The present application is a national stage entry of International Application No. PCT/EP2019/069949, filed Jul. 24, 2019, which claims priority to European Patent Application No. 18186552.8, filed on Jul. 31, 2018, and European Patent Application No. 19185917.2, filed on Jul. 12, 2019, the entire content and disclosure of all of the above application is incorporated by reference herein.
The invention relates to a variable-geometry timepiece display mechanism, comprising at least one resilient hand, which comprises a first drive pipe integral with a first end of a flexible strip, and a second drive pipe integral with another end of said flexible strip, and which comprises a display index or tip which, in an unstressed free state of said resilient hand wherein both said first pipe and said second pipe are not subjected to any stress and are remote from one another, is remote from said first pipe and from said second pipe, the operating position of said resilient hand being a stressed position where said first pipe and said second pipe are coaxial to one another about an output axis, said display mechanism comprising first means for driving said first pipe about said output axis, and second means for driving said second pipe about said output axis, said first drive means and second drive means being arranged so as to deform said flexible strip, by varying the angular position of said second pipe relative to the angular position of said first pipe about said output axis, and so as to vary the radial position of said display index or tip relative to said output axis.
The invention further relates to a horological movement comprising at least one such display mechanism.
The invention further relates to a timepiece comprising at least one such horological movement, and/or comprising at least one such display mechanism.
The invention further relates to a scientific apparatus comprising at least one such horological movement, and/or at least one such display mechanism.
The invention relates to the field of analogue display mechanisms using moving mechanical components, for timepieces or scientific apparatuses.
Patent documents EP2863274 and EP3159751 filed by MONTRES BREGUET SA disclose different arrangements of resilient hands, allowing a display on a timepiece to be adapted to the shape of the case or dial thereof, thanks to a radial extension obtained by controlling such a resilient hand which comprises flexible segments driven separately.
The invention proposes a reliable and extremely robust solution to the problem of providing an indicator having variable radial extension according to the position and control thereof.
For this purpose, the invention relates to a timepiece display mechanism comprising at least one such resilient hand, which comprises a first drive pipe integral with at least one flexible strip, according to claim 1.
The invention further relates to a horological movement comprising at least one such display mechanism.
The invention further relates to a timepiece comprising at least one such horological movement, and/or comprising at least one such display mechanism.
The invention further relates to a scientific apparatus comprising at least one such horological movement, and/or at least one such display mechanism.
Other features and advantages of the invention will be better understood upon reading the following detailed description given with reference to the accompanying drawings, in which:
The invention relates to a display indicator for a timepiece or for a scientific apparatus.
Patent documents EP2863274 and EP3159751 filed by MONTRES BREGUET SA disclose a timepiece display using a resilient hand, and the features thereof can be directly used to produce a display mechanism according to the present invention.
The invention is described here in the particular, but non-limiting case of a rotating indicator, and particularly a resilient hand. However, the principle is applicable to an indicator having a non-circular trajectory of mobility, for example with a linear cursor, or suchlike, particularly in space. The invention is more precisely described for this application of a flexible indicator to a hand, but it is applicable to other planar or three-dimensional indicator shapes.
Similarly, drive means comprising gear trains are described hereinbelow, but the invention is equally applicable to analogue display means for an electronic or electrical apparatus, a quartz watch or other device.
The principle of the invention is to produce a display mechanism, wherein at least one indicator, particularly a hand, for example the minute hand for a watch, has a variable length, or a variable radial extension, or a variable shape.
The invention further relates to a variable-geometry timepiece display mechanism 10 that comprises at least one resilient hand 1. This resilient hand 1 comprises a first drive pipe 2 integral with at least one one-piece flexible strip 3, and with a single flexible strip 3 in the specific, non-limiting case shown in the figures.
The display mechanism 10 comprises an input wheel set 71, which is arranged so as to be driven such that it pivots about an input axis by a movement 20, and which defines an input angle relative to a reference direction.
The resilient hand 1 comprises a first drive pipe 2 integral with a first end of a flexible strip 3, and a second drive pipe 4 integral with another end of this flexible strip 3, and the resilient hand 1 comprises a display index or tip which, in an unstressed free state of this resilient hand 1 wherein both the first pipe 2 and the second pipe 4 are not subjected to any stress and are remote from one another, is remote from the first pipe 2 and from the second pipe 4. The operating position of this resilient hand 1 is a stressed position where the first pipe 2 and the second pipe 4 are coaxial to one another about an output axis D.
The display mechanism 10 comprises first means 11 for driving the first pipe 2 about the output axis D, and second means 13 for driving the second pipe 4 about this output axis D.
