CH709056A2 - Mechanism of clock synchronization. - Google Patents

Abstract

The invention relates to a mechanism for synchronizing the speed of rotation of a gear train subjected to a torque in a watch movement. This mechanism comprises an annular resonator (6) comprising a ring (7) arranged around an axis (A), which ring (7) is periodically deformable under the action induced by the movement of a driver (8) , which comprises said mechanism, and which driver (8) is driven, directly or indirectly, by said pair.

Description

Field of the invention

The invention relates to a mechanism for synchronizing the speed of rotation of a gear subjected to a torque in a watch movement.

The invention also relates to a watch movement comprising, fixed on a plate, energy storage means and an actuating wheel of such a mechanism.

The invention also relates to a timepiece comprising such a movement.

The invention relates to the field of regulation of mechanical timepieces, particularly mechanical watches.

Background of the invention

[0005] In a clock escapement mechanism, the Swiss lever escapement generally used has a fairly low efficiency (of the order of 35%).

[0006] The main sources of losses of a Swiss anchor escapement are:

[0007] The development of a new synchronization system in a watch movement, with a yield greater than that of a Swiss lever escapement, can be translated by:

Summary of the invention

The invention proposes to create mechanisms that would have a higher yield performance of the Swiss lever escapement.

The invention consists of a system for synchronizing a gear driven by a motor spring with a resonator.

For this purpose, the invention relates to a mechanism for synchronizing the speed of rotation of a gear subjected to a torque in a watch movement, characterized in that said mechanism comprises an annular resonator comprising a ring arranged around an axis, which ring is deformable periodically under the action induced by the movement of a trainer, that includes said mechanism, and which driver is driven, directly or indirectly, by said pair.

The invention also relates to a watch movement comprising, fixed on a plate, a means for storing energy and an actuating wheel of such a mechanism comprising an annular resonator, with a ring fixed by blades. flexible to the turntable, and a trainer driven by the gear, this coach controlling means of displaying the second of the movement.

The invention also relates to a timepiece comprising such a movement, characterized in that this piece is a watch.

Brief description of the drawings

Other features and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, in which: <tb> figs. 1 to 3 <SEP> show schematically and in plan view, a mechanism for synchronizing the speed of rotation of a watch mechanism according to the invention comprising an annular resonator with a deformable ring whose deformation is induced by a crank-drive, which pivots around the axis of this ring, FIG. 2 representing a neutral state where this ring has a substantially circular profile, between FIGS. 1 and 3 which represent profiles of maximum deformation in ellipses, with permutation of the ellipse axes between these two extreme positions of deformation; <tb> fig. 4 <SEP> shows, schematically and in plan view, a variant with an annulus resonator of "wineglass" type weighted to lower the natural frequency, synchronized with a trainer acting as a crank; <tb> fig. 5 <SEP> represents, schematically and in plan view, a variant with a weighted wineglass annular resonator for the purpose of lowering the natural frequency, synchronized magnetically with a wheel, which comprises magnetic zones arranged to cooperate with each other. with magnetic tracks of the ring to generate deformations and / or pulses; <tb> fig. 6 <SEP> shows, schematically and in plan view, a variant comprising an annular resonator of "wineglass" weighted to lower the natural frequency, synchronized magnetically with a wheel; <tb> fig. 7 <SEP> represents, schematically and in side view, a "wineglass" experiment with a source of excitation consisting of a loudspeaker near the tulip of a stemmed glass whose foot is held in recess ; <tb> fig. 8 <SEP> represents, schematically and in plan view, the glass of FIG. 7 in its different states of deformation of elliptic profile, with the distribution of bellies and nodes of vibration; <tb> figs. 9 to 11 <SEP> are similar to FIGS. 1 to 3, with a ring whose free state is not exactly circular but has bulges making energy thresholds, and where the fasteners of the flexible blades connecting this ring to the plate are in the diagonals of the large and small axes of the ellipse; <tb> fig. 12 <SEP> is a block diagram illustrating a timepiece comprising a movement incorporating a mechanism according to the invention; <tb> figs. 13 to 18 <SEP> illustrate particular and non-limiting forms of rings suitable for implementing the invention: - in fig. 13, externally circular and internally quadrilobed; - in fig. 14, substantially triangular externally, and trilobed internally; - in fig. 15, substantially circular substantially constant section; - in fig. 16, externally circular and having a plurality of point clearances; - in fig. 17, with a varying thickness depending on the radius; - in fig. 18, circularly internally and with a plurality of external flyweights with a tee profile; <tb> fig. <SEP> illustrates the cooperation of a ring and a driver both substantially annular and each having a plurality of magnetic tracks; <tb> figs. 20 to 31 <SEP> illustrate the eigenmodes in the XY plane of such a resonator, with a ring of diameter 14.00 mm, of thin type, with thickness and height of 0.01 mm, in silicon with a module of Young of 146 GPa, a density of 2329 kg / m3 and a Poisson modulus of 0.26: <Tb> Fig. <SEP> with a first clean mode according to FIG. 22 to 182 Hz, a second clean mode according to FIG. 23 to 470 Hz, a third clean mode identical to that of FIG. 23 but orthogonal, not shown, a fourth clean mode according to FIG. 24 to 550 Hz, a fifth clean mode according to FIG. 25 to 605 Hz, a sixth clean mode according to FIG. 26 to 692 Hz; <Tb> Fig. 21 <SEP> with 32 ballasts each of radius 1.0 mm, allowing a very clear lowering of the frequencies of the eigen modes: a first eigenmode according to fig. 27 to 33 Hz, a second clean mode according to FIG. 28 to 85 Hz, a third clean mode identical to that of FIG. 28 but orthogonal, not shown at 89 Hz, a fourth eigenmode according to FIG. 29 to 96 Hz, a fifth clean mode according to FIG. 30 to 148 Hz, a sixth eigenmode according to FIG. 31 to 155 Hz.

