Patent Application
20230205137
The invention relates to a method for the fine adjustment of the rate of a mechanical horological oscillator including at least one inertial mass arranged to oscillate about an axis of rotation and returned to a rest position by elastic return means.
The invention further relates to a mechanical horological oscillator suitable for the implementation of this method.
The invention further relates to a timepiece, particularly a watch, including such a mechanical horological oscillator.
The invention relates to the field of rate setting of a mechanical horological oscillator, and in particular of an oscillator already fitted into a watch head.
Modifying the frequency of a mechanical oscillator almost always involves a change of the rigidity of the elastic part, particularly a spring, or a change in the inertia/mass thereof. For example, in mechanical watch sprung balances, devices for adjusting the stiffness of the balance-spring are routinely found, such as the variation of the active length thereof by moving pins. A further method routinely used is inertia modification of the balance by moving small masses towards the outside or towards the inside of the balance, such as screws, or offset rotating inertia-blocks.
However, these operations require that the watch be opened and the movement removed, which tends to distort the result once the case is closed again, with a drift of up to 10 seconds per day, which is a nuisance for movements that need to be set from 0 to +2 seconds per day. Furthermore, these delicate mechanisms generally contribute to mechanical play causing drift, once the setting tool—the force used for setting—are removed.
The invention proposes to accurately adjust the frequency of a mechanical horological oscillator, for example a watch sprung balance, without having to dismantle the watch, or more generally the timepiece carrying this oscillator.
For this purpose, the invention relates to a method for the fine adjustment of the rate of a mechanical horological oscillator, according to claim 1.
The invention further relates to a mechanical horological oscillator suitable for the implementation of this method.
The invention further relates to a timepiece, particularly a watch, including such a mechanical horological oscillator.
The aims, advantages and features of the invention will become more apparent upon reading the following detailed description, and with reference to the appended drawings, wherein:
The invention proposes to induce permanent mechanical tension, and therefore a volume expansion, particularly by femtosecond laser excitation, in a flexible micromechanism machined in a glass (molten silica) or similar support.
The support is embedded on the inertial mass of the oscillator, particularly the balance, of a mechanical watch. The movement of a part of the mechanism will modify the inertia of this inertial mass, therefore the frequency of the oscillator, particularly of the sprung balance. Movements of the order of several micrometres can be obtained in such glass microstructures by writing parallel internal tension expansion lines, as seen in particular in the article “Non-contact sub-nanometre optical repositioning using femtosecond lasers”, by Y. Bellouard, in “Optics Express, 2 Nov. 2015, volume 23, No. 22”.
The microstructures per se are embodied thanks to a blanking method with a precision of +/−1 micrometre, and using the same type of laser, followed by chemical etching, as seen in the article cited above, or in the article “Fabrication of high-aspect ratio, micro-fluidic channels and tunnels using femtosecond laser pulses and chemical etching”, by Y. Bellouard et al., in “Optics Express, 2004, 12, pages 2120-2129”, or on the website of FEMTOprint SA, 6933 Muzzano (CH), on the page https://www.femtoprint.ch/devices-photos.
The absence of pivots or of any other frictional guidance ensures high positioning precision and zero hysteresis. The optical excitation is direct through a crystal or any non-absorbent casing separation for the wavelength of the laser, or out of focus at the passage point.
The invention is illustrated more specifically, and not restrictively, for the case where the oscillator is a watch oscillator, and is a sprung balance.
The invention relates to a method for the fine adjustment of the rate of a mechanical horological oscillator 100 including at least one inertial mass 1 arranged to oscillate about an axis of rotation D and returned to a rest position by elastic return means.
According to the invention, and as seen in
The description “writing zone 39” relates to the generic case, and the terms “first writing zone 391” and “second writing zone 392” relate to the preferred, but non-restrictive, application, on respectively a first arm 33, and a second arm 34 of the inertia-block 3.
