CH707343A2 - Shock-proof bearing for timepiece, has chimney pivoting about axis perpendicular to bearing axis upon receiving force exerted by pivot, so that chimney is in contact with cup on side of median plane perpendicular to radial component - Google Patents

Abstract

The bearing has a cup (10) assembled on a frame of a timepiece, and defining an inner cavity (12) with an opening (14) to receive a shank (15). A tubular chimney (18) is placed at the center of the cavity. An elastic element (28) exerts axial force on the chimney. The chimney pivots about an axis perpendicular to a bearing axis upon receiving a force exerted by a pivot (16), so that the chimney is in contact with the cup on a side of a median plane perpendicular to a radial component, where the contact is at a single contact point or two contact points on the outer surface of the chimney.

Description

Technical area

The present invention relates to the field of watchmaking. It relates, more particularly, an anti-shock bearing. Watchmakers are pivoted in bearings by means of pivots which one tries to reduce the rays, in order to minimize the energetic losses. Since such pivots are fragile, the stresses they undergo in the event of shocks may cause them to break.

State of the art

It is known to make anti-shock bearings to protect the pivots in case of shocks. These bearings are arranged to allow movement of the ends of the pivot, this movement allowing a tigeron extending the pivot, to absorb the impact when it abuts against a stationary part of the bearing. An elastic member ensures a return of the pivot to its normal operating position.

[0003] Many embodiments of such bearings are known. Some of them have a pierced stone with an opening through which the end of the pivot takes place. A counter-pivot stone overcomes the pierced stone to provide axial guidance of the pivot. Generally, it is on the counter-pivot stone that the elastic member exerts its restoring force. A kitten, in which is housed at least the counterpoise stone, moves by sliding on bearing surfaces which, in some bearings, have conical portions. In the event of a radial shock, the kitten can then, while moving on the conical portions, tilt around a virtual point of rotation situated substantially at the intersection of the perpendiculars to the conical portions passing through the points of contact of the kitten and portions conical. It may happen that the elastic member can not bring the kitten down flat. In such a case, the walking of the watch may be disturbed. Examples of bearings of these types are disclosed in documents FR 1 060 383, in which the kitten houses exclusively the counterpivot, and CH 265 111, in which the kitten houses the two stones.

The present invention aims to provide a shockproof bearing free of the aforementioned drawbacks.

Disclosure of the invention

More specifically, the invention relates to an anti-shock bearing for a timepiece comprising: A cup defining an interior cavity, in the center of which is formed an opening adapted to receive a tigeron of a watchmaker and defining an axis of the bearing, A tubular chimney arranged, when the bearing is in a predefined rest position, substantially in the center of the internal cavity, - A pivot member associated with said chimney and adapted to receive a pivot extending the tigeron, - At least one resilient member arranged to exert on said tubular chimney at least one axial force parallel to said axis and tending to maintain or return the chimney in said predefined rest position.

The bearing is arranged so that the chimney, when it receives a force exerted by the pivot and whose value of the radial component is greater than a trigger value, pivots about an axis substantially perpendicular to the axis of the bearing so that the chimney is in contact with the cup on one side of a median plane perpendicular to said radial component

As will be understood from the description below, the term "exercise" should here be interpreted as encompassing a direct action and an indirect action.

Brief description of the drawings

Other details of the invention will appear more clearly on reading the description which follows, given with reference to the accompanying drawing in which: <tb> figs. 1a, 1b, 2a, 2b, 3a and 3b <SEP> propose three embodiments according to the invention, the figures indexed a being sectional views and the indexed figures b being perspective views, <tb> figs. 4a, 4b and 4c <SEP> propose an additional embodiment and illustrate the operation of a bearing according to the invention, and <tb> figs. 5a, 5b and 5c on the one hand, and figs. 6 and 7, on the other hand, <SEP> represent other variants of the invention; <tb> figs. 8 and 9, on the one hand, and figs. 10 and 11, on the other hand, <SEP> still represent other variants of the invention.