Detailed description of the preferred embodiments:

We will call in the following of the presentation "ring" a volume similar to an open torus, unfolding, closed on itself, around an axis. This "ring" is substantially of revolution about this axis, but not necessarily exactly of revolution around this axis.

A particular type of resonator combines the implementation of different waves.

It is known in particular a laboratory resonator said "wineglas" or wine glass, where the tulip of a stemmed glass, whose foot is held in recess, is subjected to a particular sound excitation. When the excitation frequency, effected by a loudspeaker in the vicinity of the glass, is chosen equal to a resonant frequency of the glass, of the order of 800 to 900 Hz, with a signal power of about 100 W, we can create in the tulip of the glass a wave network bringing important deformations of this tulip, which seen in plan at the opening of the glass, perpendicular to the axis of the foot, give at a given moment to the edge of the glass an elliptical shape, as visible in FIGS. 7 and 8, on this latter being spotted the nodes of vibration N and the bellies V. This elliptic form is deformable, and the maintenance of the excitation makes evolve this form in ellipse, by modifying its eccentricity, and up to swap the major axis and the minor axis of the ellipse, passing through the eccentricity position equal to one corresponding to the free form of the edge of the glass. These deformations can go as far as causing the glass to break. When the excitation source is disposed radially, it is found the presence of four identical vibration bellows, one of which directly opposite the excitation source, the vibration nodes being in directions at 45 ° of the defined axis. by the axis of the glass and the source of excitation.

This phenomenon is due to a standing wave. This standing wave can be seen as the sum of a progressive wave and a regressive wave propagating in both directions along the edge of the glass, in an annular zone, substantially of revolution.

The resulting vibration obeys the equation: u (x, t) = f (x + vt) + g (x-vt) where f is the function qualifying the progressive wave, where g is the function qualifying the regressive wave.

These functions f and g may be arbitrary, and depend on the initial excitation of the glass.

If we wait long enough, we can get a standing wave.

For example, if f and g are sinusoidal functions: u (x, t) = sin (kx + ωt) + sin (kx-ωt) the trigonometric relation sin a + sin b = 2 sin (a + b) / 2 cos (a-b) / 2 makes it possible to write that u (x, t) = 2 sin (kx) cos (ωt), which is a standing wave: each point oscillates in phase like cos (ωt), but with a different amplitude 2 sin (kx).

The invention proposes to extrapolate such a principle, which is without known industrial application, by exciting a single wave, for example the progressive wave, by acting on a deformable ring.

This wave can then rotate at the same speed around the edge of the ring as an excitation source, here constituted, without limitation, by a trainer, in particular constituted by a central crank or by a wheel .

As for an exhaust, this coach provides: - the transmission of energy (maintenance of the oscillation), and - counting, since this trainer rotates at the same speed as the wave.

