CH708937A1 - oscillating element for clock movement. - Google Patents

Abstract

The invention relates to an oscillating element (1) for a watch movement comprising: an axis (3); a component (2) mounted on a first portion of said axis (3) so as to be rotatable with said axis; a compliant element (4) mounted on a second part of the axis (3) so as to allow this axis to rotate when said compliant element deforms elastically. In one embodiment, the component (2) is an anchor.

Description

Technical area

The present invention relates to an oscillating element for mechanical watch movement.

State of the art

[0002] Mechanical clock movements comprise numerous oscillating elements, in particular elements rotated alternately in one direction and then in the other. The balance wheel, the hairspring, the escapement anchor, the winding mass, and certain complications are examples of such oscillating elements.

The power reserve of a mechanical watch depends in particular losses due to friction in the train and in the pivot of the regulating member. It is therefore advantageous to reduce these friction in order to increase the power reserve. Friction at the parts oscillating rapidly, especially in the exhaust, are particularly critical. The performance of a typical Swiss lever escapement is typically of the order of about 40%; 60% of the energy transmitted by the gear train to the exhaust is lost in friction.

[0004] A substantial part of these friction occurs at the level of the bearings. Despite the use of rubies and progress in lubrication, the friction between the anchor axis and the bearing that maintains this axis is therefore a critical factor in the loss of energy stored in the barrel.

Furthermore, conventional bearings require a clearance between the pivots of the movable axis and the bearing to allow the axis to rotate. The accuracy of this game depends on manufacturing tolerances and progressive wear of the bearing. This results in poorly controlled positioning of the axis and the component mounted on this axis. In the case of an anchor, this game refers to the relative position of the pallets and the anchor wheel, which also causes energy losses.

[0006] Compiling mechanisms are known in the state of the art which are often used to reduce friction or improve the accuracy of a displacement. A compiling mechanism is a mechanism that, unlike rigid body-based mechanisms, allows displacement through the flexibility of at least one limb. For example, a compiling element allows the rotation of an axis thanks to the flexibility of at least one member. Compiling elements therefore partially or completely avoid the friction of moving parts relative to each other, and the energy losses and wear of the parts that result from this friction. They also make it possible to elegantly solve the problems caused by the play of conventional bearings.

[0007] An application of the compiling elements to the horological domain is described in the patent application EP 2,037,335 A2. This document describes in particular an exhaust anchor without axis and which can rotate thanks to the deformation of two arms whose axes intersect at the point of virtual rotation of the anchor. The attachment arms and the anchor form a relatively fragile single piece. In addition, the attachment arms occupy a relatively large area in the plane of the anchor which is often particularly congested; this place is not available for other organs.

[0008] WO 2011/120 180 A1 discloses a gear lock device based on another compiler link. Again, this device is made in one piece or in one piece with the exception of pallets, making its design difficult. A compiler link integrated with the blocker also has the disadvantage of not being easily adapted to an existing blocker; it is necessary to completely redraw the entire blocker.

Another disadvantage of the solutions described in these anteriorities is that it is very difficult to control or modify the torque required for the rotation of the locking devices.

Brief summary of the invention

An object of the present invention is to provide an oscillating element for horological movement free from the limitations of known oscillating elements, in particular an oscillating element capable of oscillating with minimal torque and energy losses as reduced as possible.

Another object of the present invention is to provide an oscillating element for a watch movement capable of oscillating with a torque and energy losses as constant as possible.

Another object of the present invention is to provide an oscillating element based on a compiler link but which does not have the drawbacks of existing compliant links.

Another object of the present invention is to provide an oscillating element for a watch movement based on a compiler link and whose size in the plane of the oscillating functional component is as small as possible.

According to a first aspect of the invention, these objects are achieved by means of an oscillating element for a watch movement comprising: an axe; a component mounted on a first part of this axis so as to be rotatable with this axis; a compiling element mounted on a second part of the axis so as to allow said axis to rotate when the compiling element deforms elastically.

According to this aspect, this construction allows to separate the two functions of the oscillating element into two components on two different planes. The first functional component is on a first plane and the second component is constituted by an element compiling on another plane. The functional component in the foreground provides a function in the context of the watch movement; the second component compiling on the second plane provides no function other than that of "virtual" pivot for the axis of the first component. Preferably, the first and second parts of the axis are first and second ends of the axis respectively.

