Patent Grant
9958832
The invention concerns a timepiece regulating mechanism comprising a plate and, mounted to move at least in a pivoting motion with respect to said plate, an escape wheel that pivots about an axis of escapement and is arranged to receive a drive torque, via a gear train, and a first oscillator comprising a first rigid structure connected to said plate by first elastic return means,
The invention concerns a timepiece movement including such a regulating mechanism.
The invention concerns a timepiece including such a movement.
The invention concerns the field of the regulation of mechanical timepieces, in particular mechanical watches.
In a timepiece escapement mechanism, the efficiency of the Swiss lever escapement that is generally used is relatively low (on the order of 35%).
The main sources of losses in a Swiss lever escapement are:
the friction of the pallet-stones on the teeth;
shocks due to the jerky movements of the wheel and the pallet lever;
the drop necessary to accommodate machining errors.
The development of a new system for synchronizing a gear train driven by a mainspring with a resonator inside a watch movement, with greater efficiency than that of a Swiss lever escapement, may result in:
an increase in the autonomy of the watch;
an improvement in the chronometric properties of the watch; marketing and aesthetic differentiation.
Systems are sought that can synchronize a gear train driven by a mainspring with a resonator, and which offer greater efficiency than the efficiency of the Swiss lever escapement.
The invention proposes to create mechanisms that offer greater efficiency than the efficiency of the Swiss lever escapement.
The invention consists of a system for synchronizing a gear train, in particular driven by a mainspring, with a resonator.
To this end, the invention concerns a timepiece regulating mechanism according to claim 1.
The invention concerns a timepiece movement including such a regulating mechanism.
The invention concerns a timepiece including such a movement, characterized in that the timepiece is a watch.
Other features and advantages of the invention will appear upon reading the following detailed description, with reference to the annexed drawings, in which:
The invention consists of a system for synchronizing a gear train driven by a mainspring with a resonator.
The invention more particularly concerns the regulation of mechanical movements.
The principle of the invention is to fit a mechanical watch with a movement comprising at least two series connected oscillators, in particular placed one atop the other, synchronized with a gear train via mechanical cooperation between the last oscillator of the cascade and a component of the gear train, between guide means and complementary guide means, notably a finger and a cam, or more particularly a finger and a grooved wheel. The invention is illustrated in a non-limiting manner, with only two cascade connected oscillators.
More particularly, the invention concerns a timepiece regulating mechanism 100. This regulating mechanism 100 comprising a main plate 1 and, mounted to move at least in a pivoting motion relative to plate 1, an escape wheel 51 and a first resonator 110.
Escape wheel 51 pivots about an axis of escapement D and is arranged to receive a drive torque, via a gear train. In a particular application, this drive torque is provided by an energy storage means, such as a barrel, of a movement 200 in which regulating mechanism 100 is intended to be incorporated.
First resonator 110 comprises a first rigid structure 310, which is connected to plate 1 by first elastic return means 210.
According to the invention, regulating mechanism 100 also includes at least a second oscillator 120. This second oscillator 120 comprises a second rigid structure 320, which is connected to first rigid structure 310 of first oscillator 110 by second elastic return means 220.
These second elastic return means 220 are arranged to allow at least a pivoting motion of second rigid structure 320 with respect to first rigid structure 310.
This second structure 320 includes guide means 42, which are arranged to cooperate with complementary guide means 52 comprised in escape wheel 51. These guide means 42 and complementary guide means 52 together form a means for transmitting motion, to synchronize first oscillator 110 and second oscillator 120 with the gear train to which escape wheel 51 belongs.
This motion transmission means may take different forms: a pin-groove system, as illustrated in a non-limiting manner by the Figures, a crank-connecting rod or other system.
The invention is described here with two series connected oscillators. Naturally, it is also applicable to a cascade of series connected oscillators.
Preferably, first oscillator 110 and second oscillator 120 have equal natural frequencies.
Preferably, first oscillator 110 and second oscillator 120 have a substantially constant angular phase shift between them, close to 90°.
These at least two resonators, formed by first oscillator 110 and second oscillator 120, preferably having the same natural frequency, each having one degree of angular freedom, are placed one atop the other such that a particular point of the second resonator travels a closed, potato-shaped trajectory 53 about a fixed point, which here is pivot 151 of escape wheel 51, for the mechanisms illustrated in the Figures. The closer the shape of trajectory 53 is to a circle, the better the synchronization will be. Trajectory 53 is more generally an ellipse, whose eccentricity depends on the geometry of the mechanism, particularly at the connection between guide means 42 and complementary guide means 52.