More specifically, when an inertial mass 1, subjected to a rotation movement, extends on either side of the axis of rotation D, this inertial mass 1 is equipped with at least one pair of diametrically opposed actuators 35, in a material suitable for irreversible local micro-expansion under the action of laser fires. This is particularly the case when the inertial mass 1 is a balance of a sprung-balance type oscillator.
More specifically, when an inertial mass 1 is overhanging with respect to the axis of rotation D, like the inertial masses suspended by flexible strips, which are symmetrical with respect to a plane passing through the axis of rotation D, this inertial mass 1 is equipped with at least one pair of symmetrical actuators 35 with respect to this plane of symmetry.
More specifically, this method is applied to an oscillator 100 with at least two inertial masses 1 each including such an actuator 35.
In a second step 802, a first, particularly rough, setting of the initial rate of the oscillator 100 is performed in a first rate range and the rate is measured.
In a third step 803, the direction and the value of the rate deviation to be imparted to the oscillator 100 in order to bring it into a predetermined second rate range are calculated, and the direction and the value of the travel to be applied to each inertia-block 3 included in the oscillator 100 are calculated.
In a fourth step 804, at least one writing zone 39, 391, 392, is subjected to femtosecond laser fires to create at least one expansion line 390 by local molecular expansion of the material to deform the actuator 35 radially with respect to the axis of rotation D.
In a fifth step 805, the rate of the oscillator 100 is measured, and if required the third step 803 and the fourth step 804 are repeated until the rate of the oscillator 100 is within the predetermined second rate range.
More specifically, during the fourth step 804, a femtosecond laser source 700 is used, mounted on a table with crossing movements 710, or with radial travel, so as to increment different series of fires on different beams with respect to the axis of rotation D, to create a series of expansion lines 390 in the immediate vicinity of one another.
More specifically, during the fourth step 804, a femtosecond laser source 700 is used to perform fires in each direction of rotation of the inertial mass 1.
More specifically, during the fourth step 804, control means 790 are used to control the fires of the femtosecond laser source 700, according to the information in respect of the presence or absence of material provided by the combination of a detection laser 750 and a collection means 760 or a photodetector.
More specifically, during the second step 801, an actuator 35 is chosen including, on a first arm 33 a first writing zone 391, and on a second arm 34 parallel with the first arm 33 along a radial linear direction L and joining it at a common segment 334 a second writing zone 392. The actuator 35 is thus mounted in an “S” between, on one hand, a fastening zone 30 fastened to a support 2 mounted on the inertial mass 1 or directly fastened to the inertial mass 1, and, on the other, an exit point or a linking neck 32 for linking with an amplifying mechanism 36. The actuator 35 is arranged to act in two opposing directions along the linear direction L, whereby, during the fourth step 804, laser fire writing takes place in the first writing zone 391 on the first arm 33 for a gain setting, or in the second writing zone 392 on the second arm 34 for a loss setting.
More specifically, during the first step 801, an actuator 35 is chosen with an exit point or a linking neck 32 for linking with an amplifying mechanism 36 which is arranged to amplify the exit travel of the actuator 35, to impart an amplified travel to the inertia-block 3.
More specifically, this amplifier 36 is parallelogram type, and includes a connecting rod system with connecting rods 310 arranged between flexible necks 31 forming a linear guidance along a radial linear direction L.
More specifically, during the first step 801, an actuator 35 is chosen including a fastening zone 30 rigidly connected to a support 2 mounted on the inertial mass 1. And the support 2 forms a one-piece assembly forming a flexible micro-mechanism, with the actuator 35, and amplifier 36 and the inertia-block 3 mounted in series with each other.
More specifically, during the first step 801, an actuator 35 is chosen including a fastening zone 30 fastened to a support 2 mounted on the inertial mass 1 or rigidly connected to a support 2, and the actuator 35 and/or the support 2 is made of glass.
More specifically, during the first step 801, the inertial mass 1 is chosen in the form of a balance, which includes at least one pair of identical inertia-blocks 3 diametrically opposed with respect to the axis of rotation D.