The compiling element therefore occupies no space in the first plane of the functional component. Both components can be made and dimensioned independently of each other, allowing uncompromising optimization of each component. The compiling element can for example be used with existing functional components, without modification of these components. The two components are linked to each other by an axis.

In addition, the compliant element acts on an axis (which is integral with the functional component) and not directly on the periphery of the functional component as is the case in the prior art. This is advantageous, for example for fragile components or that have complex shapes.

The expression "compliant element" designates in this text an element that allows a displacement of a part, for example a rotation of an axis, thanks to the elastic deformation, for example bending, of at least one part of the element. With respect to a bearing or a bearing for example, a compliant element can therefore operate without friction between the moving part (for example an axis) and fixed part.

Advantageously, the compliant element is made to allow rotation of an axis with a torque as low as possible. It therefore exerts no return force on the axis, or only a negligible return torque or in any case voluntarily chosen to be as low as possible, at least in the expected range of oscillations.

In an advantageous embodiment, the compliant element comprises two flexible beams forming a cross intersection. This construction minimizes clutter and facilitates synthesis and simulation. The beams may be for example straight beams.

Other types of compiling elements may also be used.

In the advantageous case of a cross compliant element, the axis is advantageously mounted at the intersection between said beams. One or preferably two ends of two adjacent branches of the cross may be attached to the frame of the movement by means of mounting points provided for this purpose. The mounting points may for example be openings for the driving or gluing of fixing pins. The one or both ends of the one or both limbs can thus be fixed relative to the frame, while the end of the two other limbs, as well as the point of intersection, can be movable when the limbs of the compliant element are deformed. .

An elastic prestressing element is advantageously provided in order to exert a prestressing force on the compliant element so as to modify the torque necessary for the rotation of said axis. Preferably, the prestressing is chosen so as to minimize the torque necessary for the rotation of the axis. Prestressing is advantageously exercised simultaneously on two adjacent branches of the cross of the compliant element.

The elastic prestressing element may be integrally bonded to the compliant element, or even form a single element, which facilitates assembly and alignment.

In the preferred case of a compliant element comprising two crossed beams forming a cross intersection with four branches X, the elastic prestressing element may exert a prestressing force on both ends of two adjacent branches of the cross .

This prestressing force can be exerted directly by the elastic prestressing element on the compliant element.

This prestressing force may be exerted by the elastic prestressing element on the compliant element through a support piece through two branches. This solution has the advantage of distributing the prestressing force on the two branches.

This prestressing force can be exerted by the elastic prestressing element on the compliant element through a support piece through two branches and an articulated connection. This solution has the advantage of allowing a relative displacement of the elastic prestress element with respect to the compliant element.

The elastic prestressing element may be shaped so as to comprise two strands. One end of each strand is rigidly connected to one end of a fixed branch of the cross, another portion of each strand exerts a prestressing force on the free end of another branch of the cross. Preferably, the elastic prestress element and the compliant element is at least partly in the same plane.

The elastic prestressing element being dimensioned and structured so as to exert a substantially constant prestressing force on the compliant element even when the compliant element is deformed. Calculations and simulations have shown that a constant prestressing force makes it possible to minimize the torque necessary for the rotation of the axis, and to prevent this torque from being dependent on the angular position.

The strands may be bonded to each other so as to form a ring.

The axis can be driven and / or glued into the component and / or the compiling element.

According to a second independent aspect of the invention, the aforementioned aims are achieved by means of an oscillating element for a watch movement comprising: a functional component; a compiling element which allows said functional component to rotate when the compliant element deforms elastically; and at least one resilient biasing element which exerts a prestressing force on the compliant element so as to modify the torque necessary for rotating the functional component.

In this case, the functional component and the compliant element may be in the same plane (at least partially) without necessarily being interconnected by an axis. Alternatively, the functional component and the compliant element can be in different planes linked together by an axis.

This second aspect may be combined with any or all of the characteristics of the solution as described, illustrated and claimed.

According to a third independent aspect of the invention, the aforementioned objects are achieved by means of an oscillating element for a watch movement comprising: a functional component; a compliant element which allows said functional component to rotate when the compliant element deforms elastically; said compliant element comprising at least two deformable beams which cross each other at a distance from their ends, so as to form a cross, the center of rotation of said functional component being in the center of said cross.