In an advantageous embodiment, first oscillator 110 pivots about a first pivot axis O1, and oscillates in a plane parallel to plate 1 on either side of a first plane axis A1, second oscillator 120 pivots about a second pivot axis O2 and oscillates in a plane parallel to plate 1 about a second plane axis A2, and, in projection onto plate 1, first plane axis A1 and second plane axis A2 form with each other an angle comprised between 60° and 120°.
Preferably, this angle is comprised between 80° and 100°. In a particular application, it is 90°.
In the particular embodiments illustrated by the Figures, the most downstream oscillator, here the second oscillator 120, has, at a particular point, a means of interaction, such as a pin, forming guide means 42 for cooperating with escape wheel 51. The oscillations of the two resonators, first oscillator 110 and second oscillator 120, are maintained by escape wheel 51, which also has a means of interaction, such as a cam or a groove, and particularly a radial groove, forming complementary guide means 52. Escape wheel 51 is subjected to a drive torque. Its speed is synchronized by the frequency of the two resonators.
The movement of each oscillator of regulating mechanism 100 is preferably planar. The planes of mobility of the various oscillators forming regulating mechanism 100 may coincide, or be parallel to each other.
Thus, preferably, regulating mechanism 100 comprises first planar guide means, which are arranged to allow at least a pivoting motion of first structure 310 with respect to a point on plate 1, in a plane P parallel to that of plate 1. Likewise, regulating mechanism 100 comprises second planar guide means, which are arranged to allow an at least pivoting motion of second structure 320 with respect to first structure 310 in plane P or in a plane parallel to said plane P.
In a particular embodiment, second rigid structure 320 is mounted to pivot on first rigid structure 310.
More specifically, first oscillator 110 comprises a first sprung balance assembly 11. This first sprung balance 11 comprises a first balance 31, forming first rigid structure 310, and a first balance spring 21, which forms the first elastic return means 210, and the outer coil of which is attached to plate 1 at a first balance spring stud 61, and which pivots about a first pivot axis O1.
First balance 31 comprises a first pivot 41, which is off-centre with respect to first pivot axis O1. This first pivot 41 defines a second pivot axis O2 about which pivots a second sprung balance assembly 12, which forms second oscillator 120.
This second sprung balance assembly 12 comprises a second balance 32, which forms second rigid structure 320, and a second balance spring 22, which forms the second elastic return means 220, and whose outer coil is attached to first balance 31 at a second balance spring stud 62. This second balance 32 forms second structure 320 comprising guide means 42.
A first balance, formed here in a non-limiting manner of two circular sectors, end-to-end, forms first rigid structure 310. A second balance, formed here in a non-limiting manner of a circular sector, forms second rigid structure 320. More particularly, first balance 310 and second balance 320 are coplanar.
More specifically, in this second variant, the first elastic return means 210 comprise at least a first flexible strip 210A and a second flexible strip 210B, which are crossed with each other, and which together form the first planar guide means arranged to allow at least a pivoting motion of the first structure 310 with respect to a part 101 of plate 1 in a plane P parallel to that of plate 1. This part 101 of plate 1 may be an added element, or form part of plate 1. First flexible strip 210A is attached to part 101 of plate 1 at a point 211, and to first balance 310 at a point 214, and second flexible strip 210B is attached to part 101 of plate 1 at a point 212, and to first balance 310 at a point 213.
In a preferred embodiment, first flexible strip 210A and second flexible strip 210B are remote from each other and arranged in two distinct planes parallel to plate 1.
Second elastic return means 220 comprise, in a similar manner, at least a third flexible strip 220A and a fourth flexible strip 220B crossed with each other and together forming the second planar guide means arranged to allow at least a pivoting motion of second structure 320 with respect to first structure 310 in a plane P parallel to that of plate 1, and to ensure an elastic return function. Third flexible strip 220A is attached to first balance 310 at a point 312, and to second balance 320 at a point 313, and fourth flexible strip 220B is attached to first balance 310 at a point 311, and to second balance 320 at a point 314.
In a preferred embodiment, third flexible strip 220A and fourth flexible strip 220B are remote from each other and arranged in two distinct planes parallel to plate 1.
These various crossed strips are advantageously made in two parallel planes.
In an advantageous embodiment, part 101 of plate 1, first flexible strip 210A and second flexible strip 210B, first balance 310, third flexible strip 220A and fourth flexible strip 220B, second balance 320, form a one-piece assembly made of micromachinable material, such as silicon or suchlike.
