CH709908A1 - Landing shock absorber for a timepiece. - Google Patents

Abstract

The shock absorbing bearing comprises a one-piece piece (1) defining a central portion (4), a peripheral portion (5) and an elastic member (6) connecting the central portion (4) to the peripheral portion (5). The central portion (4) has a hole (7) for receiving a pivot. The elastic member (6) comprises a movable intermediate portion (11) surrounding the imaginary axis (13), a first spring (10a) comprising at least one elastic arm (12a) connecting the central portion (4) to the intermediate portion mobile (11) and a second spring (10b) comprising at least one elastic arm (12b) connecting the movable intermediate portion (11) to the peripheral portion (5). The first and second springs (10a, 10b) have different stiffnesses in at least one of the direction of the imaginary axis (13) of the hole (7) and the radial direction with respect to this imaginary axis (13) .

Description

The present invention relates to a shock absorbing bearing for a timepiece.

[0002] In watchmaking, the pivots of the axes of the mobiles rotate in bearings mounted in the plate or in bridges. For some mobiles, particularly the balance, it is customary to equip the bearings with a shock-absorbing system. Indeed, as the pivots of the axis of a beam are generally thin and the weight of the balance is relatively high, said pivots can break under the effect of a shock in the absence of damper system.

[0003] Patent application EP 2015 147 A2 discloses a shock-absorbing bearing comprising a one-piece piece itself comprising a central part, a peripheral part and a resilient member connecting the central part to the peripheral part. The central portion has a hole for receiving a pivot. The elastic member comprises elastic arms wound spirally. This one-piece piece is fixed in a cup-shaped intermediate piece mounted in a frame member (plate, bridge), or is fixed directly in the frame member. In an alternative embodiment, illustrated in FIGS. 9 and 10 of this document EP 2015 147 A2, the elastic member comprises laced arms each connecting the central portion of the one-piece piece to the central portion of a respective circular elastic ring segment supported by its two ends against the inner wall of the intermediate piece. Each lacy arm forms with the respective elastic segment a spring. In a small shock, the elastic segments participate in the deformation and the displacement of the axis of the mobile is relatively important. As soon as the central part of an elastic segment comes into contact with the intermediate part, thereby stopping the deformation of the elastic segment, the active length of said spring is reduced and the restoring force is increased. The displacement of the axis of the mobile during a great shock is therefore smaller, in proportion, than during a small shock. This feature improves the effectiveness of the anti-shock system.

However, the design of this bearing, with its elastic arms laces and its peripheral elastic segments, offers in practice little flexibility to obtain a displacement / force curve of the desired impact. In addition, the stressing of the lace arms and peripheral elastic segments by the intermediate piece during assembly makes said curve dependent on the machining accuracy of the intermediate piece. Another disadvantage of this bearing is that it is able to differentiate small and large shocks only in the radial direction. To obtain the same effect in the axial direction, a particular assembly, with an additional monoblock piece superimposed, is proposed. This assembly increases the size and complicates the manufacture.

The present invention aims to remedy, at least in part, the aforementioned drawbacks and proposes for this purpose a shock absorbing bearing for a timepiece, comprising a one-piece piece defining a central portion, a peripheral portion and an elastic member connecting the central portion to the peripheral portion, the central portion having a hole for receiving a pivot, characterized in that the elastic member comprises at least one movable intermediate portion surrounding the imaginary axis of said hole, a first spring comprising at least an elastic arm connecting the central portion to a first movable intermediate portion and a second spring comprising at least one elastic arm connecting either the first movable intermediate portion or another intermediate portion movable to the peripheral portion, and in that the first and second springs have different stiffness in at least one of the direction said imaginary axis and the radial direction with respect to said imaginary axis.

[0006] Preferably, the first and second springs have different stiffnesses both in the direction of said imaginary axis and in the radial direction with respect to said imaginary axis.

In a particular embodiment, the stiffness of the first spring in the direction of said imaginary axis and in the radial direction relative to said imaginary axis is smaller than that of the second spring.