These first drive means 11 and second drive means 13 are arranged so as to deform the flexible strip 3, by varying the angular position of the second pipe 4 relative to the angular position of the first pipe 2 about the output axis D, and so as to vary the radial position of the display index or tip relative to the output axis D.
In one specific embodiment, the resilient hand 1, and more particularly the flexible strip 3 thereof, comprises a plurality of flexible segments 5, 5A, 5B that are joined end-to-end at at least one tip 6, arranged so as to form such an index, and preferably two successive flexible segments are joined by such a tip.
In the case shown in the figures, a first flexible segment 5A of the flexible strip 3 extends between the first pipe 2 and a first tip 6.
More particularly, the invention is shown in the most common case whereby the hand comprises two flexible segments 5 joined by a single tip 6, which is used for the display.
The display mechanism 10 comprises first means 11 for driving the first pipe 2 about an output axis D, and comprises second means 12 for stressing at least the first flexible segment 5: these second means 12 are arranged so as to vary the position of at least the first tip 6 relative to the output axis D. The first tip 6 is thus at a variable distance from the first pipe 2, as a function of the forces applied to the flexible strip 3 by the second stressing means 12.
More particularly, the first drive means 11 and/or the second stressing means 12, and in particular the second drive means 13 comprised therein, comprise a first shaped gear train 111 and/or respectively a second shaped gear train 131, which is arranged or which are arranged so as to accelerate or stabilise the speed of, or slow at least the first pipe 2, and/or the second pipe 4, over a part of the angular travel thereof.
More particularly, the first drive means 11 and the second stressing means 12, and in particular the second drive means 13 comprised therein, comprise at least one first shaped gear train 111 and respectively at least one second shaped gear train 131, which are arranged so as to accelerate or stabilise the speed of, or slow the first pipe 2, and respectively the second pipe 4, over at least part of the angular travel of the first pipe 2, and respectively of the second pipe 4.
In one specific embodiment, shown in
More particularly, and as disclosed in the patent documents EP2863274 and EP3159751, the resilient hand 1 comprises a second drive pipe 4 also integral with the flexible strip 3. The second stressing means 12 thus comprise second drive means 13 of the second pipe 4 in an assembled and stressed state of the resilient hand 1. In this assembled state of the resilient hand, both the first pipe 2 is, advantageously but not necessarily in a prestressed operating state, driven by the first drive means 11, and the second pipe 4 is, advantageously but not necessarily in a prestressed operating state, driven by the second drive means 13. Additionally, at least one of the tips 6 is, in a non-stressed free state of the resilient hand 1 in which both the first pipe 2 and the second pipe 4 are not subjected to any stress, remote from the first pipe 2 and from the second pipe 4, which first pipe 2 and second pipe 4 are spaced apart from one another in this free state of the resilient hand 1.
In the specific case shown in the figures wherein the flexible strip 3 only comprises one first flexible segment 5A and one second flexible segment 5B, only one such tip 6 joining them is present. Thus, more particularly, this first flexible segment 5A bears the first pipe 2 at a first end 52, and this second flexible segment 5B joined to the first flexible segment 5A bears the second pipe 4 at a second end 54. Moreover, in the free state of the resilient hand 1, the first end 52 and the second end 54 are remote from one another, or form a non-zero angle with one another from the tip 6 at which the first flexible segment 5A and the second flexible segment 5B are joined.
More particularly, the output of the second drive means 13 of the second pipe 4 is coaxial to the output of the first drive means 11 of the first pipe 2 in the assembled state of the resilient hand 1. However, this arrangement is not compulsory, in particular in the case of a retrograde display, where the axes of the first pipe 2 and of the second pipe 4 can be different.
According to the invention, the first drive means 11 and the second drive means 13 comprise an accelerator or decelerator device, which is arranged such that it accelerates, or stabilises the speed of, or slows down at least the first pipe 2 and/or said second pipe 4 over at least part of the angular travel thereof.
In one alternative embodiment, the first pipe 2 is advanced or delayed relative to the value of the input angle, which is symmetric to the delay or advance of the second pipe 4 relative to the input angle, such that the first tip 6 always displays, relative to the output axis D and the reference, an angle that is equal to the input angle.
