CH714936A2 - Shockproof protection of RCC swivel resonator. - Google Patents

Abstract

Clock-resonator mechanism (100), comprising a structure (1) and an inertial element (2) oscillating about an axis (D), subjected to the recalls exerted by a flexible pivot RCC (200) with elastic blades (3) , each fixed to the structure (1) and to said inertial element (2) and essentially deformable in a plane perpendicular to said axis (D), straight and extending in parallel or coincident planes, the crossing, in projection on a perpendicular plane to said axis (D), their directions defining said axis (D), these blades (3) are fixed on the side of the inertial element (2) to a rigid element (13), which comprises an elastic element (10), and on which are fixed these blades (3) and which is secured to flexible blades (11) arranged to hold in suspension said inertial element (2), said elastic member (10) providing the shockproof protection of the blades (3) of the pivot flexible (200).

Description

Description: The invention relates to a clock resonator mechanism, Clock resonator mechanism, comprising a structure and at least one inertial element arranged to oscillate in a pivoting movement around a pivot axis, with the center d inertia of this at least one inertial element aligned with the pivoting tax, this at least one inertial element being subjected to restoring forces exerted by at least one flexible RCC pivot comprising a plurality of elastic blades each fixed, directly or indirectly, to a first end to the structure and fixed, directly or indirectly, to a second end to said at least one inertial element, each elastic blade extending in a plane perpendicular to the pivot axis, and being deformable essentially in the plane perpendicular to the pivot axis, where the elastic blades are straight and extend in parallel planes between them or combined, and where the crossing, in projection on a plane perpendicular to the pivot axis, of the directions in which the elastic blades extend, defines the pivot axis.

The invention also relates to an oscillator comprising at least one such resonator mechanism and an escapement mechanism.

The invention also relates to a timepiece movement comprising at least one such oscillator and / or at least one such resonator mechanism.

The invention also relates to a watch comprising such a clockwork movement, and / or at least one such oscillator and / or at least one such resonator mechanism.

The invention relates to the field of watchmaking resonators, and in particular those which include elastic blades acting as return means for operating the oscillator.

BACKGROUND OF THE INVENTION Impact resistance is a delicate point for most horological oscillators, and in particular for cross-blade resonators. In fact, during out-of-plane shocks, the stress suffered by the blades quickly reaches very high values, which reduces the travel that the part can travel before yielding.

Shock absorbers for timepieces are available in many variants. However, their main purpose is to protect the fragile pivots of the axle, and not the elastic elements, such as conventionally the spiral spring.

Document EP 3 054 357 A1 in the name of ETA Manufacture Horlogère Suisse SA describes a horological oscillator comprising a structure and separate primary resonators, temporally and geometrically phase-shifted, each comprising a mass biased towards the structure by an elastic return means . This oscillator comprises coupling means for the interaction of the primary resonators, comprising motor means for driving in motion a mobile which comprises drive and guide means arranged to drive and guide a control means articulated with transmission means. , each articulated, at a distance from the control means, with a mass of a primary resonator. The primary resonators and the mobile are arranged in such a way that the axes of the articulations of any two of the primary resonators and the axis of articulation of the control means are never coplanar.

Document EP 3 035 127 A1 in the name of SWATCH GROUP RESEARCH & DEVELOPMENT Ltd describes a timepiece oscillator comprising a resonator constituted by a tuning fork which comprises at least two oscillating moving parts, fixed to a connecting element by elements flexible whose geometry determines a virtual pivot axis of determined position relative to a plate, and around which oscillates the respective movable part, whose center of mass coincides in the rest position with the respective virtual pivot axis. For at least one movable part, the flexible elements consist of elastic blades crossed at a distance from each other in two parallel planes, the projections of the directions of which on one of the parallel planes intersect at the level of the pivot axis virtual part of the mobile part.

Claims (19)