This arrangement of cross beams provides a central symmetry of the forces exerted by the deformable beams on the point of rotation.

In this case also, the functional component and the compliant element may be in the same plane (at least partially) without necessarily being interconnected by an axis. Alternatively, the functional component and the compliant element can be in different planes linked together by an axis.

In this case also, at least one elastic prestressing element may be optionally provided to exert a prestressing force on the compliant element so as to modify the torque necessary for the rotation of the functional component. This elastic prestressing element can act for example on the distal ends of the beams.

The component may be an escape anchor, preferably a Swiss anchor for Swiss anchor escapement.

According to an independent aspect, the invention also relates to a regulating member comprising a compliant oscillating anchor, for example an oscillating anchor by means of an oscillating element according to any of the embodiments described in this application, fixed on a door -Exhaust which also carries the escape wheel and, preferably, the balance shaft with the balance and the spiral.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> Fig. 1 <SEP> illustrates a perspective view of an oscillating element according to a first embodiment of the invention. <tb> Fig. 2 <SEP> illustrates a top view of an oscillating element according to the first embodiment of the invention. <tb> Fig. [SEP] illustrates a side view of an oscillating element according to the invention. <tb> Fig. FIG. 4 illustrates a perspective view of an oscillating element according to a second embodiment of the invention. <tb> Fig. <SEP> illustrates a perspective view of an oscillating element according to a third embodiment of the invention. <tb> Fig. [SEP] illustrates a top view of an oscillating element according to a fourth embodiment of the invention. <tb> Fig. 7 <SEP> is an exploded view of an oscillating element according to a fifth embodiment of the invention.

Example (s) of embodiment of the invention

A particular embodiment of the invention will now be described. In this preferred example, the functional component 2 that is to be oscillated at one end of the axis 3 is an anchor, more particularly a Swiss anchor for Swiss lever escapement. The element of the invention can however also be used to oscillate other components.

The anchor 2 comprises in this example two pallets 20A and 20B, a fork 21 and a dart 22. It may be made of steel or advantageously silicon or another material for manufacturing by one of the methods among photolithography processes, DRIE (abbreviation for "Deep Reactive Ion Etching") or LIGA (abbreviation for "Lithography, Galvanoformung, Abformung"). It is mounted on a first end of the axis 3 by driving, for example in the case of a metal anchor, or by gluing, for example in the case of a silicon anchor. Alternatively, the axis 3 and the anchor 2 can be formed in one piece. An anchor integrating the pallets and / or the stinger into a monolithic assembly can also be envisaged.

The axis 3 is not a conventional mobile axis which pivots in bearings. Instead, the oscillating element preferably comprises at the other end of the axis 3 a compliant element 4. In the embodiment of FIGS. 1 to 3, the compliant element is of the cross type and therefore comprises two rectilinear beams 5A, 5B which intersect at X. The axis 3 is mounted at the intersection between the two beams 5A, 5B, this intersection being coincidental with the center of rotation of the compliant element. Non-rectilinear beams may be used, including curved or bent beams. The four branches of the cross are referenced by the numbers 7A to 7D.

The distal ends of two adjacent branches 7A, 7B of the cross are provided with attachment points 6A, 6B to fix them on a portion of the frame of the movement, such as the plate, a bridge, an exhaust door, or a whirlpool cage. In a preferred embodiment, the oscillating element is fixed by means of pins or pins or screws inserted into these two attachment points. The oscillating element can be fixed on an exhaust-door which also carries the escape wheel and, preferably, the balance shaft with the balance and the hairspring. This configuration facilitates the alignment and mounting of various components of the regulating member.

In the illustrated embodiment, a connection element 60 is integrally connected to the distal end of the two branches 7A, 7B and provided with two attachment points 6A, 6B in the form of through holes. This configuration makes it possible in particular to move the fixing bridges with respect to the elastic beams 5A, 5B whose deformable length can thus be maximized.

Numerical simulations have demonstrated that the torque necessary to rotate the axis 3 can be controlled, and for example reduced or even minimized, by constantly exerting a force of stress on the beams 5A, 5B. In the embodiment of FIGS. 1 to 3, the two branches 7C, 7D are free and opposite to the two fixed branches 7A, 7B. In this case, a force of stress is exerted by means of an elastic element, here of an annular spring defining two strands 80A, 80B. This elastic element is advantageously integral with the two beams 5A, 5B of the cross. This monolithic solution allows in particular to facilitate the assembly and alignment of the various components. Note that with this solution, the center of rotation is not completely fixed, but the displacement of it is controlled, repeatable and generally lower than the traditional game of a pivot of a conventional anchor rod in a stone, which is typically between 4 μm to 14 μm.