Typically, the first and second springs have different heights. By the term "height" is meant in the context of the present invention the dimension in the direction of said imaginary axis.

The height of each of the first and second springs can be constant.

Alternatively, the height of the elastic member may vary gradually.

The or each elastic arm of each of the first and second springs can be spirally wound around said imaginary axis.

The first and second springs may each comprise a plurality of resilient arms. In this case, said elastic arms are preferably regularly distributed around said imaginary axis.

Stoppers may be provided on the at least one of the movable intermediate portions and / or on the peripheral portion to limit the deformation of at least one of the first and second springs.

[0014] Preferably, said hole is blind.

Also preferably, the or each mobile intermediate portion and / or the peripheral portion are rigid, that is to say that they do not deform or almost not in the direction of said imaginary axis and in the radial direction with respect to said imaginary axis.

The one-piece part may be made of silicon, amorphous metal alloy or nickel alloy or nickel-phosphorus, for example.

In a particular embodiment, the shock absorbing bearing comprises a single movable intermediate portion.

Other features and advantages of the present invention will appear on reading the following detailed description with reference to the accompanying drawings, in which: <tb> fig. 1 <SEP> is a sectional view of a shock absorbing bearing according to a first embodiment of the invention mounted on a frame member of a movement of a timepiece; <tb> fig. 2 <SEP> is a plan view from above of a one-piece part forming part of the bearing illustrated in FIG. 1; <tb> fig. 3 <SEP> is a perspective view of said one-piece piece; <tb> fig. 4 <SEP> shows a curve of displacement of a pivot according to the force of the shock obtained with the bearing according to the invention; and <tb> fig. <SEP> is a cutaway perspective view of a one-piece part forming part of a bearing according to a second embodiment of the invention.

[0019] Referring to FIG. 1, a shock absorbing bearing for a timepiece according to a first embodiment of the invention comprises a single piece 1 fixed in a hole 2 of a frame member 3 such as a plate or a bridge. The one-piece piece 1 has the shape of a circular plate of variable height. It may be made in a silicon (monocrystalline or polycrystalline) plate or other crystalline material by a known etching process. The one-piece piece 1 may alternatively be made of an amorphous metal alloy (metal glass), for example by casting and molding, or in a nickel or nickel-phosphorus alloy compatible with the LIGA manufacturing process. The frame member 3 may itself be made of a conventional metal such as brass.

With reference to FIGS. 1 to 3, the one-piece part 1 comprises a central portion 4, a peripheral portion 5 and an elastic member 6 connecting the central portion 4 to the peripheral portion 5. The central portion 4 has a blind hole 7 for receiving a pivot 8 d a mobile axis 9, such as a balance shaft. The peripheral portion 5 has an annular shape and is dimensioned to be fixed, for example by gluing, in the hole 2 of the frame member 3. The elastic member 6 comprises a first spring 10a, a second spring 10b and a mobile intermediate portion 11 of annular shape surrounding the central portion 4 and providing the connection between the first and second springs 10a, 10b. The central, peripheral and intermediate portions 4, 5, 11 are typically rigid, and they are at least stiffer than the first and second springs 10a, 10b.

Each of the springs 10a, 10b comprises elastic arms 12a, 12b spirally wound around the common imaginary axis 13 of the hole 7, the one-piece piece 1 and the mobile axis 9. Each arm 12a of the first spring 10a is joined to the central portion 4 at one of its ends and to the movable intermediate portion 11 at its other end. Each arm 12b of the second spring 10b is joined to the movable intermediate portion 11 at one of its ends and to the peripheral portion 5 at its other end. The arms 12a, 12b of each of the springs 10a, 10b are regularly distributed around the imaginary axis 13 and, in the example shown, are three in number. The spiral shape of each arm 12a, 12b may comprise two arcs of circle centered on the imaginary axis 13, of different radii and connected to each other, as shown.

