis Z. The spiral spring 19 alone provides the return to the equilibrium position both in translation and in rotation.

Finally, there is also interposed, between the support member 2 and the cradle 4, third connecting means 20 which are visible in FIGS. 1 and 3. The connecting means 20 comprise a pivot 21 (here constituted by a screw shouldered) connecting the support member 2 and the cradle 4 with free rotation, being directed perpendicular to the short sides 14 of the body 1 of connector. A spring 22 is interposed between the support member 2 and the cradle 4 to ensure the return of the latter in the equilibrium position. The connecting means 20 are double and arranged on either side, along the axis X, of the body 1 opposite the short sides 14 thereof.

According to the conventions given in FIG. 1, the connecting means 20 confer a degree of freedom in rotation α around the axis X.

In the connector element equipped with connection means 5, 13 and 20, the body 1 is provided with six degrees of freedom - three degrees in translation along the axes X, Y and Z and three degrees in rotation in the angular directions α, β and Γ- which gives it a total possibility of movement relative to its support member 2.

As goes without saying and as it already follows from the above, the invention is in no way limited to those of its modes of application and embodiments which have been more particularly envisaged; on the contrary, it embraces all its variants.

Claims (10)

1. An electrical connector element arranged to be fixed in a floating manner to a support member (2), said connector element comprising a body (1) having a polygonal cross-section and being suitable for coupling and decoupling with a body of a complementary connector element secured to another support member when the two support members are moved respectively towards each other and apart from each other along a direction approximately parallel to the coupling direction of the two connector elements, said connector element comprising, interposed between the body (1) of the connector element and the support member (2), link means (5, 13, 20) arranged to impart six degrees of freedom to the body (1) of the connector element, namely three degrees of freedom in translation along three directions (X, Y, Z) that are substantially mutually orthogonal, one of said directions (Z) coinciding substantially with the coupling direction (F), and three degrees of freedom in rotation (α, β, Γ) about said three directions (X, Y, Z), with resilient return means (12, 19, 22) being associated with said link means to return the body (1) of the connector element to an equilibrium position for each degree of freedom ;
      characterized in that one first (5) of said link means which is interposed between the body (1) of the connector element and the support member (2) is arranged to enable the body of the connector element to rotate about an axis (Y) which is substantially perpendicular to the coupling direction, and to enable the body of the connector element to move in translation relative to the support member along a direction (Z) approximately parallel to the coupling direction ; and
      in that one of said relilient return means for returning the body of the connector element to an equilibrium portion in which it is spaced apart from the support member is rated so as to come into play when the body of the connector element is subjected to a force along the coupling direction which is greater than the coupling force between the two elements of the connector.
2. A connector element according to claim 1, characterized in that it comprises at least one single intermediate link piece (6) which is free rotatably connected to the body of the connector element by at least one pivot (7) substantially transverse to the coupling direction and which is free slidably connected via guide means to the support member.
3. A connector element according to claim 2, characterized in that the guide and link means of the intermediate piece (6) comprise a passage (9) integral with the support member and in which the intermediate piece (6) is freely engaged and a system comprising a projecting finger (10) and an elongate slot (11) extending approximately in the coupling direction, which system is interposed between the intermediate piece and the support member.
4. A connector element according to anyone of claims 1 to 3, characterized in that it comprises at least one curved spring blade (12) having a central region bearing against the pivot (7) providing rotary linkage between the intermediate piece (6) and the body of the connector element, and having two ends bearing against the support member.
5. A connector element according to anyone of claims 1 to 4, characterized in that an intermediate platform (3) is associated with the body (1) of the connector element, said platform extending substantially perpendicularly to the coupling direction ; in that the body (1) of the connector element is fixed to said platform by one second (13) of said link means which has three degrees of freedom, namely one degree of freedom in rotation (Γ) about an axis (Z) parallel to the coupling direction, and two degrees of freedom in translation along two axes (X, Y) that are perpendicular to each other and to the coupling direction ; and in that said second link means (13) co-operates with said intermediate platform (3) connected to the body of the connector element.
6. A connector element according to claim 5, characterized in that the second link means (13) comprises at least one second pivot (18) approximately parallel to the coupling direction and integral with the platform (3) or the body (1) of the connector element, and second resilient return means (19) deformable transversely to the coupling direction and interposed between said pivot and respectively the connector element or the platform.
7. A connector element according to claim 6, characterized in that the second resiliently deformable means comprise at least one spiral spring (19).
8. A connector element according to anyone of claims 1 to 7, characterized in that an intermediate cradle (4) is associated with the support member (2), said cradle extending approximately perpendicularly to the coupling direction ; in that said cradle is fixed to the support member by one third (20) of said link means which has one degree of freedom in rotation (α) about an axis (X) substantially perpendicular to the coupling direction ; and in that said first (5) of said link means co-operates with said cradle (4) connected to the support member.
9. A connector element according to claim 8, characterized in that the third (20) of said link means comprises at least a third pivot (21) approximately perpendicular to the coupling direction and to the first pivot, and integral with the cradle (4) or the support member (2), and third resilient return means (22) interposed between the cradle and the support member to return said cradle to an equilibrium position relative to the support member.
10. A connector element according to anyone of claims 2 to 9, characterized in that the link means are provided in duplicate and are situated respectively on opposite sides of the body of the connector element.

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