The two strands 80A, 80B leave the connecting element 60 near the fixed ends of the cross and surround the two beams 5A, 5B so as to exert a prestressing force on the distal ends of the free branches 7C, 7D . More particularly, one end 81A, 81B of each strand is rigidly connected to one end of each fixed branch 7A, 7B of the cross. They are thus united in a single ring.

In this example, the elastic element 80A, 80B directly supports the points 81C, 81D against the distal ends of the branches 7C, 7D.

In a preferred embodiment, the prestressing force is exerted by the elastic member 80A, 80B through a support piece 9 which distributes and equalizes the pressure against the two branches 7C, 7D. This solution ensures equal pressure on the two branches 7C, 7D even in case of slight differences in length due for example to manufacturing imperfections. The support element 9 may be integral, monolithic with the two branches 7C, 7D.

An articulated connecting element 90 is advantageously pivotally connected on the one hand to the strands 80A, 80B, on the other hand to the support piece 9. This connecting element ensures a constant distance between these two elements. by allowing rotation relative to the blades 80A, 80B and relative to the part 9. In the illustrated example, it has a bone shape with a head, or epiphysis, approximately hemispherical at each end of a central portion. Each head collaborates with a corresponding dome in the strands 80A, 80B respectively in the support piece 9.

The prestressing force exerted by the strands 80A, 80B depends on the length of the connecting element 90 and the displacement it causes on the support piece 9 and on the ends of the branches 7C, 7D. For series production, an oscillating element can be delivered with several connecting elements of different lengths to adjust the prestressing force. The mounting of the oscillating element may comprise the choice of a connecting element 90 of suitable length among several connecting elements of different lengths. In a preferred embodiment, the ideal length of the connecting member 90 is determined by digital simulation once and for all during the design, and applied.

The compliant element is constituted in this example of two parts: the cross structure 5A, 5B with the elastic element 80A, 80B and the elements 9 and 60; and the connecting element 90. As in the other variants described below, these two parts can be made of steel, silicon, etc.

FIG. 4 illustrates a second variant of oscillating element 1 for watch movement. The oscillating component 2 is an anchor, represented without its pallets but which could naturally be equipped with pallets; other components could be used with this variant as well.

In this variant, the compliant element 4 comprises three flexible beams 5C, 5D 5E star about the axis 3. The elastic prestressing element 8 is constituted by three strands 80C, 80D, 80E forming a triangle, for example an equilateral triangle. The ends of the three beams are connected to the three respective points of the triangle.

Prestressing is therefore exerted in the same way on all three beams 5C to 5E. The end of the three beams is not blocked. One advantage is that the center of the axis 3 remains almost immobile even during rotation of the part 2.

The oscillating element 1 is fixed to the frame of the movement by the three mounting points 6C, 6D, 6E directly on the prestressing element 80C to 80E. In this example, the mounting points are linked to the media of the strands 80C to 80E. In this variant, it is a displacement applied on the strands 80C to 80E which creates the constraint. There is no support piece ("bone").

Compiling elements with a number of star arms different from three can be envisaged, for example compilants with 2, 4, 5, .. N star arms around the axis 3. The angular space between the different ras is preferably constant and equal to 360 ° / N.

FIG. 5 illustrates a third variant of compliant element 4 intended to be integrated in an oscillating element for watch movement. As in the first variant, the compliant element 4 comprises two beams 5A, 5B forming a cross about the axis 3. The oscillating component, for example an escapement anchor or a gear not shown, is intended to be mounted on the axis 3 in another plane than the compliant element 4.

The two beams 5A, 5B X form four branches 7A to 7D whose ends are connected two by two thanks to the connection elements 60 and 61, respectively.

A resilient ring preload member 8 has two strands 80A, 80B which join the center of the connecting member 60 with the center of the connecting member 61, forming a ring. This elastic element 8 exerts a prestressing force directly on the distal ends of the four branches 7A to 7D. More particularly, one end 81A, 81B of each strand is rigidly connected to one end of each fixed branch 7A, 7B of the cross. No connecting part 9 is used between the prestressing element and the connecting elements 60, 61.