More specifically, during the first step 801, the oscillator 100 is incorporated into a watch head 500 of a watch 1000, said watch head 500 including at least one transmissive transparent element 600, which separates the outside and inside of the watch 1000, and enables optical access for at least one laser to at least the inertial mass 1 of the oscillator 100 of the watch.
In a static alternative embodiment, during the first step 801, the oscillator 100 is equipped with stopping means or a stop-seconds means arranged to bear on an inertial mass 1, and the fourth step 804 is performed in a locked position of the inertial mass 1.
In a dynamic alternative embodiment, during the fourth step 804, femtosecond laser writing fires are performed during the oscillation of the inertial mass 1, wherein the angular position and fires are synchronised.
More specifically, during the fourth step 804, the fires are performed with a femtosecond laser, for example and non-restrictively of wavelength between 900 and 1100 nm, pulse time between 200 and 350 fs, pulse energy approximately between 200 and 300 nJ, repetition rate of 700 to 900 kHz. It is obvious that a different femtosecond laser (wavelength, pulse time and energy) can be used, provided that it can modify the material as described hereinabove.
The invention further relates to a mechanical horological oscillator 100 including at least one inertial mass 1 arranged to oscillate about an axis of rotation D and returned to a rest position by elastic return means, suitable for the implementation of this method. According to the invention, at least one inertial mass 1 includes an actuator 35 made of a material suitable for irreversible local micro-expansion under the action of laser fires. The actuator 35 is arranged to impart to an inertia-block 3 a radial linear travel with respect to the axis of rotation D, directly or by means of at least one travel amplifier 36, when a writing zone 39, 391, 392, included in the actuator 35 is subjected to suitable laser fires.
More specifically, the actuator 35 includes, on a first arm 33 a first writing zone 391, and on a second arm 34 parallel with the first arm 33 along a radial linear direction L and joining it at a common segment 334 a second writing zone 392, the actuator 35 thus being mounted in an “S” between, on one hand, a fastening 30 fastened to a support 2 mounted on the inertial mass 1 or directly fastened to the inertial mass 1, and, on the other, an exit point or a linking neck 32 for linking with an amplifying mechanism 36, the actuator 35 being arranged to act in two opposite directions along a linear direction L, whereby femtosecond laser fires are applied in the first writing zone 391 on the first arm 33 for a gain setting, or in the second writing zone 392 on the second arm 34 for a loss setting.
More specifically, the actuator 35 includes an exit point or a linking neck 32 for linking with an amplifying mechanism 36 arranged to amplify the exit travel of the actuator 35, to impart an amplified travel to the inertia-block 3. And the amplifier 36 is parallelogram type, and includes a connecting rod system with connecting rods 310 arranged between flexible necks 31 forming a linear guidance along a radial linear direction L.
More specifically, the actuator 35 includes a fastening zone 30 rigidly connected to a support 2 mounted on the inertial mass 1, and the support 2 forms a one-piece assembly forming a flexible micro-mechanism, with the actuator 35, and amplifier 36 and the inertia-block 3 mounted in series with each other.
More specifically, the actuator 35 includes a fastening zone 30 fastened to a support 2 mounted on the inertial mass 1 or rigidly connected to a support 2, and the actuator 35 and/or the support 2 is made of glass.
More specifically, the inertial mass 1 is a balance, which includes at least one pair of identical inertia-blocks 3 diametrically opposed with respect to the axis of rotation D.
The invention further relates to a timepiece, particularly a watch 1000, including at least one such mechanical horological oscillator 100. According to the invention, the watch 1000 includes a watch head 500 including at least one transmissive transparent element 600, which separates the outside and inside of the watch 1000, and enables optical access for at least one laser to at least the inertial mass 1 of the oscillator 100 of the watch.
The figures illustrate non-restrictive embodiments of the invention, in the specific case where the inertial mass 1 is a balance.