As already mentioned and visible in Figs. 1 and 3, the height of the single piece 1 is variable. More specifically, the assembly consisting of the central portion 4 and the first spring 10a has a height h1 less than the height h2 of the assembly constituted by the movable intermediate portion 11, the second spring 10b and the peripheral portion 5, thereby defining a central recess 14 in the surface of the one-piece piece 1 facing the mobile carried by the axis 9. By this difference in height, the springs 10a, 10b have different stiffnesses, the stiffness of the second spring 10b being larger than the stiffness of the first spring 10a. This difference in stiffness is valid both in the axial direction (that is to say for shocks received by the axis of mobile 9 in the direction of the imaginary axis 13) and in the radial direction (c ' that is to say for shocks received by the mobile axis 9 in any of the radial directions with respect to the imaginary axis 13). This results in a different damping according to the force of the shock, as will be explained below. In a variant, the central recess 14 could be formed in the surface of the one-piece piece 1 opposite that facing the mobile carried by the axis 9.

Advantageously, bumps 15 are provided on the outer surface of the movable intermediate portion 11 and on the inner surface of the peripheral portion 5 to serve as radial stops to the arms 12b of the second spring 10b limiting the deformation of the latter . Such bumps could also be provided on the inner surface of the movable intermediate portion 11 and on the surface of the central portion 4 to limit the deformation of the arms 12a of the first spring 10a.

The bearing according to the invention further comprises, typically, axial stops and radial to prevent deformation of the elastic member 6 beyond a certain limit. These stops are defined by a washer 16 fixed to the frame member 3 and whose central hole 17 is traversed with a certain clearance by the mobile axis 9, more precisely by a tigger 18 of this axis carrying the pivot 8. The wall of the hole 17 constitutes the radial abutment, against which the tigeron 18 can come to rest during a large radial shock. The surface 19 of the washer 16 facing the mobile carried by the axis 9 constitutes the axial abutment, against which a shoulder 20 of the axis 9 can come to bear during a large axial impact.

FIG. 4 shows the radial or axial displacement curve of the pivot 8 as a function of the impact force, obtained with the bearing according to the invention. In normal operation of the timepiece, that is to say for shocks of force below a threshold S1 (trigger threshold), the forces generated by the acceleration of the mass of the mobile are less than the force of the first spring 10a, there is therefore no movement of the elastic member 6. In case of low shock, above the trigger threshold S1 and below a threshold S2, the force due to the acceleration of the mass of the mobile is greater than that of the first spring 10a and lower than that of the second spring 10b. The axis of mobile 9 moves by deforming the first spring 10a without deforming the second spring 10b or moving the movable intermediate portion 11, and without coming into contact with the washer 16. The shock is thus slowed down, which avoids too much effort 8. In case of a stronger shock, above the threshold S2 and below a threshold S3, the force due to the acceleration of the mass of the moving body is greater than that of the second spring 10b. Therefore, the movable intermediate portion 11 is moved, the second spring 10b is biased and the restoring force exerted by the elastic member 6 becomes larger, which further slows the shock. In the event of a very strong shock, above the threshold S3, the mobile axis 9 abuts against the washer 16.

Playing on the dimensions of the springs 10a, 10b, it is possible to obtain quite easily the shape that is desired for the curve of FIG. 4 (position of the thresholds S1, S2, S3, slope of the curve, etc.). In particular, the height of the springs 10a, 10b is an easily manipulated parameter. However, in addition to the height or as an alternative thereto, other parameters such as the thickness of the arms 12a, 12b can be varied. In fig. 2 it can be seen that the thickness of the arms 12b of the second spring 10b is greater than that of the arms 12a of the first spring 10a to compensate for the fact that the arms 12b have a greater length than the arms 12a.

The height of each of the springs 10a, 10b is not necessarily constant. Fig. 5 illustrates a second embodiment of the invention in which the height of the elastic member 6, and even of the one-piece piece V as a whole, varies progressively, giving for example to the surface of the one-piece piece opposite to the surface turned towards the mobile, a bowl shape.