It should be understood that the speed of propagation of the wave around the ring is a property of the ring, regardless of the trainer.

So this coach can only follow this wave, at the same speed as the wave, if we sized the system properly.

The wave propagates in the material of the ring. The wave has the effect of an elastic deformation of the ring (bending).

Preferably, but not limited to, the excitation is continuous. Thus, if we focus on a point of the ring, the passage of the trainer at a point is analogous to a sinus vertex. The signal is preferably periodic.

In the examples illustrated in the figures, the effect of the wave associated with the presence of the trainer tends to push the ring radially, forcing it to deform elastically.

The excitation wave is a wave of elastic deformation of the ring, which is a roughly transverse wave, resulting in a substantially radial deformation.

This explains that, in the illustrated example, from a circular ring, the deformation is in the form of eltipse whose main axis revolves around the center. One can of course imagine other forms of deformation.

The object subjected to this or these excitation waves is preferably of substantially annular shape, the ring perfect torus of revolution being a special case.

This object can be kept in simple embedding as the foot of the glass in the laboratory example described above.

The figures show variants where recessed blades hold the ring. Preferably these blades are very flexible relative to the ring, to allow proper operation.

Indeed, the analogy with the foot of the glass seems poorly suited to a watch, because this embodiment requires a large glass wall height so that the edge of the glass can be deformed, at a sufficient distance from this point d Recessed.

The invention relates to a mechanism for synchronizing the speed of rotation of a watch train by a deformable annular resonator, substantially concentric with the axis of the trainer, which performs the function ordinarily assigned to the escape wheel. in a classic watchwagon. Preferably this annular resonator is similar to a resonator of the "wineglass" type, as described above. The interaction between the trainer and the resonator may be mechanical or non-contact, in particular of the magnetic and / or electrostatic type.

More particularly, the invention relates to a synchronization mechanism 1 of the speed of rotation of a gear train 2 of a watch movement 10 subjected to a torque, in particular from a means of storing energy 3 that comprises this movement 10.

According to the invention, this mechanism 1 comprises an annular resonator 6 comprising a ring 7, which is deformable about an axis A under the effect of an action induced by the movement of a trainer 8, which comprises the mechanism 1. This driver 8 is driven, directly or indirectly, by this pair, and, more particularly, by said energy storage means 3, in particular from a cylinder through a gear train.

In one embodiment of the invention, the speed of the driver 8 defines a speed of propagation of a wave of deformation in the material of the ring 7 all around it.

In another embodiment of the invention, the speed of the driver 8 defines a stationary oscillation wave of the ring 7 between repetitive forms corresponding to stationary modes.

In a preferred embodiment, this trainer 8 drives a display 4, for example a second display, of the watch movement 10.

The movement of the coach 8 comprises a pivoting movement. Preferably, the movement of the driver 8 is a pivoting movement.

In one embodiment of the invention, as shown in FIG. 15, the driver 8 comprises at least one distal end 800 which extends, relative to the axis A, beyond the smallest diameter that present, in a free unstressed state, the ring 7 with respect to the axis A. More particularly, at least one distal end 800 locally deforms the ring 7 in the form of a bead 700) protruding radially outwards with respect to the axis A.

More particularly, at least one distal end 800 is arranged to cooperate with at least one clearance 71 that comprises, in an unstressed free state, the ring 7 at its inner periphery on the side of the axis A.

In a particular embodiment, the ring 7 comprises, in an unstressed free state, at its inner periphery on the side of the axis A, at least one bulge 70 facing the axis A constituting the smallest diameter that presents the ring 7 with respect to the axis A.

In a particular embodiment, the interaction between the driver 8 and the annular resonator 6 is mechanical.

In a particular embodiment, statically, the driver 8 exerts at least one radial force relative to the axis A in the centrifugal direction on the ring 7.

In a preferred embodiment, the ring 7 is fixed to a plate 5 that includes said watch movement 10 by a plurality of flexible blades 9, which in a first alternative are more flexible than the ring 7, arranged to maintain the ring 7 substantially centered on said axis A, and to restrict the movements of the ring 7 in the same plane P perpendicular to the axis A with limited displacements of the center of inertia of the ring 7 less than one tenth of the smaller outer dimension of the ring 7 in said plane P.

In a second alternative, these flexible blades 9 are more rigid than the ring 7.

