Timepiece regulating mechanism with articulated resonators

Abstract

A timepiece regulating mechanism including primary resonators each with an inertial weight suspended by flexible strips to a fixed structure with respect to which this weight pivots, and mechanical device of synchronizing the primary resonators which include, between the inertial weights, an articulated connection which, under normal conditions, allows pivoting of the inertial weights in opposite directions of rotation and with close rotation angles, and during a shock, prevents pivoting thereof in the same direction of rotation, the mechanism including an oscillator with a frictional rest escapement mechanism arranged to cooperate alternately with the primary resonators, on pallet stones of the inertial weights.

Claims

1. A timepiece regulating mechanism comprising: a plurality of primary resonators, including a first primary resonator and a second primary resonator, the first primary resonator including at least one first inertial weight, which is pivotable with respect to a first fixed structure to which said first inertial weight is suspended by a plurality of first flexible strips, and the second primary resonator including at least one second inertial weight, which is pivotable with respect to a second fixed structure to which said second inertial weight is suspended by a plurality of second flexible strips, said first fixed structure being spaced apart and separate from said second fixed structure, wherein said regulating mechanism includes mechanical means of synchronization of at least said first and second primary resonators which include an articulated connection between said first and second inertial weights comprised in said first and second primary resonators, which articulated connection is arranged, under normal conditions, to allow pivoting of said first and second inertial weights in opposite directions of rotation and with close rotation angle values, and is arranged to prevent, during a shock, pivoting of said first and second inertial weights in the same direction of rotation, wherein said regulating mechanism includes an oscillator which includes a frictional rest escapement mechanism which is arranged to cooperate alternately with said first and second primary resonators, on pallet stones comprised in said first and second inertial weights of said first and second primary resonators.

2. The timepiece regulating mechanism according to claim 1, wherein said articulated connection is a connection in which there is play.

3. The timepiece regulating mechanism according to claim 1, wherein one of said first and second inertial weights comprises a pin that slides with play in a slot comprised in the other of said first and second inertial weights, said slot being V-shaped so as to allow, under normal conditions, pivoting of said first and second inertial weights in opposite directions of rotation and with the same rotation angle value.

4. The timepiece regulating mechanism according to claim 1, wherein said first and second primary resonators have the same frequency and poising adjustment, and wherein said articulated connection is only in mechanical contact in case of shock.

5. The timepiece regulating mechanism according to claim 1, wherein said frictional rest escapement mechanism comprises an escape wheel with teeth which are curved and arranged to cooperate with said pallet stones which are straight.

6. The timepiece regulating mechanism according to claim 1, wherein said frictional rest escapement mechanism comprises an escape wheel made of silicon and/or silicon dioxide, and wherein said pallet stones are made of ruby so as to minimise the contact forces between the teeth of said escape wheel and said pallet stones.

7. The timepiece regulating mechanism according to claim 1, wherein said first and second plurality of flexible strips comprises at least one position insensitive pivot including head-to-tail V-shaped portions.

8. The timepiece regulating mechanism according to claim 1, wherein said first and second plurality of flexible strips comprises at least one position insensitive pivot with strips in two parallel planes that cross in projection.

9. The timepiece regulating mechanism according to claim 1, wherein said first and second plurality of flexible strips comprises at least one Wittrick-type V-shaped pivot, wherein said articulated connection removes position sensitivity.

10. A timepiece movement comprising one of the timepiece regulating mechanism according to claim 1.

11. A watch comprising the timepiece movement according to claim 10.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other features and advantages of the invention will appear upon reading the following detailed description, with reference to the annexed drawings, in which:

(2) FIG. 1 represents a schematic, plan view of a regulating mechanism according to the invention, comprising two resonators each including an inertial weight suspended by flexible strips, which weights define together an articulated connection with play, in a first angular rest position of each resonator.

(3) FIG. 2 represents, in a similar manner to FIG. 1, the same mechanism in an intermediate oscillation position.

(4) FIG. 3 represents, in a similar manner to FIG. 1, a similar mechanism, with an escapement on one of the resonators.

(5) FIG. 4 represents, in a similar manner to FIG. 1, a similar mechanism, with an escapement on both resonators, in a first angular rest position of each resonator.

(6) FIG. 5 represents, in a similar manner to FIG. 4, the same mechanism in an intermediate oscillation position.

(7) FIG. 6 represents a schematic, plan view of a flexural bearing in the form of a top-to-tail V-shaped pivot.

(8) FIG. 7 represents a schematic, plan view of a flexural bearing in the form of a pivot with strips that cross in projection.

(9) FIG. 8 represents a schematic, plan view of a flexure bearing in the form of a Wittrick-type pivot.

(10) FIG. 9 represents, in a similar manner to FIG. 1, a similar mechanism, with a detached, direct, double tangential impulse escapement.

(11) FIG. 10 is a block diagram representing a watch including a timepiece movement comprising such a regulating mechanism.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(12) The invention concerns a timepiece regulating mechanism 300 comprising a plurality of primary resonators 100, 200. This display mechanism 300 is a mechanism with articulated resonators.