SUMMARY OF THE INVENTION The invention proposes to protect against impact the blades of a resonator with flexible pivot RCC ("remote center compliance") blades, and therefore to ensure a better behavior of the system. To this end, the invention relates to a reed resonator mechanism according to claim 1. The invention also relates to an oscillator comprising at least one such resonator mechanism and an escapement mechanism. The invention also relates to a timepiece movement comprising at least one such oscillator and / or at least one such resonator mechanism. The invention also relates to a watch comprising such a clockwork movement, and / or at least one such oscillator and / or at least one such resonator mechanism. CH 714 936 A2 Brief description of the drawings [0015] Other characteristics and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, where: fig. 1 shows, schematically, partially, and in plan view, a resonator mechanism with elastic blades, with a flexible pivot RCC, and comprising, at the end of the elastic blades of this pivot RCC, an elastic element according to the invention, in which a shaft of an inertial mass, not shown, is maintained; fig. 2 is a detail of this elastic element, which comprises a substantially annular external rigid element, to which an elastic inner ring is suspended, by means of three flexible blades which provide the shock protection of the RCC pivot; this inner ring clamps, with clamping, the shaft of the inertial mass; fig. 3 and 4 show schematically, respectively in axial section and in top view, an assembly with two RCC pivots placed face to face, one upper above a bridge, the other lower below a plate, each squeezing one end of the inertial mass shaft which is located between the bridge and the plate; fig. 5 shows, schematically, in axial section, a detail of the figures at the upper pivot; fig. 6 is a block diagram representing a watch comprising a movement, comprising an oscillator which itself comprises a resonator mechanism according to the invention; fig. 7 and 8 represent, in a similar manner respectively in FIGS. 3 and 4, a mounting variant with two superimposed RCC pivots, and also arranged on either side of the plate and the bridge. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention proposes to protect against impact the blades of a resonator with flexible pivot blades RCC (“remote center compliance”), and therefore to ensure a better behavior of the system. . Application CH 01 511/16 on behalf of The Swatch Group Research & Development Ltd describes shock absorbers for flexible pivots in vee head to tail, and for flexible pivots RCC. This request includes numerous arrangements of stops which are advantageous for such mechanisms, easy to implement by a person skilled in the art, in combination with the description of the present description, and which are not detailed here. It can be noted that the arrangement of a flexible pivot in vee head to tail has the advantage of juxtaposing four blades, always at least one of which can bend or buckle, and prevent breakage of the assembly. The situation is more delicate for a shock occurring on an RCC pivot, because, if the direction of the shock is parallel to one of the blades, and tends to lengthen this blade which is very rigid, it can break in the event of too high elongation. The invention therefore proposes to provide a simple solution to this particular case. To this end, the invention consists in introducing at least one elastic element between the blades of the RCC pivot and the inertial element. Thus, the invention relates to a clockwork resonator mechanism 100, comprising a structure 1 and at least one inertial element 2, which is arranged to oscillate in a pivoting movement around a pivot axis D. The center of inertia of this at least one inertial element 2 is aligned on the pivot axis D during the oscillation. This at least one inertial element 2 is subjected to restoring forces exerted by at least one flexible pivot RCC 200 in FIGS. 1 and 2, 201 and 301 in figs. 3 and 4. This flexible pivot 200, 201, 301, comprises a plurality of elastic blades 3. Each of these blades 3 is fixed, directly or indirectly, at a first end to the structure 1, and is fixed, directly or indirectly, at a second end at least one inertial element 2. Each elastic blade 3 extends in a plane perpendicular to the pivot axis D, and is deformable essentially in the plane perpendicular to the pivot axis D. Preferably the elastic blades 3 are straight. These blades 3 extend in planes which are parallel to one another or coincide, and where the crossing, in projection on a plane perpendicular to the pivot axis D, of directions D1; D2, along which the elastic blades 3 extend defines the pivot axis D. According to the invention, the resonator mechanism 100 comprises an elastic element 10 which comprises a rigid element 13, on which are fixed the second ends of the blades 3, and which is integral with at least one flexible blade 11 arranged for the holding the inertial element 2 in suspension. This elastic element 10 provides shockproof protection for the blades 3 of the flexible pivot 200, 201,301. More particularly, the rigid element 13 is at least 100 times more rigid, according to all the degrees of freedom, than the elastic blades 3 of the flexible pivot, and that each flexible blade 11 that comprises the shock-resistant elastic element 10. CH 714 936 A2 Different arrangements of the flexible blades 11 are possible. In a first variant, each flexible blade 11 is substantially spiraled around the pivot axis D. In a second variant, each flexible blade 11 is substantially of revolution around the pivot axis D. More particularly, the elastic element 10 comprises a plurality of identical flexible blades 11, and regularly distributed around the pivot axis D. In an advantageous embodiment visible in