In another alternative embodiment, the first pipe 2 is advanced or delayed relative to the value of the input angle, which is, as an absolute value, different to the delay or advance of the second pipe 4 relative to the input angle, such that the first tip 6 displays, relative to the output axis D and the reference, an angle that is variable relative to the input angle throughout the length of the travel thereof. This particular advance and/or delay arrangement relative to the input pipe allows the hand to point to the time (or another display) only on the dial, and in particular for a non-regular display, for example a square trajectory where the time is divided into twelve equally-spaced segments over the square trajectory, which cannot be managed in the same manner as twelve indexes separated by 30°.
In yet another alternative embodiment, the hand 1 is arranged such that it travels a total non-retrograde path and, over the total path, the average speed of the first pipe 2 is equal to the average speed of said second pipe 4.
Numerous configurations can be considered:
In one specific embodiment which will be described in detail hereinbelow, the accelerator or decelerator device comprises a first shaped gear train 111 and/or respectively a second shaped gear train 131.
According to the invention, and as shown in
In yet another embodiment, the accelerator or decelerator device comprises single gear trains suitably arranged so as to perform the required accelerations or decelerations.
More particularly, and as shown in
respectively, at least one first shaped gear train 111 and at least one second shaped gear train 131, which are each arranged or which are arranged so as to accelerate, or stabilise the speed of, or slow the first pipe 2 and respectively the second pipe 4 over a part of the angular travel thereof. The term “shaped gear train” is understood herein to mean that at least one wheel of the gear train is not axisymmetric; more particularly, at least two counteracting wheels of this gear train are not axisymmetric, and are arranged so as to permanently gear with one another with minimal clearance and a constant centre-to-centre distance.
More particularly, the first shaped gear train 111 and the second shaped gear train 131 are arranged so as to accelerate or respectively brake the first pipe 2, and to brake or respectively accelerate the second pipe 4 over at least part of the angular travel of the resilient hand 1, or over only part of the angular travel of the resilient hand 1. In other words, one of the pipes procures an angular advance relative to the input angle, whereas the other pipe procures an angular delay relative to the input angle.
Thus, in one specific embodiment of the invention, the first pipe 2 is advanced or delayed relative to the value of said input angle, which is symmetric to the delay or advance of the second pipe 4 relative to the same input angle, such that the first tip 6 always displays, relative to the output axis D and the reference direction, an angle that is equal to the input angle.
Thus, considering the embodiment according to
The invention is shown in the figures for the specific case of a continuous horological display showing a full revolution; it is understood that the invention can be applied to any display, in particular a retrograde display.
More particularly, the first shaped gear train 111 and the second shaped gear train 131 are arranged such that they symmetrically control the first pipe 2 and the second pipe 4, such that the first flexible segment 5A and the second flexible segment 5B are symmetrical relative to a radial originating from the output axis D and passing by way of the tip 6 at which the first flexible segment 5A and the second flexible segment 5B are joined, over at least part of the angular travel of the resilient hand 1. This configuration is not limiting, however it has the advantage of subjecting the first flexible segment 5A and the second flexible segment 5B to symmetric stresses.
More particularly, the first shaped gear train 111 and the second shaped gear train 131 each comprise at least one pair of wheels arranged such that they engage by gearing with one another and whose geometric supports, i.e. the primitive curves, of the toothings are not axisymmetric.
Also more particularly, the first drive means 11 and/or the second drive means 13 comprise at least one first gear train stage 115, 135, and one second gear train stage 116, 136, which are arranged such that each controls a part of the shape transformation of the resilient hand 1 over at least part of the angular travel thereof, with distribution per stage. This distribution allows a part of the deformation to be distributed over each of the stages, which conserves, in each shaped gear train, wheels whose geometry is close to a circular geometry, so as to allow for suitable gearing of the toothings and prevent the wear thereof. More specifically, the shaped gear trains are not circular, however must not be excessively deformed, i.e. the shape thereof must allow for the gearing thereof without arcing, and without too high sensitivity to variations in the centre-to-centre distance and manufacturing tolerances. This can thus prevent interference defects that cut teeth would create if the primitive curves of the toothings deviated too far from the circular shape. A compromise must thus be found between a shape that is sufficiently non-circular so as to actuate the hand, and a shape that is resistant to wear. Distribution over a plurality of stages allows these conditions to be met: each stage takes part in the deformation of the hand, however the primitive curves thereof remain close to a circular shape; this is referred to as distribution per stage, whereby the overall cumulation of these staged gear trains procures the desired deformation of the hand.
The figures show a non-limiting alternative embodiment having two gear train stages, however this number of two is not limiting, and the number of stages is only limited by the overall thickness of the movement and the efficiency loss due to friction.
More particularly, both the first gear train stage 115, 135 and the second gear train stage 116, 136 respectively comprise a first shaped gear train 111 and a second shaped gear train 131.