Embodiment of the invention

[0009] FIG. 1, a first embodiment of the invention. Such an anti-shock bearing comprises a cup 10 intended to be assembled on a timepiece frame, formed by a bridge or a deck not shown. This cup 10 can be driven into an ad-hoc recess that includes the frame. It can also be formed directly in the frame and be integral with it. The cup 10 defines an interior cavity 12, in the center of which is formed an opening 14 adapted to receive a tigeron 15 extending a pivot 16 of a watchmaker. The center of this opening 14 defines the axis of the bearing.

The bearing also comprises a tubular chimney 18 arranged, when the damping bearing is in a predefined rest position, in the center of the inner cavity 12. In this embodiment, the bottom of the inner cavity 12 is provided with a clearance 20 in which takes place with a slight clearance, the base of the tubular chimney 18. A wall of the clearance 20 defines a radial stop for the tubular chimney 18, that is to say a stop in a plane perpendicular to the bearing axis limiting the radial displacements of the base of the tubular chimney 18. However, care will be taken to ensure that the clearance allows a minimum displacement of the tubular chimney 18, otherwise the tubular chimney 18 would be static and the shocks suffered will not be able to The cup 10, and more particularly in this example, the recess 20, defines an axial abutment for the tubular chimney 18, that is to say a goal in the direction determined by the bearing axis. Thus, these radial and axial stops together predefine the rest position of the shockproof bearing.

The tubular chimney 18 may, as in the example shown in FIG. 1, receive a flange 22 serving as a support for an elastic member 28 which will be described later. The collar may be located at any level of the chimney.

The bearing also comprises a pivoting member intended to cooperate with the pivot 16. In the proposed example, the pivot member comprises a pierced stone 24 disposed in the tubular chimney 18 and having a hole located substantially in the axis of the bearing in which can take place the end of the pivot 16. The pivot member also comprises a counter-pivot stone 26 disposed at least partially in the chimney, on the side of the pierced stone 24 opposite the cup 10 The end of the pivot 16 can come to bear on the counter-pivot stone. Thus, in this example, the pierced stone 24 and the counter-pivot stone 26 are mounted rigidly in the tubular chimney 18 and their relative position / orientation, one with reference to the other, is fixed.

The bearing is further provided with at least one aforementioned elastic member 28, interposed between the tubular chimney 18 and the cup 10 and arranged to exert on said tubular chimney 18 at least one axial force, tending to maintain or bring back the tubular chimney 18 in the predefined rest position. In the rest position of the bearing, the elastic member 28 is preferably prestressed so that a triggering force is necessary to set in motion the tubular chimney 18. The axial force exerted by the elastic member 28 in the position of rest, defines a trigger value, in the axial case. The force exerted by the elastic member 28 in the rest position creates a moment of force at the points of contact of the chimney on the cup 10, which defines a trigger value, in this case radial.

Note that the presence of a radial abutment as mentioned above, is not necessary if the friction exerted between the tubular chimney 18 and the cup 10 under the prestressing of the elastic member are sufficient to ensure a radial holding of the tubular chimney 18.

In the variant proposed in FIG. 1, several elastic members 28 are angularly distributed around the tubular chimney 18. The elastic members are flexible blades whose one end is integral with the cup 10 and the second end is free and cooperates with the tubular chimney 18. The blades may be reported on the cup or be arranged on a ring 34 fitted inside the cavity of the cup 10. Advantageously, one can realize the blades integrally with the ring. The blades can exert their support on the collar, but also on the end of the chimney or on a groove formed on the periphery thereof. In these cases, we could do without collar. The chimney may then comprise a toric zone, disposed at its periphery, at least in the areas where the elastic members cooperate with it. Preferably, the upper end of the chimney, that is to say located on the opposite side to the mobile, receives over its entire periphery, a ridge shaped half-torus. The elastic members are thus supported on a toric portion, which promotes the working conditions between them and the chimney.

In the embodiment of FIG. 1, the elastic member is also capable of generating a radial force on the tubular chimney 18.