The invention proposes to precisely adjust, through an at least locally transparent or low optical absorption casing such as this transmissive transparent element 600, the frequency of a sprung balance by means of a focused laser beam. The oscillator 100 is, either already set roughly to +/−15 seconds per day, for example using screws not shown, or specifically paired with a suitable balance-spring in this range. The action of the laser enables the fine setting to around 0-2 seconds per day, through the movement of small inertia-blocks towards the outside or towards the inside of the balance 1, thus modifying the inertia thereof, and therefore modifying the frequency of the oscillator, and thus enabling the precise adjustment of the rate of the watch.
The figures illustrate specific alternative embodiments where each support 2 is mounted on the balance 1, for convenience of execution; another alternative embodiment where the supports 2 and the balance 1 form a one-piece assembly is possible, although more costly to produce.
The movement amplitude is dependent on several laser exposure parameters. This amplitude can be controlled very precisely, and the inertia-blocks 3 remain in place after an exposure, and it is possible to move the inertia-blocks 3 in both directions over a fixed number of cycles. So as not to disrupt the unbalance, it is necessary to group the supports 2 in diametrically opposed pairs, and it is necessary to set them simultaneously on the same amplitude.
For the specific simple case of two diametrically opposed supports 2, illustrated by the figures, the relationship between the rate deviation (deviation with respect to the ideal frequency) of the oscillator 100, in seconds per day, and the radial movement X of two inertia-blocks 3, in metres, is given by the following equation:
rate deviation ΔM=86400*x*(2R+x)/(R2+Io/2m),
The graph in
For example, curve C2, relating to inertia-blocks 3 with a mass of 1.6 mg, corresponds to the movement by +/−10 micrometres of a glass parallelepiped measuring 0.30×1.33×1.70 mm3, on either side of the zero position thereof. The frequency adjustment obtained is here +/−11 seconds per day. This range can be easily extended, either by increasing the mass of the inertia-blocks, or by increasing the peak-peak travel. An alternative embodiment particularly consists of embedding, on this glass plate, an additional mass, made of metal or any other ad hoc material.
The choice of the opto-mechanical actuator is essential to obtain a reproducible and precise result. The publication mentioned above “Non-contact sub-nanometer optical repositioning using femtosecond lasers”, by Y. Bellouard, in “Optics Express, 2 Nov. 2015, volume 23, No. 22” describes an ultra-high-precision positioning device, capable of serving to align optical fibre axes, which requires positioning within a few nanometres. It consists of a demonstrator made of a glass wafer, of a thickness of approximately 500 micrometres routinely used in packaging and in microfluidics applications.
A further alternative embodiment, seen in
Similarly, it can furthermore be envisaged that the inertia-blocks 3, the supports 2, and the balance 1, form a one-piece assembly, although this alternative embodiment is even more costly to produce.
According to the invention, this first arm 33 and this second arm 34 are intended to receive laser pulses, and include writing zones respectively 391, 392, at which very brief bursts of laser pulses, emitted by the laser source 700, will create, in the thickness of the material, a local modification of the structure thereof by molecular expansion, this expansion being rapidly stopped by stopping the pulses, and the deformation hence remaining a permanent deformation. These core deformations are infinitesimal, and hence the method consists of locally juxtaposing a large quantity of zones expanded thus, to achieve a sufficient cumulative expansion to move the inertia-block 3 sufficiently along a linear direction L. Advantageously, a mechanical amplifier 36, for example a parallelogram type mechanism with four necks as seen in
It is understood that the movement is different, depending on whether the laser pulses etches the first arm 33 or the second arm 34:
The action of the laser does not cause blanking, or even surface etching, the aim is a molecular reorganisation at the core of the material, in the thickness thereof. The concept of writing expansion lines is a paraphrase to describe the application of series of pulses according to a grid wherein the projection of the trajectories on the plane of the inertia-block is presented as a series of very close parallel expansion lines, or very pointed zig-zag expansion lines, or other; the aim is indeed that of expanding the core material, and of cumulating more close expansions along the same linear direction L.