The compliant element 4 is mounted on the frame of the movement with two mounting points 6F, 6G directly on the constraint element 8, for example in the middle of the strands 80A respectively 80B. Like the second variant, the amplitude of the prestressing force is identical on all the beams. The center of the axis 3 remains motionless even when rotating the workpiece 2.

FIG. 6 illustrates a fourth compliant element variant 4 intended to be integrated into an oscillating element for a watch movement. This variant corresponds to the third variant, except that the free ends of the four branches 7A to 7D are connected to the prestressing element 8 by means of two support pieces 9A, 9B connecting the branches two by two, and bone-shaped connecting members 90A, 90B bonding these support members 9A, 9B to the strands 80A, 80B of the prestressing member. These connecting elements allow a displacement according to several degrees of freedom of the prestressing element 8 relative to the support parts 9A, 9B and with respect to the end of beams. In this variant, it is a displacement applied on the support pieces 9A, 9B which creates the constraint.

The shape and structure of the elastic element is optimized, for example by successive approximations, so that the prestressing force remains substantially constant even when the various beams of the compliant element deform, throughout the usual deformation range. This ensures that the restoring torque exerted on the axis 3 is independent of its angular position. In one embodiment, the thickness of the strands 80A, 80B is irregular to achieve this objective.

FIG. 7 illustrates a fifth variant compliant element 4 intended to be integrated in an oscillating element for clock movement. This variant differs from that of FIG. Mainly by the shape of the elastic prestressing element; the other elements may be identical to those described in relation to FIG. 5 and will not be described.

The elastic prestressing element 8 is formed of two arms 80A, 80B which do not meet directly, but connect together pairs of points on the connection elements 60, 61. More specifically, the arm 80B connects the point 600 near one end of the connecting member 60 with the point 610 near the corresponding end of the other connecting member 61; the arm 80A connects the point 601 near one end of the connection element 60 with the point 611 near the corresponding end of the other connection element 61

The mounting points 6H, 61 of the constraint element 8 on the frame are on the prestressing element 8, as in FIG. 5. However, these mounting points are not directly in the middle of the strands 80A, 80B, but are connected to these strands by elastic elements 80C respectively 80D. In this example, each of the resilient members 80C, 80D is constituted by a ring one point of which is connected to a strand 80A, respectively 80D, and another point to 180 ° is bound to one side of a mounting point 6H, 61 opposite to the strand. In this way, the mounting points 6H, 61 do not limit or almost no freedom of the strands 80A, 80B to move, which allows the constraint element 8 as a whole to exert a greater stress on the compliant element 4.

As illustrated in FIG. 7, the compliant element 4 can be assembled on a plate 11 made for example of LIGA and having pads 110 for receiving the mounting points 6H, 61. The plate 11 can be mounted on the frame of the movement or be part of this building. This plate 11 makes it possible to obtain better control of the prestressing applied to the compliant element 4 by better precision of the spacings between the studs 110. More particularly, the studs 110 and the plate 11 preferably form one single piece, as well as misalignment during assembly can be practically. In addition, we obtain a greater ease of assembly of the assembly on the frame of the movement, and therefore the replacement of this set if necessary. Finally, this plate can be integrated into an exhaust door, and it can be used to adjust the position of the anchor by moving the plate on the movement frame. This plate 11 may be used in combination with oscillating elements different from that of FIG. 7, for example with an oscillating element according to any embodiment according to one of FIGS. 1 to 6.

All embodiments described above comprising a compliant element in a first plane connected by an axis to a functional component in another plane. It is possible to modify these embodiments so that the compliant element and the functional element are wholly or partly in the same plane.

For example, it is possible to provide an oscillating element for a watch movement comprising a functional component, a compliant element in the same plane and which allows this functional component to rotate when the compliant element deforms elastically, and at least an elastic prestressing element which exerts a prestressing force on the compliant element so as to modify the torque necessary for the rotation of the functional component.

The elastic prestressing element may be in the same plane as the compliant element, and / or in the same plane as the functional component, or in another plane.

In this case, the functional component and the compliant element may be in the same plane (at least partially) without necessarily being interconnected by an axis. Alternatively, the functional component and the compliant element can be in different planes linked together by an axis.