The number of springs 10a, 10b in the bearing according to the invention is not necessarily limited to two. It can be equal to three, four, etc. Thus, the second spring 10b could connect the movable intermediate portion 11 to a second movable intermediate portion, and a third spring could connect the second movable intermediate portion to the peripheral portion 5.

In addition, the stiffness of the springs 10a, 10b can be reversed. In other words, the springs located closer to the central portion 4 could have a high stiffness and the springs located closer to the periphery 5 could have a small stiffness.

The one-piece character of the part 1 facilitates the mounting of the bearing. The bearing according to the invention does not need an intermediate piece or cage between the one-piece piece 1 and the frame member 3 (see Fig. 1). However, the use of such an intermediate part is not excluded in the present invention.

To improve the contact between the pivot 8, generally made of steel, and the one-piece piece 1, a coating of a material known for its good tribological properties can be formed on the single piece 1 (or only on the wall of his hole 7) and / or on the pivot 8. In the case of a one-piece piece 1 of silicon, said material may be sapphire, diamond, amorphous carbon (DLC: Diamond-Like Carbon) or oxide of silicon.

Claims (15)

1. Shock absorber bearing for a timepiece, comprising a one-piece piece (1) defining a central portion (4), a peripheral portion (5) and an elastic member (6) connecting the central portion (4) to the part peripheral (5), the central portion (4) having a hole (7) for receiving a pivot (8), characterized in that the elastic member (6) comprises at least one movable intermediate portion (11) surrounding the imaginary axis (13) of said hole (7), a first spring (10a) comprising at least one elastic arm (12a) connecting the central portion (4) to a first movable intermediate portion and a second spring (10b) comprising at least one elastic arm (12b) connecting either the first movable intermediate part or another movable intermediate part to the peripheral part (5), and in that the first and second springs (10a, 10b) have different stiffnesses in at least one the direction of said imaginary axis (13) and the radial direction with respect to said imaginary axis (13). Shock absorber bearing according to Claim 1, characterized in that the first and second springs (10a, 10b) have different stiffnesses both in the direction of said imaginary axis (13) and in the radial direction with respect to said axis. imaginary (13). Shock absorbing bearing according to Claim 1 or 2, characterized in that the stiffness of the first spring (10a) in the direction of said imaginary axis (13) and in the radial direction with respect to said imaginary axis (13) is smaller. than that of the second spring (10b). 4. shock absorbing bearing according to one of claims 1 to 3, characterized in that the first and second springs (10a, 10b) have different heights. Shock absorbing bearing according to claim 4, characterized in that the height of each of the first and second springs (10a, 10b) is constant. 6. shock absorbing bearing according to claim 4, characterized in that the height of the elastic member (6) varies gradually. 7. shock absorbing bearing according to one of claims 1 to 6, characterized in that the or each elastic arm (12a, 12b) of each of the first and second springs (10a, 10b) is wound in a spiral about said imaginary axis (13). 8. shock absorbing bearing according to one of claims 1 to 7, characterized in that the first and second springs (10a, 10b) each comprise a plurality of resilient arms (12a, 12b). 9. shock absorbing bearing according to claim 8, characterized in that the resilient arms (12a, 12b) of each of the first and second springs (10a, 10b) are regularly distributed around said imaginary axis (13). 10. shock absorbing bearing according to one of claims 1 to 9, characterized in that it comprises stops (15) on the or at least one of the movable intermediate portions (11) and / or on the peripheral portion (5) for limiting the deformation of at least one of the first and second springs (10a, 10b). 11. shock absorbing bearing according to one of claims 1 to 10, characterized in that said hole (7) is blind. 12. shock absorbing bearing according to one of claims 1 to 11, characterized in that the or each movable intermediate portion (11) is rigid. 13. shock absorbing bearing according to one of claims 1 to 12, characterized in that the peripheral portion (5) is rigid. 14. shock absorbing bearing according to one of claims 1 to 13, characterized in that the single piece (1) is silicon, amorphous metal alloy, or nickel or nickel-phosphorus alloy. 15. shock absorbing bearing according to one of claims 1 to 14, comprising a single movable intermediate portion (11).