By writing expansion lines in the volume of the material at writing zones 39, particularly first writing zone 391, second writing zone 392, this material expands following the action of these zones subject to compressive stress. This state results from isolated heating that is very intense, but brief enough so as not to liquefy the material. There is merely a very slight expansion of the volume, the material remaining solid. This isolated heating is performed with a burst of very brief pulses of a femtosecond laser, for example that which is described, but not restricted to, by the article mentioned above “Non-contact sub-nanometer optical repositioning using femtosecond lasers”, by Y. Bellouard, in “Optics Express, 2 Nov. 2015, volume 23, No. 22” (Yb-fiber amplified laser, from Amplitude systèmes SA, wavelength=1030 nm, pulse time 270 fs, pulse energy approximately 250 nJ, repetition rate 800 kHz). The beam is focused through a lens at a spot of a few micrometres, at a working distance of the order of 6 mm. A three-dimensional scan with a precision of within a few micrometres of these pulses thus makes it possible to define one or more volume zones under stress. It is obvious that a different femtosecond laser (wavelength, pulse time, energy and repetition rate) can be used provided that it can modify the material as described hereinabove. The working distance of the focusing lens can be varied according to the laser beam shaping and focusing optics.
The non-restrictive mechanism of
According to the invention of the article mentioned above (Y. Bellouard, 2015), for blocks of 200 parallel planes written in a volume of overall length of approximately 1 mm along the linear direction L, the following are obtained, with the laser parameters above and according to the figures: a multiplication factor Km of 6, an amplified travel of the inertia-block 3 of approximately 5 micrometres, for 200 expansion lines written over a length of 1 mm; the proper movement at the actuator 35, along the linear direction L, therefore equals, per written line: 5/(200*6)=4.167 nm/line (or plane).
The same technique can be used for blanking the microstructure per se, according to the articles cited above. A first step consists of writing, according to the same method of core expansion under the action of a laser, volume zones to be removed in a glass plate (molten silica). In a second step, the plate is subjected to chemical etching, which selectively removes the parts under stress. The machining obtained is also precise to the micrometre, and makes it possible to produce glass microstructures.
The mechanism schematically represented in
As illustrated in
The distance between the middle of two deflection necks 31 delimiting a connecting rod 310 is, in this example, 1.40 mm, and the distance between the middle of the lower deflection neck 31 and the linking neck 32 is 0.14 mm. These deflection 31 or linking 32 necks have a width of 20 micrometres here, which is acceptable from a technological point of view. The multiplication factor Km between the travel of the actuator, and that of the mass equals, by virtue of the lever arm ratio: Km=1.400 mm/0.140 mm=10
The maximum linear amplitude of the structure equals: +/−x=Km*200 expansion lines*4.167 nm/line=2000*4.167 nm=+/−8.33 micrometres, which corresponds, via the graph C2, to approximately +/−Δrate=+/−9 seconds per day.
The resolution of the setting per written line and considering 200 expansion lines for each of the two ranges of 9 seconds per day therefore equals d_rate (1 line)=9/200=0.045 seconds per day and per line, which is ample to adjust a rate within a range of 0-2 seconds per day.
It is noted that two zones 1 mm in length along the linear direction L enable a single gain correction of +9 seconds per day and a loss correction of −9 seconds per day. In order to have several writing cycles, it is possible, either to increase the number of supports 2, or to increase the mass, which has the effect of having to write fewer expansion lines for the same movement, and therefore reserve space on the first arm 33 and on the second arm 34 for subsequent writings.
With respect to the implementation of the rate adjustment, an initial state is considered where, before correction, the rate of the watch is assumed to be known and measured, with the case closed. To perform the correction, a specific fitting is used to position the watch head precisely. A microscopic objective and a positioning stage with crossing movements xy then enables the centring of the laser source 700, particularly a femtosecond layer, on the balance 1.