In FIG. 4, another embodiment shown diagrammatically is proposed. The elastic member 28 acts on the tubular chimney 18, either directly or via the stone against pivot, being interposed between one of these elements and a fixed bridge of the cup. Where appropriate, the cup 10 may have a shape adapted to cover the tubular chimney 18 and provide a support adapted to the elastic member 28, which exerts an axial force on the chimney.

The description of the operation given below with reference to FIGS. 4a, 4b and 4c can be transposed to the other embodiments. Thus, as shown in FIG. 4a, in the absence of shock, the tubular chimney 18 is in its rest position predefined by the axial abutment and, where appropriate, by the radial abutment. The forces exerted by the elastic member 28 and the cup 10 are canceled and the tubular chimney 18 does not move. In the event of an axial impact (FIG 4b), the tubular chimney 18 moves only if the force exerted by the pivot 16 on the counter pivot stone 26 is greater than the axial release value. The elastic member 28, after an impact, thus brings the chimney back to its rest position.

In the event of a radial shock (FIG 4c), the configuration of the bearing makes such a shock is likely to cause a rolling of the tubular chimney 18 with respect to a fulcrum on the bottom of the cup 10. The tubular chimney 18 moves in rolling motion only if the radial component of the force exerted by the pivot 16 on the pierced stone 24 creates a moment of force relative to said point of support of the chimney on the cup 10, greater than the radial trigger value. The chimney rolls about an axis substantially perpendicular to the axis of the bearing, and rises, so that the chimney is in contact with the cup only on one side of a median plane P perpendicular to said component radial.

Thus, in this embodiment, the energy of a radial shock induces a substantially rotational movement and not rotation and translation, as in anti-shock bearings of the state of the art. It should further be noted that, in bearings with conical surfaces, if a translation on the conical surfaces can induce a tilting of the chimney, this is not done with reference to the points of contact between the cup and the chimney. It will also be noted that the tilting of the chimney in the systems of the state of the art is in the opposite direction to that observed with an anti-shock bearing according to the invention. Indeed, as illustrated in FIG. 4c, the end of the chimney carrying the pivoting members, moves in the same direction as the moment of force created by said component, while the same end is to be driven in the other direction in a bearing of the state of the art.

If, in addition, the force exerted by the pivot 16 is greater than the static friction force exerted at the interface between the chimney and the cup 10, the tubular chimney 18 will not move more only by rolling, but by sliding in a radial direction. The radial displacement of the base of the tubular chimney 18 is, however, limited by the radial abutment or the radial retention provided by the friction exerted between the tubular chimney 18 and the cup 10, as mentioned above. The tubular chimney 18 is therefore able to rotate by rolling or sliding. The elastic member 28 is thus constrained and, after an impact, returns the chimney to its rest position. Note that a bearing of the tubular chimney 18 on the cup 10 also induces axial stress since the elastic member 28 is axially constrained. The elastic member 28 can thus act effectively also on a combined impact, radial and axial. Advantageously, the return of the tubular chimney 18 to the rest position is done safely, without risk that the chimney may be flat with reference to the pivot, especially since the bearing does not have a conical surface. The radial displacement of the base of the chimney being limited, the recourse even to a refocusing system becomes superfluous, the refocusing is done automatically when returning the tubular chimney 18 to its rest position.

In another embodiment proposed in FIG. 2, the tubular chimney 18 is not arranged in a recess 20, but on a flange 32 bordering Cover 14. In this variant, the chimney does not comprise flange 22.

The elastic member 28 is formed integrally with a ring 34 fitted inside the cavity of the cup 10. Advantageously, it can also be integral with the tubular chimney 18. The elastic member 28 comprises one or more arms, extending between the chimney and the ring 34. The point of attachment of the elastic member on the ring 34 may be at a lower level, that is to say closer to the bottom of the cup, relative to the point of attachment of the elastic member on the tubular chimney 18, to create an axial prestress on the tubular chimney 18. It is expected that the ring 34 is split and introduced into the cup 10 with radial prestressing on the arms of the elastic member.