(13) The invention is applicable, in particular but not exclusively, to resonators on short-stroke flexural pivots for mechanical watches, which are usually very sensitive to disturbance during wear, and particularly very sensitive to angular accelerations, especially in rotation.

(14) The Figures only illustrate, in a non-limiting manner, the variant with two such primary resonators 100, 200, but those skilled in the art will have no difficulty in extrapolating the features of the invention to a higher number of resonators.

(15) These primary resonators 100, 200 each include at least one inertial weight 102, 202, which is pivotable with respect to a fixed structure 101, 201, to which inertial weight 102, 202 is suspended by a plurality of flexible strips 103, 203. These flexible strips define, in a known manner, a virtual pivot axis about which the inertial weight concerned pivots, with a very small distance, of several micrometres or tens of micrometres, in particular less than 30 micrometres, between the position of the instantaneous pivot axis and the theoretical pivot axis dictated by the shape and position of the flexible strips.

(16) According to the invention, this regulating mechanism 300 includes mechanical means for synchronizing at least two such primary resonators 100, 200. These mechanical synchronizing means include an articulated connection between two inertial weights 102, 202 comprised in the two primary resonators 100, 200.

(17) This articulated connection is arranged, under normal conditions, to allow pivoting of the two inertial weights 102, 202, in opposite directions of rotation, and with close rotation angle values. The articulated connection is arranged, in case of shock, to prevent pivoting of the two inertial weights 102, 202 in the same direction of rotation.

(18) In a particular embodiment, this articulated connection has some play.

(19) More particularly and in a non-limiting manner, and as seen in FIGS. 1 to 8, this articulated connection results from the cooperation between a pin or suchlike and a groove of suitable shape: more particularly, one of the two inertial weights 102, 202, includes a pin 104, which slides with play in a slot 204 comprised in the other of the two inertial weights 102, 202. This slot 204 is V-shaped, so as to allow, under normal conditions, pivoting of the two inertial weights 102, 202, in opposite directions of rotation and with the same rotation angle value.

(20) Thus, as seen in FIGS. 1 and 2, the two resonators are synchronized by pin 104 mounted on a first arm of first inertial weight 102 of first resonator 100, whose first virtual pivot axis is designed D1. Pin 104 slides in slot 204 in a second arm of second inertial weight 202 of second resonator 200. There is a space between pin 104 and slot 204 so as to minimise friction. Slot 204 is V-shaped, widening towards its opening 205 away from second virtual pivot axis D2 of second inertial weight 202, this V-shape allows first resonator 100 and second resonator 200 to have the same opposite rotation angle, and prevents pin 104 and slot 204 touching each other, in order not to impair the mechanical efficiency of the resonator.

(21) In case of rotary shock, first resonator 100 and second resonator 200 tend to rotate in the same direction, and the articulated connection prevents them doing so, which ensures proper operation of the escapement with which at least one of the two resonators cooperates. There is no untimely stopping, as would be the case of a single resonator on a short-stroke flexural pivot.

(22) The resonator oscillations can be maintained in various ways.

(23) FIG. 3 illustrates the configuration in which regulating mechanism 300 includes an oscillator, which includes an escapement mechanism 400 and one of primary resonators 100, 200. The mechanical synchronizing means, notably in the pin/slot variant, as illustrated, are arranged to maintain the oscillations of every other primary resonator 100, 200; here first resonator 100 cooperates with escapement 400 and the oscillations of second resonator 200 are maintained by the first.

(24) More particularly, this oscillator includes enlarged pallets 401, as described in European Patent Application No EP16200152 in the name of ETA Manufacture Horlogère Suisse, and in the Applications that depend thereon: PCT/EP2017/069037, PCT/EP2017/069038, PCT/EP2017/069039, PCT/EP2017/069040, PCT/EP2017/069041, PCT/EP2017/069043, PCT/EP2017/078497, PCT/EP2017/080121.

(25) An arm 110, comprised in primary resonator 100, 200 with which escapement mechanism 400 is arranged to cooperate—first resonator 100 in the case of FIG. 3—is arranged to cooperate with enlarged pallets 401.

(26) A second means of maintaining the resonator oscillations is to use a frictional rest escapement, which acts alternately on first resonator 200 and second resonator 200.

(27) Thus, according to the invention and as seen in FIGS. 4 and 5, regulating mechanism 300 includes an oscillator that includes a frictional rest escapement mechanism 400, which is arranged to cooperate alternately with two primary resonators 100, 200, on pallet stones 121, 221, comprised in the two inertial weights 102, 202 of these two primary resonators 100, 200.

(28) This variant has many advantages.

(29) Indeed, the energy is distributed equally over the two resonators. When the two primary resonators 100, 200 have the same frequency and poising adjustment, the articulated connection is only in mechanical contact in case of shock: pin 104 and slot 204 never touch each other, except in case of external disturbance. This makes it possible to minimise disruption to operation caused by friction between pin 104 and slot 204.

