TIMEPIECE REGULATING MECHANISM WITH OPTIMISED MAGNETIC ESCAPEMENT

Abstract

Timepiece regulating mechanism including an energy storage means delivering an output torque (CS), via a train (3), to a wheel set (4) forming a magnetic escapement mechanism (10) with a resonator wheel set (5) subjected to the torque from a return means (6) and cooperating therewith, either directly or via a magnetic stop member (7), this magnetic escapement mechanism (10) being arranged to operate when the wheel set (4) receives a torque higher than or equal to a maintenance torque (CE), and the train (3) includes a torque regulating means (30) arranged to deliver to the wheel set (4) a constant torque comprised between 1.0 and 2.0 times the maintenance torque (CE), the torque regulating means (30) including a fusee (8) of continuously variable cross-section, from which unwinds a chain (9), wound by a drum (21), directly or indirectly driven by the energy storage means (2).

Claims

1. A timepiece regulating mechanism with a magnetic escapement, including transmission train, a magnetic escape wheel set, a resonator wheel set, a return means, said regulating mechanism including an energy storage means arranged to deliver energy in the form of an output torque, via said transmission train, to said magnetic escape wheel set, forming a magnetic escapement mechanism with said resonator wheel set subjected to the torque from said return means, said magnetic escape wheel set cooperating with said resonator wheel set, either directly, or via a magnetic stop member comprised in that case in said regulating mechanism, said magnetic escapement mechanism being arranged to operate when said magnetic wheel set receives a torque higher than or equal to a maintenance torque specific to said magnetic escapement mechanism, wherein said transmission train includes a torque regulating means arranged to deliver to said magnetic escape wheel set a constant torque comprised between 1.0 and 2.0 times said maintenance torque, said torque regulating means including a fusee of continuously variable cross-section from which unwinds a chain wound by a drum driven by said energy storage means.

2. The regulating mechanism according to claim 1, wherein said energy storage means includes at least one barrel.

3. The regulating mechanism according to claim 1, wherein said transmission train includes a speed increasing gear train, arranged to transform said output torque into a lower intermediate torque, at the input of said torque regulating means.

4. The regulating mechanism according to claim 1, wherein said magnetic escapement mechanism includes a magnetic stop member between said magnetic escape wheel set and said resonator wheel set, said magnetic escape wheel set including at least one magnetized or ferromagnetic track, with a period of travel in which the magnetic characteristics are repeated, said stop member including at least one magnetized or ferromagnetic pole piece, said pole piece being mobile in a transverse direction relative to the direction of travel of at least one element on a surface of said track, and at least said pole piece or said track creating a magnetic field in an air-gap between said at least one pole piece and said at least one surface, and further wherein said pole piece is confronted by a magnetic field barrier on said track just before each transverse motion of said stop member controlled by the periodic action of said resonator wheel set.

5. A timepiece movement including a regulating mechanism according to claim 1.

6. A watch including a timepiece movement according to claim 5.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] Other features and advantages of the invention will appear upon reading the following detailed description, with reference to the annexed drawings, in which:

[0021] FIG. 1 represents a schematic perspective view of a timepiece regulating mechanism with a magnetic pallet lever escapement mechanism optimised according to the invention through the insertion of a fusee-chain transmission.

[0022] FIGS. 2 and 3 are graphs illustrating the decrease in efficiency of a magnetic escapement when the torque is high: FIG. 2 shows the absolute channels of loss in a conventional magnetic escapement, where only losses due to rebounds of the magnetic escape wheel vary when the torque varies, and FIG. 3 represents the relative channels of loss in a conventional magnetic escapement: the escapement efficiency is low when the torque is high, and high when the torque is low.

[0023] FIG. 4 is a graph illustrating the consistency of efficiency over time for a regulating mechanism according to the invention.

[0024] FIG. 5 represents a schematic plan view of a non-limiting example of a magnetic escapement mechanism incorporated in such a regulating mechanism according to the invention.

[0025] FIG. 6 shows a schematic, plan view of a non-limiting example of a gear train according to the invention.

[0026] FIG. 7 is a block diagram representing a watch including a movement equipped with such an optimised magnetic pallet lever escapement mechanism.

[0027] FIG. 8 shows a schematic perspective view of such a watch.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0028] The invention concerns the field of timepiece regulating mechanisms, and more particularly field-effect, contactless or reduced contact escapement mechanisms of the magnetic or electrostatic type.

[0029] FIGS. 2 and 3 are graphs illustrating the decrease in efficiency of a magnetic escapement when there is an increase in the torque applied to the escape wheel set, generally an escape wheel. FIG. 2 shows the losses on the ordinate and the torque applied to the escape wheel set on the abscissa. It illustrates the absolute channels of loss in a conventional escapement mechanism, where only the losses pR due to rebounds of the escape wheel set, particularly a magnetic escape wheel, vary when the torque varies. These rebounds consume unusable excess energy, dissipated in the air and in the pivots. The upper curve PTF illustrates the total power provided, which is the sum of the power dissipated by resonator PDR which is at a constant level, which is the advantage of a magnetic or electrostatic escapement, of losses through shocks and friction pCF (which are considerable when the escapement mechanism includes a stop member such as a pallet lever or similar) and of losses through rebound pR, which represent the surplus energy consumption, which is inefficient.