In this variant, the axial abutment is always formed by the cup 10, in this case by the flange 32. The radial abutment is formed by the stiffness of the elastic member 28.

In another embodiment proposed in FIGS. 3a and 3b, the elastic member 28 is housed in the bottom of the cavity and held by a bearing surface 36 associated with the cup 10. This bearing surface 36 can be attached to the cup 10 or made by a groove in the cup 10. The resilient member 28 is provided with a plurality of resilient arms 38 extending in a substantially radial direction to overcome the collar 22 of the chimney. The elastic arms 38 could also cooperate with a groove formed at the periphery of the tubular chimney 18, the collar may not be present. The arms 38 are elastically deformable in the radial and axial directions. They are endowed with a positioning zone 40 cooperating with the chimney to define the rest position of the chimney. Such a positioning zone 40 may, for example, be made by a V-shaped notch.

In this embodiment, the axial and radial abutments are made in a manner similar to the second mode above, that is to say that the axial abutment is formed by the cup 10 and the radial abutment is made by the stiffness of the elastic member 28. The resilient arms may be integral with a ring 34, as proposed above.

Figs. 5a, 5b and 5c show an elastic member 28 particularly adapted to the implementation of the invention, and a bearing incorporating this elastic member. It may be particularly noted that the elastic member 28 is provided with arms 38 spiral connecting outwardly a ring 34, and inwardly, a wafer 42 coaxial with the pivot member. The patch 42 could act as a counter-pivot stone as proposed in FIG. 7. It may then not be integral with the tubular chimney 18.

The ring 34 is further provided with gripping lugs 44, defining in pairs and between them, a working area 46 with which can cooperate a mounting tool. Some of the gripping tabs 44 receive a holding zone 48 whose role will appear hereinafter. Each holding zone 48 has an elastic finger 48a extending substantially parallel to the ring 34, like a last turn of a spiral. All areas of flexible support supports are oriented in the same direction. The end of the elastic finger 48a has a pad 48b on its outer face intended to press on the tubular chimney 19.

As shown in FIGS. 5b and 5c, the elastic member is intended to be engaged in a housing 50 defined by flanges 52, functionally similar to the span 36 described above, the flanges being formed by the cup 10. These flanges are regularly distributed and separated by spaces devoid of flange 52, allowing the engament, in each space, a gripping lug 44 associated with a holding zone 48. Then, by pressure and rotation of the elastic member by means of the tool ad-hoc, the flexible bearing support zones 48 are constrained in the housing 50 and the pad 48b is pressed against the wall of the cup 10 to prevent inadvertent rotation of the elastic member. These areas of flexible supports therefore allow a play-free assembly for centering the ring in the cup.

FIG. 6 proposes an elastic member according to an alternative similar to that proposed in Figure 5a. The flexible bearing support zones 48 are replaced by a wedging profile with two portions 54, 56 concentrically oriented at the center of the elastic member, respectively according to two different radii. The first portion 54 has a radius less than the radius of the housing 50 and can be inserted freely into the housing 50. The second portion 56 has a radius greater than the radius of the housing 50. The two portions are connected by an intermediate zone having a varying radius gradually and likely to be wedged against the wall of housing 50.

In the case of the embodiments of FIGS. 1, 5 and 6, when the tubular chimney 18 pivots, it remains in contact with the cup at two points: one being located between the lower outer corner 18a of the chimney and the bottom of the recess 20, the other being located between the outer cylindrical surface of the chimney and the upper corner 20a of the clearance. The lower corner of the chimney belonging to said cylindrical surface without discontinuity of the shape, it is said that these points belong to the same continuous surface. In contrast, a non-continuous surface is a contiguous surface that has a significant discontinuity, for example, having an angle of more than 60 °, more than 80 °, or even more than 90 °, between straight portions of the surface. For example, the bottom surface of the tubular chimney is not continuous with its cylindrical wall, these surfaces joining at a right angle. A chamfer or bevel between such surfaces does not make them continuous.