In a first embodiment, as shown in FIGS. 1 to 4 and 9 to 11, a ring resonator 6 of the "wineglass" type is synchronized with a driver 8 acting as a crank. Fig. 2 shows the shape of the resonator at rest, and FIGS. 1 and 3 show the extreme states that can take the ring resonator 6 during the evolution of the crank.

Advantageously, the ring 7 of the annular resonator 6 is fixed to a plate 5 that includes the watch movement 10 by a plurality of flexible blades 9, more flexible than the ring 7, and which are arranged to maintain the ring 7 centered on the axis A, and to restrict the movements of this ring 7 in the same plane P perpendicular to the axis A at very low strokes, especially with strokes less than one-tenth of the smallest outer dimension of the ring 7 in this plane P. In the preferred and illustrated case where the ring 7 has at rest a substantially circular shape, this smaller dimension is the length of the small axis of the flatter ellipse corresponding to an extreme deformation of this ring 7. Figs. 9 to 11 illustrate a similar configuration, but where the flexible blades 9 are attached to areas likely to become nodes of vibration, at 45 ° modulo 90 ° with respect to the horizontal axis of the figures, and where the annular resonator n ' is not strictly of revolution in the free state, but comprises two narrowing, as visible in fig. 10, forcing the trainer to exert on the ring an additional radial force to cross them.

The interaction between the driver 8 and the annular resonator 6 is of the mechanical type, and the driver 8 induces a radial centrifugal force on the ring 7.

In a second embodiment, the interaction between the driver 8 and the annular resonator 6 is performed by magnetic interaction means 11 having magnets or / and magnetic poles.

In a particular embodiment, the ring 7 comprises a plurality according to a first number of magnets or magnetic poles, the driver 8 comprises a plurality according to a second number of magnets or magnetic poles, the first number being different of the second number, so that the ring 7 and the driver 8 together constitute a gear reduction mechanism or multiplier. More particularly, the first number differs from the second number by one unit.

In a particular embodiment, the shape of the magnetic interaction means 11 or magnets defines first zones forming potential ramps and second potential barrier zones, making it possible to locate an impulse between the driver 8 and the ring resonator 6.

In a third variant, the interaction between the driver 8 and the annular resonator 6 is performed by electrostatic interaction means comprising electrets and / or electrostatically conductive poles.

In the second or third variant, and as shown in FIG. 5, the form of the magnetic interaction means 11, respectively electrostatic, or said magnets, respectively electrets, defines first zones forming potential ramps and second zones forming potential barriers, for locating a pulse between the driver 8 and the annular resonator 6. On the nonlimiting embodiment of FIG. 5, the coach 8 carries T-shaped magnets 81, which, in certain relative positions of the driver 8 and the ring 7, will arrive in superposition, initially partial and then total, with zones of the ring 7, equipped or not with magnetic tracks 71. The cooperation between the magnets 81 and the tracks 71 is progressive: a first branch 82 of the magnet 81 begins to cooperate with the magnetic track 71 antagonist, forming a potential ramp, then a transverse bar 83 of the magnet 81 forms a real potential barrier generating a pulse.

In an advantageous variant illustrated in FIGS. 4 and 5, 21 and 27 to 31, the ring 7 is ballasted on its periphery, continuously or periodically, for example by flyweights 75 giving the ring 7 thus equipped the appearance of a vehicle crawler.

Figs. 27 to 31 illustrate the benefit of these weights in lowering the frequency of the first eigen modes.

More particularly, the ring 7 is weighted on its periphery, continuously or periodically.

In a particular embodiment, the ring 7 is weighted by a plurality of weights 75.

In a particular embodiment, at least some flyweights 75 extend externally to the ring 7 relative to the axis A, with a T-profile whose vertical bar is radial with respect to the axis A, and whose transverse bar is perpendicular to the axis A and the farthest from it.

FIG. 4 thus illustrates an annular resonator 6 of the "wineglass" type weighted to lower the natural frequency, synchronized with a crank. Fig. 5 illustrates an annular resonator 6 of wineglass type weighted to lower the natural frequency, synchronized magnetically with a wheel.

The use of magnets as interaction elements between the wheel and the resonator eliminates friction losses, noise shocks and losses due to "falls". The shape of the magnets can be optimized to obtain a ramp / potential barrier effect for locating the pulse.

In a first variant of the mechanical type, the driver 8 is advantageously a crank inducing a mechanical deformation of the ring 7.