In a particular embodiment, the whole of plate 1, first flexible strip 210A and second flexible strip 210B, first balance 310, third flexible strip 220A and fourth flexible strip 220B, second balance 320, form a one-piece assembly made of micromachinable material, such as silicon or suchlike.
For both of the first and second embodiments, which are not limiting of the invention, guide means 42 and complementary guide means 52 may take different forms.
In the variants illustrated by the Figures, the cooperation between guide means 42 and complementary guide means 52 is mechanical.
In the embodiments illustrated in
Preferably, this cam is a groove having parallel sides comprised in escape wheel 51.
In an advantageous embodiment of the second variant, part 101 of plate 1, first flexible strip 210A and second flexible strip 210B, first balance 310, third flexible strip 220A and fourth flexible strip 220B, second balance 320 and finger 42 (or suchlike), form a one-piece assembly made of micromachinable material, such as silicon or suchlike.
In particular, the cam is a substantially radial groove, or strictly radial in the case of the Figures, of escape wheel 51.
Advantageously, the cam-groove comprises a first inner radial portion with respect to axis of escapement D, which is tangent to a second curved portion whose concavity is constant or decreases as it moves away from axis of escapement D so as to compensate for isochronism defects.
In a particular embodiment, the finger is a pin which is arranged to cooperate with minimum play with the groove, the motion transmission means is thus a pin-groove system.
In a particular embodiment, guide means 42 comprise a finger carrying an inner cage of a ball bearing. The outer cage of the bearing is advantageously mounted in a slide-contact rubbing with friction inside a radial groove of the escape wheel. This slide-contact promotes a 90° phase shift between the two resonators and thus prevents the trajectory collapsing into a line.
In a particular embodiment, first oscillator 110 pivots about a first pivot axis O1 and oscillates in a plane parallel to plate 1 on either side of a first plane axis A1, second oscillator 120 pivots about a second pivot axis O2 and oscillates in a plane parallel to plate 1 about a second plane axis A2, and, in a rest position of first oscillator 110 and of second oscillator 120 free of any excitation, first pivot axis O1, second pivot axis O2, and the finger together define an angle e comprised between 60° and 120°. Preferably, this angle e is comprised between 80° and 100°.
In a particular embodiment of the invention, the cooperation between guide means 42 and complementary guide means 52 is magnetic and/or electrostatic.
Thus, more particularly, in another embodiment that is not illustrated by the Figures, to remove friction, guide means 42 include at least one magnet or one ferromagnetic path, arranged to cooperate with at least one magnet or one ferromagnetic path comprised in complementary guide means 52.
In another embodiment, not illustrated by the Figures, also for removing friction, guide means 42 include at least one electrically charged or electrostatically conductive path, arranged to cooperate with at least one electrically charged or electrostatically conductive path comprised in complementary guide means 52.
The invention also concerns a timepiece movement 200 including such a regulating mechanism 100.
The invention also concerns a timepiece 300 including such a movement 200, and notably said timepiece 300 is a watch.
The invention has numerous advantages:
the invention avoids the jerky movements characteristic of a Swiss lever escapement and consequently losses due to shocks;
the invention proposes an innovation in the field of the escapement while respecting conventional watchmaking codes by maintaining sprung balances;
in the first variant, advantage can be taken of all the watchmaker's knowledge for using isochronous resonators.
| Number | Date | Country | Kind |
|---|---|---|---|
| 14184155 | Sep 2014 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2015/063892 | 6/22/2015 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2016/037717 | 3/17/2016 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 1232285 | Greeley | Jul 1917 | A |
| 7950846 | Hessler | May 2011 | B2 |
| 8002460 | Daout | Aug 2011 | B2 |
| 8770828 | Ching | Jul 2014 | B2 |
| 9465363 | Winkler | Oct 2016 | B2 |
| 20100002548 | Hessler | Jan 2010 | A1 |
| 20110222377 | Ching et al. | Sep 2011 | A1 |
| 20150131413 | Helfer | May 2015 | A1 |
| 20160231708 | Roth | Aug 2016 | A1 |
| Number | Date | Country |
|---|---|---|
| 2 141 555 | Jan 2010 | EP |
| 2 365 403 | Sep 2011 | EP |
| 2 431 823 | Mar 2012 | EP |
| 2 908 189 | Aug 2015 | EP |
| Entry |
|---|
| International Search Report dated Apr. 5, 2016 in PCT/EP2015/063892 filed Jun. 22, 2015. |
| Number | Date | Country | |
|---|---|---|---|
| 20170068216 A1 | Mar 2017 | US |