It should be noted that the entire gear train is tensioned as a result of the play compensation of the resilient hand due to the prestressing thereof.
This driving cannon-pinion 72 is axisymmetric, and drives a first shaped wheel 78, which gears with a second complementary shaped wheel 79 mounted such that it idles (with play compensation) about the first axis DA, and which is pivotably integral with a third shaped wheel 80, which gears with a fourth complementary shaped idler wheel 81, which in this case pivots about the output axis D of the pipes, and which comprises a cannon-pinion 82 for attaching the first pipe 2.
The same driving cannon-pinion 72 drives a fifth shaped wheel 73, which gears with a sixth complementary shaped wheel 74 mounted such that it idles about the second axis DB, and which is pivotably integral with a seventh shaped wheel 75, which gears with an eighth complementary shaped idler wheel 76, which in this case pivots about the output axis D of the pipes, and is integral with a shaft 77 on which the second pipe 4 is attached.
Each shaped wheel comprises an angular marking so as to correctly ensure indexing of the shaped gear train, as shown in
The driving cannon-pinion 72 further drives a ninth wheel 91 comprised in a wheel set pivoting about an hour axis DH, which comprises a pinion 92 driving the wheel 93 of an hour cannon-pinion 94 receiving the hour hand 100.
The case of a construction with radial symmetry of movement between the two flexible segments of the same hand 1 uses two similar sets of identical shaped gear trains, one mounted the right way up, the other upside down.
The wheel in
The resilient hand 1 can be produced in a variety of different ways.
In an alternative embodiment, in the free state, the resilient hand 1 extends over a single planar level comprising the first pipe 2 and the second pipe 4, and the resilient hand 1 is thus arranged such that it is mounted in a twisted manner in a stressed operating position wherein the first pipe 2 and the second pipe 4 are superimposed on one another.
In an alternative embodiment, in the free state, the resilient hand 1 extends over a first planar level comprising the first pipe 2 and over a second planar level comprising the second pipe 4, and comprises a connecting area between the first planar level and the second planar level at a tip 6 between a first flexible segment 5A bearing the first pipe 2 and a second flexible segment 5B joined to the first flexible segment 5A and bearing the second pipe 4, and the resilient hand 1 is arranged such that it is mounted in a non-twisted manner in a stressed operating position wherein the first pipe 2 and the second pipe 4 are superimposed on one another. In another specific alternative embodiment, when the resilient hand 1 comprises more than two flexible segments 5, in the free state, the resilient hand 1 extends over, at most, as many parallel levels as there are flexible segments 5, and is arranged such that it is mounted in a non-twisted manner in a stressed operating position wherein the first pipe 2 and the second pipe 4 are superimposed on one another.
In a specific alternative embodiment intended to facilitate assembly, as shown in
Advantageously, the hand 1 is made from a material that can be micro-machined according to a “LIGA” method, and is in particular made of nickel-phosphorus NiP12 or similar material. Such a hand can be gold-plated, or can receive any other colouring, the adherence whereof is satisfactory on such a material. The hand 1 can be coloured using different methods: PVD, CVD, ALD, electrodepositing, painting, lacquering, or other coating or ionisation.
The hand 1 can comprise jewel setting or similar, and/or decoration by engine-turning, engraving, angling or enamelling, the latter being reserved to areas of low deformation such as the circumference of the pipes, an eye circumference, the tip or similar areas.
More particularly, the mechanism 10 forms an additional module, which is arranged so as to be connected to a horological movement 20, and the first drive means 11 and the second stressing means 12 comprise a common input 71, which is arranged so as to be driven by a single output 21 comprised in the movement 20, such as the cannon-pinion that rotates in one hour, or the minutes wheel set.
In an alternative embodiment, in addition to or in place of the shaped gear trains, the mechanism 10 comprises, between on the one hand the input wheel set 71 arranged so as to be driven by the movement 20, and on the other hand the first pipe 2 and/or the second pipe 4, at at least one stage, a cam 902, 904. This cam is arranged such that it controls a differential gear 912, 914, a first input whereof is formed by the input wheel set 71, a second input whereof is a wheel set, in particular a rack, controlled by this cam 902, 904, and the output whereof gears with the gear train for transmitting the movement to the first pipe 2 or respectively to the second pipe 4.