FIGS. 1 and 2, the elastic element 10 comprises an elastic inner ring 14, to which each flexible blade 11 is fixed internally which is externally fixed to the rigid element 13, which is substantially annular, and to which the elastic inner ring 14 is suspended And the elastic inner ring 14 more particularly comprises a plurality of internal bearing surfaces 12 for holding by concentric tightening of a shaft 22 that comprises the inertial element 2. Advantageously, the flexible blades 11 are calculated so that the rotational resonance frequency of the elastic element 10 according to its first natural mode is greater than 1000 Hz, or even a few thousand Hz. On the flexible pivot side, the frequency of oscillation of the inertial element 2 is more particularly between 5 Hz and 100 Hz. An assembly with two RCC pivots placed face to face makes it possible to: - cancel the effects of positions, when worn, on the frequency of the resonator; the center of mass of the inertial mass must be equidistant from the RCC pivots; - stiffen the system and limit the movements of the inertial mass to one rotation along the Z axis which corresponds to the pivot axis D. Thus this at least one inertial element 2 is subjected to restoring forces exerted by a pair of flexible pivots RCC 201, 301, identical, mounted in opposition, and of which all the blades 3 are fixed at their second end to a such a unique and common elastic element 10. The center of mass of the inertial element is equidistant from the pivot axes of the flexible pivots RCC 201,301 when these axes are separate, or aligned with them when they are coaxial. Figs. 3 and 4 illustrate a particular non-limiting case, where the flexible pivots RCC 201,301 of the pair are arranged in parallel planes, on either side of the inertial element 2. More particularly, these flexible pivots RCC 201, 301 of the pair are arranged on either side of two fixed elements of the structure 1, between which the inertial element 2 is movable. Figs. 7 and 8 show, in a similar manner respectively in FIGS. 3 and 4, a mounting variant with two superimposed RCC pivots, and also arranged on either side of the plate and the bridge. In a variant, within the elastic element 10, at least one flexible blade 11 is arranged to hold the inertial element 2 by elastic clamping. More particularly, the elastic element 10 comprises a plurality of blades flexible 11, each designed to hold the inertial element 2 by elastic clamping. We can say that, for the same mass of inertia: the rigidity in rotation (resonant frequency of the system) of the blades 11 is at least 100 times, and more particularly at least 500 times, and more particularly still at least 1000 times, greater than the rigidity of the blades 3, so as not to disturb the resonant frequency; the rigidity in translation (resonant frequency of the system) in the plane of the blades 11 is at least 100 times, and more particularly at least 500 times, and more particularly still at least 1000 times, less than the rigidity of the blades 3, so to ensure displacement in the event of an impact. Regarding the rigidities in translation in the Z direction of the blades 11 and the blades 3, they are such that, in the event of an impact, both the blades 11 and the blades 3 participate in the displacement of the mass d inertia until the stop. More particularly, the resonator mechanism 100 comprises axial stop means comprising at least one lower axial stop and / or an upper axial stop, the axial stop means being arranged to cooperate in abutment support with at least one inertial element 2 for the protection of the resonator mechanism 100 against axial shocks in the direction of the pivot axis D. The various arrangements of the application CH 01 511/16 can advantageously be incorporated into this mechanism. [0042] FIG. 3 illustrates a particular case with an upper RCC pivot 200 with blades 203, with a fixed part 201 on the upper face of a bridge 12, which comprises the structure 1, with stops in the vicinity of an upper pivot 210 of a shaft 22 of the inertial element 2; this is enclosed between this bridge 12 and a plate 13 of the structure 1, under which is fixed the fixed part 301 of a lower RCC pivot 300 with blades 303. On each side, the elastic element 10 which extends the blades elastic 3, and which is not detailed in FIG. 5, is designed to come into abutment abutment on a shoulder CH 714 936 A2 21 of the shaft 22, at a distance from the corresponding surface 121 of the bridge 12 (or respectively of the plate 13), and this shaft 22 comprises, on the side of the inertial element 2, a shoulder remote from the lower face 122 of bridge 12 (or respectively of plate 13). In a variant not illustrated, the resonator mechanism 100 comprises a plurality of such inertial elements 2 which extend over several parallel levels, and the resonator mechanism 100 comprises at least one intermediate axial stop arranged between two neighboring levels of elements inertial 2. The invention also relates to an oscillator 400 comprising such a resonator mechanism 100, arranged to cooperate with an exhaust mechanism 300. The invention also relates to a timepiece movement 500 comprising at least one such oscillator 400, and / or at least one such resonator mechanism 100. The invention also relates to a watch 1000 comprising at least one such movement 500, and / or at least one such oscillator 400, et7ou according to claim 16, and / or at least one such resonator mechanism 100. claims 1. Clockwork resonator mechanism (100), comprising a structure (1) and at least one inertial element (2) arranged to oscillate in a pivoting movement around a pivoting axis (D), with the center of inertia of said at least one inertial element (2) aligned with said pivot axis (D), said at least one inertial element (2) being subjected to restoring forces exerted by at least one flexible