In the same way, it is also possible to produce an oscillating element for a watch movement comprising a compliant element 4 formed of several beams 5A, 5B which intersect, the point of intersection of the beams defining a center of rotation for a functional component in the same plane or plane other than the compliant element. The number of beams can be two, three, etc. The beams are advantageously arranged symmetrically around the center of rotation. An elastic prestressing element 8 may optionally be provided to exert a prestressing force on the distal ends of the beams, so as to modify the torque necessary for rotating the functional component.

Claims (22)

Oscillating element (1) for a watch movement comprising: an axis (3); a component (2) mounted on a first portion of said axis (3) so as to be rotatable with said axis; a compliant element (4) mounted on a second part of the axis (3) so as to allow this axis to rotate when said compliant element deforms elastically. 2. Element according to claim 1, wherein the compliant element (4) comprises a plurality of flexible beams (5A, 5B) forming an intersection, said axis (3) being mounted at the intersection between said beams. 3. Element according to claim 2, wherein the compliant element (4) comprises two flexible beams (5A, 5B) forming a cross intersection, said axis (3) being mounted at the intersection between said beams. 4. Element according to one of claims 2 or 3, the compliant element (4) comprising at least one mounting point (6A, 6B) rigidly connected to the ends of two adjacent branches (7A, 7B) of said cross and for mounting said oscillating element on a frame of the watch movement. 5. Element according to one of claims 2 to 4, comprising a bearing element (60) in simultaneous support against two adjacent branches (7A, 7B) of said cross. 6. Element according to claim 5, said support element comprising at least one mounting point (6A, 6B) for mounting on a frame of the watch movement. 7. Element according to one of claims 1 to 6, comprising a resilient biasing element (8) for exerting a prestressing force on the compliant element (4) so as to modify the torque required for rotation of said axis (3). 8. Element according to claim 7, said elastic prestress element (8) being integrally bonded to the compliant element (4). 9. Element according to claim 8, said elastic prestress element (8) and the compliant element (4) forming a single element. Element according to one of claims 7 to 9, the compliant element (4) having at least one mounting point (6C-6D; 6F-6G, 6H-6I) connected to said elastic prestress element (8) and for mounting said oscillating element on a frame of the watch movement. 11. Element according to claim 10, said at least one mounting point (6h-6l) being connected via an elastic connection (80C, 80D) to said elastic prestressing element (8). 12. Element according to one of claims 5 to 11, the compliant element (4) comprising two beams (5A, 5B) forming a cross intersection with four branches (7A, 7B, 7C, 7D), said elastic member of prestressing (8) exerting a prestressing force on both ends of exactly two adjacent branches (7C, 7D) of said cross. 13. Element according to one of claims 5 to 11, the compliant element (4) comprising two beams (5A, 5B) forming a cross intersection with four branches (7A, 7B, 7C, 7D), said elastic member of preload (8) exerting a prestressing force on the ends of each of these four branches. 14. Element according to one of claims 5 to 11, the compliant element (4) having three star branches (5A to 5C), said resilient biasing element (8) exerting a prestressing force on the free ends of each of these three branches. 15. Element according to one of claims 11 to 14, said elastic biasing element (8) having at least two strands (80A, 80B), one end (81 A, 81B) of each strand being rigidly connected to one end of one of said branches. 16. Element according to claim 15, said strands (80A, 80B) being pressed against said free ends of two branches (7C, 7D) of said cross by means of a support piece (9). 17. Element according to claim 15, said support piece (9) being bonded to said strands (80A, 80B) via an articulated connection (90). 18. Element according to one of claims 15 to 17, said strands (80A, 80B) being bonded to each other so as to form a ring. 19. Element according to one of claims 14 to 18, comprising a first bearing element (60) in simultaneous support against two adjacent branches (7A, 7B) of said cross, a second bearing element (61) in support simultaneous against two adjacent branches (7C, 7D) of said cross, each of said strands (80A, 80B) connecting the first support member (60) with the second support member (61). 20. Element according to one of claims 7 to 19, said elastic prestressing element (80A, 80B) being dimensioned and structured so as to exert a substantially constant prestressing force on the compliant element (5A, 5B) even when the compliant element is deformed. Element according to one of the preceding claims, the axis (3) being driven out or adhered in the component and / or in the compliant element. 22. Element according to one of the preceding claims, said component being an anchor.