In embodiments such as those of FIGS. 5 and 6, the driver 8 is a wheel arranged to exert a contactless force on the ring 7.

In a particular embodiment, the wheel carries a crank arm provided with at least one roller 85 arranged to roll or slide on the inner peripheral surface of the ring 7 on the side of the axis A.

In one or other of the embodiments described above, the ring 7 may have sections and / or variable thickness along its periphery.

In a particular embodiment, the ring 7 has, in a non-constrained free state, a polygonal or poly-lobed shape in a plane P orthogonal to the axis A.

In a particular embodiment, and preferred, the ring 7 is made of micro-machinable material or silicon and has a rectangular section in any plane passing through said axis A.

In a particular embodiment, the ring 7 is monobloc with a plurality of flexible blades 9 connecting with a plate 5 that includes the watch movement 10. More particularly, the ring 7 is integral with the plurality of flexible blades 9 and with the deck 5.

In a particular embodiment, the driver 8 is driven by a reduction mechanism or speed multiplier interposed between the energy storage means 3 and the driver 8. More particularly, this gearing mechanism or speed multiplier is a magnetic coupling mechanism as shown in FIG. 6, which illustrates an annular resonator 6 of the "wineglass" type weighted in order to lower the natural frequency, synchronized magnetically with a wheel, via a magnetic multiplier, arranged to have an escape wheel which rotates at a frequency lower than the eigenfrequency of the resonator.

In a particular embodiment, the driver 8 comprises a first disk having alternating magnetic fields 81 in a first step, and which cooperates with a second disk having magnetic fields 82 in a second step, very close, but different from the first step.

Another variant, not illustrated, consists of the combination of a mechanical and magnetic or electrostatic interaction.

The invention also relates to a clockwork movement 10 comprising, fixed on a plate 5, energy storage means 3 arranged to deliver torque to an actuating gear 2 of such a mechanism 1 comprising a annular resonator 6, with a ring 7 fixed by flexible blades 9 to the plate 5, and a driver 8 driven by the gear 2, the coach 8 controlling display means 4, including the display of the second movement 10.

The invention also relates to a timepiece 100 comprising such a movement 10. More particularly, this piece 200 is a watch.

The invention has important advantages: the invention eliminates jerking movements of a Swiss lever escapement, and therefore the losses due to shocks. The exhaust efficiency is substantially increased.

Such an annular resonator does not have pivots, and therefore does not support the frictional losses of the pivots of a spiral balance.

Due to the absence of jerky movements, we can increase the frequency of the resonator, and therefore the quality factor and accuracy of the watch.

The crank variants represent purely mechanical synchronization systems, which can not pick up.

The invention proposes an innovation in the field of the exhaust and the resonator. It has, again, a strong emotional potential because of its visual similarities with a beating heart.

Claims (30)