From this stage, two options arise: either the balance is stopped by a locking/braking lever, such as a stop-seconds or similar means, or a mechanism for stopping and spatially holding the oscillator, and the laser fire is performed on an immobile target, or the balance 1 continues to oscillate, and the laser fire must then be synchronised with the angular position thereof.
The case in which the balance is stopped, and the laser fire performed on an immobile target, can be resolved with a semi-automatic positioning for example and non-restrictively with control means managing a camera with image recognition software which is centred on the axis of rotation D of the balance.
In the case in which the balance 1 oscillates, and in which the laser fire is synchronised with the angular position thereof, the method is more complex, but more advantageous as the setting is performed on the fly, without needing to stop the balance. The fire can be started with the start of the passage of the support 2 through a detection laser beam 750, as illustrated in
In
When the balance 1 oscillates, the angular velocity OME thereof is maximum in the vicinity of the neutral point, either between the times t1 and t4 of the top graph in
The signal VPD of the photodetector 760 associated with the detection laser 750 has the value 1 when the spot thereof is on a solid zone of the chip 2, i.e. successively fastening zone 30/first lower arm 33/second upper arm 34/inertia-block 3, as seen both in the middle graph of
The (passage) writing duration Te in the first gain zone on the first arm 33, or in the second loss zone on the second arm 34, which is a zone of length Le, is given by:
In this example, Le=190 um, R=4 mm, A=270°, F=4 Hz, hence Te=0.40 ms.
The repetition frequency of the writing pulses being 800 kHz in this example, the number of pulses per passage therefore equals 800*0.40=320, and therefore the maximum (cumulative) gain error equals: 1/320*(+/−9 seconds per day)=+/−0.03 seconds per day, which is perfectly satisfactory for the application.
The femtosecond laser and chemical etching glass machining technique, which makes it possible to produce three-dimensional structures with a precision to the micrometre, is a tried-and-tested technique.
This technique makes it possible to produce 2 millimetric chips with flexible elements which can be moved over micrometric amplitudes, with nanometric precisions. The actuation of the nano-movement of the actuator part 35 is performed by laser internal stress writing. A system of flexible necks 31 and connecting rods 310 makes it possible to increase the amplitudes along the linear direction L.
The embodiment of such a chip 2 is adapted to the precise and reliable setting of the rate of a sprung balance, with a precision of 0.03 seconds per day, and a resolution of 0.09 seconds per day, in a range of typically +/−10 seconds per day. Obviously, the range amplitude and the resolution can be easily varied by adapting the design.
It can be noted that the invention offers the possibility of performing an infinitesimal and irreversible expansion, which, in theory, could enable, through a series of fires on the elastic return element of the oscillator, such as a spiral spring, flexible strip or similar, to modify the stiffness thereof; however, the creation of these deformed zones impedes the homogeneity of the component, and the risk is an impairment of the elastic properties of this elastic return element. For this reason, the invention is presented here preferably for an action on the inertial element, regardless of whether it is suspended by a spiral spring, or by elastic strips.
The setting system is compact and does not require additional complications in the watch 1000, other than mounting two or more glass chips 2 on the balance 1.
This setting can be performed directly on a complete watch 1000, provided that the watch head 500 includes a transmissive transparent element 600, such as a back, a crystal, or other, which is transparent or non-absorbent for the writing laser in optical access on the oscillator. The invention naturally relates to a watch 1000 thus equipped.
The external part of the setting (fitting, microscope, optics and lasers) typically occupies the volume of a desk, which enables quick and user-friendly setting, both in production and in-store for customer service.
The implementation of the invention is all the more superior given that the absorption of the ray is optimised by the physical protection separation (case, casing), given that a reliable system for positioning the laser spot is embodied. Naturally, adapted dimensioning should be adopted for live zones, above certain experimentally determined dimensions, to prevent increased fragility of these live zones, which could cause a premature rupture during shocks.
| Number | Date | Country | Kind |
|---|---|---|---|
| 21217879.2 | Dec 2021 | EP | regional |