[0030] The level of torque applied to the escape wheel set, required for operation of the system, is the maintenance torque CE, at which losses through rebound are minimum or zero; the maximum level of torque CMAX depends on the energy source and on the gear train that transmits the energy to the escape wheel set. FIG. 3 shows efficiency on the ordinate and the torque applied to the escape wheel set on the abscissa. It illustrates the relative channels of loss in the same conventional magnetic escapement: the escapement efficiency is low at level pMIN when the torque is high at value CMAX, and it is high at level pMAX when the torque is at value CE.

[0031] The invention thus proposes to control losses, and to avoid wasting energy, by limiting or completely eliminating rebounds. To this end, it proposes to subject the escape wheel set to a constant torque, with a value at least equal to maintenance torque CE. FIG. 4 thus shows the consistency of efficiency p over time at value p MAX.

[0032] The invention is described here in a particular, non-limiting embodiment, which is that of a magnetic escapement. It can be implemented in an electrostatic embodiment, with reference to the aforecited EP Patent 13199427.

[0033] It is also illustrated in a particular non-limiting variant of a magnetic escapement including a stop member, described in the same document.

[0034] The invention can equally be implemented in a variant without a stop member, with a direct interaction between an escape wheel set and a balance or similar, described in particular in EP Patent 14186261.5 in the name of Nivarox-FAR SA, incorporated herein by reference.

[0035] FIG. 1 shows a non-limiting construction example of a timepiece regulating mechanism 1 including a magnetic pallet lever escapement mechanism 10, optimised in accordance with the invention. The invention combines the advantages of a field-effect escapement, particularly of a magnetic pallet lever escapement in the variant illustrated by the Figures, which is a constant force mechanism as regards the resonator wheel set, typically a balance, with the advantages of a torque regulating mechanism. More particularly, the transmission of torque from an energy source 2, especially but not limited to at least one barrel 20, by a constant torque system, for example a fusee-chain, ensure an almost constant torque at the escapement.

[0036] The torque value CE provided to the escape wheel set must be chosen to be low, so that the escapement has the highest efficiency, on the order of 60% to 70%.

[0037] Thus, the invention concerns a timepiece regulating mechanism 1 with a magnetic escapement including an energy storage means 2 arranged to deliver energy in the form of an output torque CS, by means of a transmission train 3, to a magnetic escape wheel set 4.

[0038] This magnetic escape wheel set 4, illustrated here in the form of a magnetic escape wheel, forms a magnetic escapement mechanism 10 with a resonator wheel set 5 subjected to the torque from a return means 6, respectively illustrated here in the form of a balance and a balance spring.

[0039] Magnetic escape wheel set 4 cooperates with resonator wheel set 5, either directly, or via a magnetic stop member 7, illustrated here in the form of a magnetic pallet lever.

[0040] Magnetic escapement mechanism 10 is arranged to operate when magnetic escape wheel set 4 receives a torque higher than or equal to a maintenance torque CE specific to magnetic escapement mechanism 10.

[0041] According to the invention, transmission train 3 includes a torque regulating means 30, which is arranged to deliver to magnetic escape wheel set 4 a constant torque comprised between 1.0 and 2.0 times the maintenance torque CE, more particularly between 1.0 and 1.5 times the maintenance torque CE, more particularly still between 1.0 and 1.2 times the maintenance torque CE, and as close as possible to maintenance torque CE, depending upon the torque consuming complications, and the structure of the going train. This torque corresponds to auto-start and to the elimination of rebounds.

[0042] Naturally, the invention also concerns the variant with an electrostatic escapement, which is not described in detail, and which those skilled in the art will know how to implement with reference to the aforecited documents.

[0043] In an advantageous application and as seen in FIG. 1, torque regulating means 30 includes a fusee 8 of continuously variable cross-section, from which unwinds a chain 9, wound by a drum 21, directly or indirectly driven by energy storage means 2.

[0044] More particularly, energy storage means 2 includes at least one barrel 20. The invention thus uses, in an optimum manner, all the energy from the barrel, which no longer rotates at constant velocity, since its instantaneous tangential velocity dpends on the instantaneous winding radius of chain 9 on fusee 8.

[0045] In a variant, seen in FIG. 6, transmission train 3 includes a speed increasing gear train 31, arranged to transform output torque CS into a lower intermediate torque CI, at the input of torque regulating means 30.

[0046] In a variant, seen in FIG. 5, magnetic escapement mechanism 10 includes a magnetic stop member 7 between magnetic escape wheel set 4 and resonator wheel set 5. This escape wheel set 4 includes at least one magnetized or ferromagnetic track 40, with a period of travel PD in which the magnetic characteristics are repeated. Stop member 7 includes at least one magnetized or ferromagnetic pole piece 70, and this pole piece 70 is mobile in a transverse direction DT relative to the direction of travel DD of at least one component of a surface 41 of track 40. At least pole piece 70 or track 40 creates a magnetic field in an airgap 5 between the at least one pole piece 70 and the at least one surface 41. Pole piece 70 is confronted with a magnetic field barrier 42 on track 40 just before each transverse motion of stop member 7 controlled by the periodic action of resonator wheel set 5.

[0047] The invention also concerns a timepiece movement 100 including such a regulating mechanism 1.

[0048] The invention also concerns a watch 1000 including a movement 100 of this type.

[0049] In short, the high efficiency value, which has become constant, makes it possible to increase the power reserve by more than 50% compared to a conventional (mechanical or magnetic) Swiss lever configuration, for a given barrel, resonator and regulating power.

[0050] For the user, this means that the watch can go longer without needing to be wound or recharged (spring).

[0051] The invention combines the regularity of rate specific to the field effect escapement mechanism, particularly a magnetic escapement, with a considerable energy saving.