In a first application of this alternative embodiment, the mechanism 10 comprises, between the input wheel set 71 and the first pipe 2, at the level of at least one stage, a single cam 902 arranged such that it controls a first differential gear 912, a first input whereof is formed by the input wheel set 71, a second input whereof is a first wheel set or a first rack controlled by the cam 902, and the output whereof gears with the gear train for transmitting the movement to the first pipe 2, and between the input wheel set 71 and the second pipe 4, the same single cam 902 arranged such that it controls a second differential gear 914, a first input whereof is formed by the input wheel set 71, a second input whereof is a second wheel set or a second rack controlled by the cam 902, and the output whereof gears with the gear train for transmitting the movement to the second pipe 4.
In a second application of this alternative embodiment, the mechanism 10 comprises, between the input wheel set 71 and the first pipe 2, at the level of at least one stage, a first cam 902 arranged such that it controls a first differential gear 912, a first input whereof is formed by the input wheel set 71, a second input whereof is a first wheel set or first rack controlled by the first cam 902, and the output whereof gears with the gear train for transmitting the movement to the first pipe 2; and, between the input wheel set 71 and the second pipe 4, a second cam 904 driven by the input wheel set and arranged such that it controls a second differential gear 914, a first input whereof is formed by the input wheel set 71, a second input whereof is a second wheel set or a second rack controlled by the second cam 904, and the output whereof gears with the gear train for transmitting the movement to the second pipe 4.
The use of a cam allows for highly non-circular trajectories, additionally with jumps of the hand. The use of a single cam for both differential gears allows a simultaneous jump of the two pipes to be performed, for example at midnight; the first differential gear adds the information of the cam for the first pipe, and the second differential gear subtracts the information for the second pipe.
In another specific alternative embodiment, at least one wheel comprised in the gear train mechanism arranged between, on the one hand, the input wheel set 71 arranged such that it is driven by a movement 20 and, on the other hand, the first pipe 2 and/or the second pipe 4, at the level of at least one stage, comprises an incomplete toothing, each missing tooth allowing the resilient hand 1 to relax, by rotation of only one of the pipes 2, 4, during the passage of the space corresponding to a missing tooth, or to the missing teeth, so as to control a recoil of the tip 6 of the resilient hand 1.
In particular, a gear train can be used, comprising one or more, or even all circular wheels, at least one circular wheel whereof is devoid of one or more teeth in order to allow the hand to relax, and to perform a jump at the end of the so-called spiral display travel carried out by the tip 6 of the hand 1. If, for example, the first pipe rotates faster than the second pipe, and if the driving cannon-pinion 72 is locally devoid of teeth, the hand tends to contract, for example over two revolutions and, when the missing teeth release the first pipe, the hand becomes taught but the second pipe does not move, and the tip of the hand recoils. The advantage of such an alternative embodiment is to allow for the conventional machining of the wheels.
By way of comparison, the induced perturbation to operation is less than that caused by a change in date at midnight for a date mechanism.
The invention is shown in the figures with a simple shape, however it can be declined with very different hand shapes. For example, an asymmetrical hand composed of two V shapes interlocking with one another and having the same direction, each arm of each V shape being integral with one of the pipes, and the extremal end of the other arm being linked to the similar end of the other V shape. Alternatively, it can be a two-armed hand with two segments joining a first tip and attached to the two pipes, and two other segments joining a second tip remote from the first, and attached to the same pipes. Alternatively, it can be a hand comprising thickened areas over a median area of the flexible segments, for improved viewing of the hand.
The invention further relates to a horological movement 20 comprising at least one such display mechanism 10.
The invention further relates to a timepiece 30 comprising at least one horological movement 20 and/or comprising at least one such display mechanism 10. More particularly, 21 this timepiece 30 is a watch.
The invention further relates to a scientific apparatus comprising at least one horological movement 20 and/or comprising at least one such display mechanism 10.
Number | Date | Country | Kind |
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18186552 | Jul 2018 | EP | regional |
19185917 | Jul 2019 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/069949 | 7/24/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/025424 | 2/6/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4671670 | Kröner | Jun 1987 | A |
7136327 | Hopkins | Nov 2006 | B2 |
20150109891 | Stranczl | Apr 2015 | A1 |
20170242400 | Denden | Aug 2017 | A1 |
Number | Date | Country |
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201576169 | Sep 2010 | CN |
0 211 285 | Feb 1987 | EP |
1 710 637 | Oct 2006 | EP |
2 863 274 | Apr 2015 | EP |
Entry |
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International Search Report dated Nov. 5, 2019 in PCT/EP2019/069949 filed on Jul. 24, 2019, 2 pages. |
Number | Date | Country | |
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20210026305 A1 | Jan 2021 | US |