Figs. 8 and 9 propose a bearing according to a similar alternative to the bearing of FIGS. 5a - c. In this embodiment, the tubular chimney 18 supports the pierced stone 24, and is attached to the elastic member by means of an intermediate fixing ring 60 in which the counterpoise stone is driven. In addition, the ring 34 has a variable width.

Figs. 10 and 11 still propose a bearing according to a similar alternative to the bearing of FIGS. 5a - c, wherein the pellet 42 is in the form of a ring, revealing the counterpoise stone.

The tubular chimney 18 of the embodiments of FIGS. 8 - 11 further has an annular protrusion 62 of rounded section, preferably O-ring on its lower part, that is to say the portion directly adjacent to the bottom of the clearance 20. This outer surface is intended to abut against the wall of the clearance 20 when the bearing is subjected to a sufficient lateral impact. Consequently, when the tubular chimney 18 pivots, it remains in contact with the cup 10 at two points: one being situated between the outer surface of the protrusion 62 and the wall of the recess 20, the other being situated also between the outer surface of protuberance 62 and bottom of clearance 20.

Thus, various embodiments of an anti-shock bearing are proposed, in which the action of the elastic members on the tubular chimney 18 makes it possible to convert a portion of the energy of a radial shock into a substantially rotational displacement of the tubular chimney 18. Thus, the tubular chimney 18 is raised under the effect of a radial shock, so that it is no longer in contact with the cup on one side of a median plane oriented perpendicularly. to the radial component of the force generated by the shock. This rotation is in rolling and / or sliding and, if the tubular chimney moves axially and radially, the radial displacement of the base of the chimney is limited. The tigeron 15 can therefore absorb all shocks, whatever their orientation. The return to the rest position is without risk of jamming the tubular chimney 18 in an undesired intermediate position. In addition, thanks to the fact that the base of the chimney does not move or radially little, the tubular chimney is automatically substantially centered when it returns to its rest position. Those skilled in the art will be able to refine the sizing of the pivot, particularly its length, so that the moment-inducing force in the event of a radial impact is, in most cases, less than the static friction forces of the chimney on the cup, in order to set in motion the tubular chimney by rolling rather than by sliding.

For the embodiments without flange, it should be noted that the point or points of contact between the chimney and the elastic member are close to the axis of the bearing, which decreases the lever of the force exerted by the elastic member. This makes it easier to manage the bearing's operation. In addition, in this case, we can provide a rounded shape of the section of the base of the tubular chimney 18, which promotes its pivoting.

Those skilled in the art may also provide different variants from the embodiments described above, without departing from the scope defined by the claims. In particular, the pivot member may not comprise a pivoting stone if, for example, the pierced stone has a conical hole. The notion of stone must be understood in a broad way and not be limited to a traditional ruby stone. It can thus be made of silicon, optionally integrally with the tubular chimney 18, at least for one of the stones. A stone can be covered with an aluminum oxide material so as to get closer to the conventional friction conditions known by the use of ruby stones. Those skilled in the art may choose to make this bearing, particularly the elastic member, in a material based on silicon or nickel-based or iron-based (steel). One or more of the following elements may be made in one piece: the cup, the chimney, at least a part of the pivoting member (pierced stone or pivoting stone if appropriate), at least one elastic member, the frame of the timepiece which carries the cup or in which the cup is formed. In a preferred embodiment, the counter-pivot stone is made of silicon, optionally coated with sapphire, and integrated with the elastic member (FIG 7).