(30) Preferably, the geometry of pallet stones 121, 221, is the same for both resonators, which makes it possible to optimise the friction paths. Compared to a conventional frictional rest escapement, in which both pallet stones are on the same mobile element, the configuration according to the invention, with one pallet stone per mobile element, makes it possible to choose a pallet stone geometry having the same efficiency, without being obliged to use the curved pallet stones known from the Graham deadbeat escapement. FIGS. 4 and 5 illustrate a preferred variant, with an escape wheel 420 with curved teeth 421, and arranged to cooperate with pallet stones 121, 221, which are straight. This configuration means pallet stones can be made from ruby, which remains economical, and it is possible to combine ruby pallet stones with a silicon or similar escape wheel 420 and thus to avoid the high contact forces of a silicon/silicon combination if curved pallet stones had to be made from silicon. Indeed, the silicon embodiment of escape wheel 420 remains very advantageous, since it minimises its inertia, which can be further improved with a maximum recess and minimum thickness. The pallet stones are thicker than the wheel and it is perfectly appropriate to make them from ruby using the traditional method.

(31) Thus, more particularly, frictional rest escapement mechanism 400 includes an escape wheel 420 made of silicon and/or silicon dioxide, and pallet stones 121; 221 are made of ruby to minimise the contact forces between teeth 421 of escape wheel 420 and pallet stones 121, 221.

(32) A third means of maintaining the resonator oscillations consists in using an articulated regulating mechanism 300, which includes an oscillator that includes a direct, double tangential impulse, detached escapement mechanism 400, as seen in FIG. 9. This regulating mechanism 300 includes a kinematic connection 600 between two inertial weights 102, 202 comprised in two primary resonators 100, 200 and which are arranged to pivot in opposite directions. These two inertial weights 102, 202 comprise pallet stones 121, 221, arranged to cooperate with teeth 421, comprised in an escape wheel 420 comprised in escapement mechanism 400, so as to produce a direct impulse from escape wheel 420 to one of pallet stones 121, 221 at each vibration of the oscillation. This kinematic connection 600 advantageously includes the articulated connection with play between the two inertial weights 102, 202.

(33) This mechanism is comparable to a coaxial escapement, in which the direct impulse from the pallets is replaced here by a direct impulse on the inertial weight of the second resonator.

(34) More particularly, in a variant illustrated by FIG. 9, regulating mechanism 300 includes a bistable stopper 700, which is arranged to cooperate, on the one hand, via a first arm 701, with one of teeth 421 to stop escape wheel 420, and on the other hand, via a fork 703, with a pin 207 comprised in one of the two inertial weights 102, 202. This stopper with two stable positions, which resembles a pallet lever, serves only for the lock function to stop the escape wheel via this first arm 701. The pivoting of the second inertial weight causes pin 207 to be released from fork 703, and then lets stopper 700 pivot, and thus allows rotation of the escape wheel.

(35) According to this third means, escapement mechanism 400 is a detached escapement with a direct, double tangential impulse.

(36) Indeed, it is detached since the resonator is free during part of its oscillation, which is favourable from a chronometric point of view.

(37) It has a double impulse, since one impulse is produced at each vibration of the oscillation.

(38) It has a tangential impulse, since the contact which produces the impulse occurs substantially on the line that connects the centre of inertia of the inertial weight concerned to the centre of the escape wheel (as opposed to the friction impulse of a conventional Swiss lever escapement).

(39) It has a direct impulse since the impulse is given directly from the wheel to the resonator, without necessarily passing through pallets.

(40) It is clear that this direct double impulse is possible only because the two inertial weights pivot in opposite directions. Thus, the escape wheel, which always rotates in the same direction, can push one of the inertial weights during the first vibration, and the other during the second vibration.

(41) The dot and dash lines A, B, C, D of FIG. 9 illustrate relative advantageous arrangements: straight line A joining the virtual pivots of two flexural bearings is perpendicular to direction B coming from the centre of the escape wheel which is the bisection of these two pivots, the impulse between a tooth 421 and a pallet stone 121, 221, occurring close to this straight line B: one of the pivots defines with the axis of stopper 700 a straight line C perpendicular to straight line D joining the axis of the escape wheel and the axis of the stopper; the contact between pin 207 and fork 703 occurs in proximity to this straight line C.

(42) With regard to the flexural pivots, various configurations can be used.

(43) FIG. 6 illustrates the case where the plurality of flexible strips 103, 203, includes at least one pivot including head-to-tail V shapes, this configuration being known to be insensitive to the positions of the watch.

(44) FIG. 8 illustrates the case where the plurality of flexible strips 103, 203, includes at least one pivot having strips in two parallel planes that cross in projection, this configuration also being known to be insensitive to the positions of the watch, in specific angle and crossing point conditions.

(45) FIG. 7 illustrates the case where the plurality of flexible strips 103, 203 include at least one V-shaped Wittrick-type pivot, which is known to be sensitive to the positions of the watch during wear. However, owing to the means of synchronizing with the articulated connection, this configuration can also be used, since the articulated connection removes position sensitivity. This variant is particularly simple to make.

(46) The invention also concerns a timepiece movement 500 including at least one such timepiece regulating mechanism 300.

(47) The invention also concerns a watch 1000 including at least one such movement 500, and/or at least one such timepiece regulating mechanism 300.