pivot RCC (200,201,301) comprising a plurality of elastic blades (3) each fixed, directly or indirectly, at a first end to said structure (1) and fixed, directly or indirectly, to a second end to said at least one inertial element (2), each said elastic blade (3) extending in a plane perpendicular to said pivot axis (D), and being deformable essentially in said plane perpendicular to said pivot axis (D), where said elastic blades (3) are straight and extend in para planes They are mutually or confused, and where the crossing, in projection on a plane perpendicular to said pivot axis (D), directions (D1; D2) along which extend said elastic blades (3) defines said pivot axis (D), characterized in that said resonator mechanism (100) comprises an elastic element (10) which comprises a rigid element (13), on which are fixed said second ends of said blades (3) and which is integral with at least one flexible blade (11) arranged to hold said inertial element (2) in suspension, said elastic element (10) ensuring the shock protection of said blades ( 3) of said flexible pivot (200, 201,301). 2. Resonator mechanism (100) according to claim 1, characterized in that said rigid element (13) is at least 100 times more rigid, according to all degrees of freedom, than said elastic blades (3) of said flexible pivot, and that each said flexible blade (11) of said elastic shock-absorbing element (10). 3. Resonator mechanism (100) according to claim 1, characterized in that each said flexible blade (11) is substantially spiraled around said pivot axis (D). 4. Resonator mechanism (100) according to claim 1, characterized in that each said flexible blade (11) is substantially of revolution around said pivot axis (D). 5. Resonator mechanism (100) according to one of claims 1 to 3, characterized in that said elastic element (10) comprises a plurality of said flexible blades (11) identical and regularly distributed around said pivot axis (D). 6. Resonator mechanism (100) according to one of claims 1 to 4, characterized in that said elastic element (10) comprises an elastic inner ring (14) to which is fixed internally each said flexible blade (11) which is fixed externally to said rigid element (13) which is substantially annular and to which is suspended said elastic inner ring (14), and in that said elastic inner ring (14) has a plurality of internal surfaces (12) for holding by concentric tightening d 'a shaft (22) that comprises said inertial element (2). 7. Resonator mechanism (100) according to one of claims 1 to 5, characterized in that the rotational resonance frequency of said elastic element (10) according to its first natural mode is greater than 1000 Hz. 8. Resonator mechanism (100) according to one of claims 1 to 6, characterized in that the oscillation frequency of said inertial element (2) is between 5 Hz and 100 Hz. 9. Resonator mechanism (100) according to one of claims 1 to 7, characterized in that said at least one inertial element (2) is subjected to restoring forces exerted by a pair of said flexible RCC pivots (200, 201 , 301) identical, mounted in opposition, and all of which said blades (3) are fixed at their said second end to said single and common elastic element (10). 10. Resonator mechanism (100) according to claim 8, characterized in that the center of mass of said inertial element is equidistant from the pivot axes of said flexible RCC pivots (200, 201, 301) when these axes are distinct, or aligned with them when they are coaxial. 11. Resonator mechanism (100) according to claim 8 or 9, characterized in that said flexible RCC pivots (200, 201, 301) of said pair are arranged in parallel planes, on either side of said inertial element (2 ). CH 714 936 A2 12. Resonator mechanism (100) according to claim 10, characterized in that said flexible RCC pivots (200, 201, 301) of said pair are arranged on either side of the two fixed elements of said structure (1) between which said inertial element (2) is movable. 13. Resonator mechanism (100) according to one of claims 1 to 11, characterized in that at least one said flexible blade (11) is arranged for the maintenance by elastic clamping of said inertial element (2). 14. Resonator mechanism (100) according to one of claims 1 to 12, characterized in that said elastic element (10) comprises a plurality of said flexible blades (11) each arranged for the elastic clamping of said inertial element (2 ). 15. Resonator mechanism (100) according to one of claims 1 to 13, characterized in that said resonator mechanism (100) comprises axial stop means comprising at least one lower axial stop and / or one upper axial stop, said means of axial stop being arranged to cooperate in abutment support with at least one said inertial element (2) for the protection of said resonator mechanism (100) against axial shocks in the direction of said pivot axis (D). 16. Resonator mechanism (100) according to one of claims 1 to 14, characterized in that said resonator mechanism (100) comprises a plurality of said inertial elements (2) which extend over several parallel levels, and in that said resonator mechanism (100) comprises at least one intermediate axial stop arranged between two said neighboring levels of said inertial elements (2). 17. Oscillator (400) comprising a resonator mechanism (100) according to one of claims 1 to 15, arranged to cooperate with an exhaust mechanism (300). 18. Clock movement (500) comprising at least one oscillator (400) according to claim 16, and / or at least one resonator mechanism (100) according to one of claims 1 to 15. 19. Watch (1000) comprising at least one movement (500) according to claim 17 and / or at least one oscillator (400) according to claim 16, and / or at least one resonator mechanism (100) according to one of claims 1 to 15. CH 714 936 A2

CH 714 936 A2

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