Claims (19)

1. Anti-shock bearing for a timepiece comprising: - a cup (10), intended to be assembled on a timepiece frame, defining an inner cavity (12), in the center of which is formed an opening (14) adapted to receive a tigeron (15) of a mobile watchmaker and defining an axis of the bearing, - a tubular chimney (18) disposed, when the bearing is in a predefined rest position, substantially in the center of the inner cavity (12), - A pivot member (24, 26) associated with said chimney and adapted to receive a pivot (16) extending said tigeron (15), the pivot member (24, 26) comprising a pierced stone (24) integral with the tubular chimney (18), At least one resilient member (28) arranged to exert on said tubular chimney (18) at least one axial force, parallel to said axis and tending to maintain or return the chimney to said predefined rest position, characterized in that said bearing is arranged in such a way that when the chimney receives a force exerted by the pivot and whose value of the radial component is greater than a trigger value, it pivots about a substantially perpendicular axis to the axis of the bearing so that the chimney is in contact with the cup on one side of a median plane perpendicular to said radial component, said contact being at a single point of contact, or at two points of contact, the two points of contact being on the same continuous outer surface of the tubular chimney. 2. anti-shock bearing according to claim 1, characterized in that the chimney is adapted to rotate by rolling on the cup. 3. Anti-shock bearing according to claim 1, characterized in that the chimney is able to pivot by sliding on the cup. 4. anti-shock bearing according to one of the preceding claims, characterized in that said cup is intended to be assembled on a timepiece frame. 5. Anti-shock bearing according to one of claims 1 to 3, characterized in that at least two of the following elements are monoblock: the cup, the chimney, at least a portion of the pivot member, at least one elastic member , a timepiece frame. 6. Anti-shock bearing according to one of the preceding claims, characterized in that said predefined rest position is determined by at least one axial abutment. 7. Anti-shock bearing according to claim 6, characterized in that said predefined rest position is determined by at least one radial abutment. 8. anti-shock bearing according to claim 6 or 7, characterized in that said axial abutment and / or said radial abutment are formed by a wall of said inner cavity (12) of said cup (10). 9. Anti-shock bearing according to one of the preceding claims, characterized in that the elastic member is also arranged to exert on the tubular chimney (18) at least one radial force when said tubular chimney receives a force which is exerted by the pivot, and whose value of the radial component is greater than a trigger value. 10. Anti-shock bearing according to claim 7 and according to claim 9, characterized in that said radial stop is made by the stiffness of the elastic member (28). 11. Anti-shock bearing according to one of the preceding claims, characterized in that said elastic member (28) comprises one or more arms. 12. Anti-shock bearing according to one of the preceding claims, characterized in that said elastic member (28) is housed in the cavity and held by a bearing surface (36) or flange (52) associated with said cup (10). 13. Anti-shock bearing according to one of the preceding claims, characterized in that said elastic member (28) cooperates with a flange (22) associated with the tubular chimney (18). 14. Anti-shock bearing according to claim 11, characterized in that said arm or said each define a flexible blade whose one end is integral with the cup and a second end is free and cooperates with the tubular chimney (18). 15. Anti-shock bearing according to one of the preceding claims, characterized in that the elastic member is integral with a ring (34) fitted inside the cavity of said cup (10). 16. Anti-shock bearing according to one of the preceding claims, characterized in that the pivot member is composed of a pierced stone (24) disposed at least partially in said tubular chimney (18) and provided with a hole substantially in the axis of the bearing. 17. Anti-shock bearing according to claim 16, characterized in that the pivoting member is provided with a counter-pivoting stone (26) disposed at least partially in said tubular chimney (18), on the side of the pierced stone (24). ) opposite to the cup (10). 18. Anti-shock bearing according to one of claims 1 to 17, characterized in that the bottom of the inner cavity (12) is provided with a recess (20) having a wall, the base of the tubular chimney (18) taking in the clearance (20), said first contact point being located between the bottom of said clearance (20) and the outer lower corner (18a) of the chimney, said second contact point being located between an upper corner (20a) of said clearance and the outer surface of the tubular chimney (18). 19. Anti-shock bearing according to one of claims 1 to 17, characterized in that the bottom of the inner cavity (12) is provided with a recess (20) having a wall, the base of the tubular chimney (18) taking placed in the recess, the tubular chimney (18) has an annular protrusion (62) of rounded section, preferably of toric section, the outer surface of said protuberance (62) forming said continuous outer surface of the tubular chimney (18), said two contact points being located between said outer surface of said protrusion (62) and the bottom of said clearance (20), respectively the wall of said clearance (20).