1. Mechanism for synchronizing (1) the speed of rotation of a gear train (2) subjected to a torque in a watch movement (10), characterized in that said mechanism (1) comprises an annular resonator (6) comprising a ring (7) arranged around an axis (A), which ring (7) is periodically deformable under the action induced by the movement of a driver (8), which comprises said mechanism (1), and which coach (8) is driven, directly or indirectly, by said pair. 2. Mechanism (1) according to claim 1, characterized in that the speed of said driver (8) defines a speed of propagation of a deformation wave in the material of said ring (7) all around it. 3. Mechanism (1) according to claim 1, characterized in that the speed of said driver (8) defines a stationary oscillation wave of said ring (7) between repetitive forms corresponding to stationary modes. 4. Mechanism (1) according to one of the preceding claims, characterized in that said driver (8) drives a display (4) of said watch movement (10). 5. Mechanism (1) according to one of the preceding claims, characterized in that said movement of said driver (8) comprises at least one pivoting movement. 6. Mechanism (1) according to the preceding claim, characterized in that said movement of said driver (8) is a pivoting movement. 7. Mechanism (1) according to one of the preceding claims, characterized in that said driver (8) comprises at least one distal end (800) which extends relative to said axis (A) beyond the smaller diameter that presents, in an unstressed free state, said ring (7) with respect to said axis (A). 8. Mechanism (1) according to the preceding claim, characterized in that said at least one distal end (800) locally deforms said ring (7) in the form of a bead (700) protruding radially outwardly with respect to said axis (A). 9. Mechanism (1) according to claim 7, characterized in that said at least one distal end (800) is arranged to cooperate with at least one clearance (71) that comprises, in a free unstressed state, said ring (7). ) at its inner periphery on the side of said axis (A). 10. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) comprises, in an unstressed free state, at its inner periphery on the side of said axis (A), at least one bulge (70). ) turned towards said axis (A) constituting the smallest diameter that has said ring (7) with respect to said axis (A). 11. Mechanism (1) according to one of the preceding claims, characterized in that the interaction between said driver (8) and said annular resonator (6) is mechanical. 12. Mechanism (1) according to the preceding claim, characterized in that, statically, said driver (8) exerts at least one radial force relative to said axis (A) in the centrifugal direction on said ring (7). 13. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) is fixed to a plate (5) that includes said watch movement (10) by a plurality of flexible blades (9), plus flexible as said ring (7), arranged to maintain said ring (7) substantially centered on said axis (A), and to restrict the movements of said ring (7) in the same plane (P) perpendicular to said axis (A) with limited displacements of the center of inertia of said ring (7) less than one-tenth of the smallest outer dimension of said ring (7) in said plane (P). 14. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) is fixed to a plate (5) that includes said watch movement (10) by a plurality of flexible blades (9), plus rigid that said ring (7), arranged to maintain said ring (7) substantially centered on said axis (A), and to restrict the movements of said ring (7) in the same plane (P) perpendicular to said axis (A) with limited displacements of the center of inertia of said ring (7) less than one-tenth of the smallest outer dimension of said ring (7) in said plane (P). 15. Mechanism (1) according to one of the preceding claims, characterized in that the interaction between said driver (8) and said annular resonator (6) is performed by magnetic interaction means (11) comprising magnets or and magnetic poles. 16. Mechanism (1) according to the preceding claim, characterized in that said ring (7) comprises a plurality according to a first number of magnets or magnetic poles, in that said trainer (8) comprises a plurality according to a second number of magnets or magnetic poles, said first number differing from said second number, so that said ring (7) and said driver (8) together constitute a gear reduction mechanism or multiplier. 17. Mechanism (1) according to the preceding claim, characterized in that said first number differs from said second number by one unit. 18. Mechanism (1) according to the preceding claim, characterized in that the shape of said magnetic interaction means (11) or said magnets defines first zones forming potential ramps and second zones forming potential barriers, to locate a pulse between said driver (8) and said annular resonator (6). 19. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) is ballasted on its periphery, continuously or periodically. 20. Mechanism (1) according to the preceding claim, characterized in that said ring (7) is ballasted by a plurality of weights (75). 21. Mechanism (1) according to the preceding claim, characterized in that at least some said weights (75) extend externally to said ring (7) relative to said axis (A), with a T-shaped profile whose vertical bar is radial to said axis (A), and whose transverse bar is perpendicular to said axis (A) and furthest from it. 22. Mechanism (1) according to one of the preceding claims, characterized in that said driver (8) is a wheel arranged to exert a force without contact on said ring (7). 23. Mechanism (1) according to the preceding claim, characterized in that said wheel carries a crank arm provided with at least one roller (85) arranged to roll or slide on the inner peripheral surface of said ring (7) on the side of said axis (A). 24. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) has sections and / or variable thickness along its periphery. 25. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) has, in an unstressed free state, a polygonal or multi-lobed shape in a plane (P) orthogonal to said axis (A). 26. Mechanism (1) according to one of the preceding claims, characterized in that said ring (7) is of micro-machinable material or silicon and has a rectangular section in any plane passing through said axis (A). 27. Mechanism (1) according to the preceding claim, characterized in that said ring (7) is integral with a plurality of flexible blades (9) for connection with a plate (5) that includes said watch movement (10). 28. Mechanism (1) according to the preceding claim, characterized in that said ring (7) is integral with said plurality of flexible blades (9) and with said plate (5). 29. A watch movement (10) comprising, fixed on a plate (5), energy storage means (3) arranged to deliver said torque to a gear train (2) for actuating a mechanism (1) according to one of the preceding claims comprising a said annular resonator (6), with a said ring (7) fixed by flexible blades (9) to said plate (5), and a said driver (8) driven by said gear ( 2), said driver (8) controlling display means (4) of said movement (10). 30. Timepiece (100) comprising a movement (10) according to the preceding claim, characterized in that it is a watch.