CH715211B1 - Variable geometry clockwork display mechanism with elastic hand. - Google Patents

Abstract

The invention relates to a timepiece display mechanism (1) with variable geometry, comprising an elastic hand (1) with a drive barrel (2) integral with a one-piece flexible blade (3) comprising flexible segments ( 5A; 5B) contiguous at vertices (6), of which a first flexible segment (5A) extends between the first barrel (2) and a first vertex (6), and on the other hand a second drive barrel (4) also attached to the flexible blade (3). The display mechanism (1) also comprises first drive means (11) for pivoting the first barrel (2) around an output axis (D), and second means for placing under stress (12) comprising second drive means (13) of the second barrel (4) to vary the position of the first vertex (6) with respect to the output axis (D). The first drive means (11) and/or the second stressing means (12) comprise an accelerator or retarder device, which is arranged to accelerate or stabilize in speed or slow down at least the first barrel (2) and/ or the second barrel (4) over at least part of its angular stroke.

Description

Field of the invention

[0001] The invention relates to a timepiece display mechanism with variable geometry, comprising at least one elastic needle which comprises a first drive bush integral with a one-piece flexible blade and which comprises a plurality of flexible segments adjoining end end at the level of at least one vertex, of which a first flexible segment extends between said first barrel and a first vertex, said display mechanism comprising first means for driving said first barrel around an output axis , and second means for stressing at least said first flexible segment which are arranged to vary the position of at least said first vertex with respect to said exit axis, said first vertex being at a variable distance from said first barrel depending on the forces applied to said flexible strip by said second stressing means.

The invention relates to the field of analog display mechanisms by moving mechanical components, for timepieces or scientific apparatus.

Background of the invention

[0003] The documents EP2863274 and EP3159751 in the name of MONTRES BREGUET SA describe different arrangements of elastic hands, allowing the adaptation of a display on a timepiece to the shape of its case or its dial, thanks to a radial extension obtained by piloting such an elastic needle comprising distinctly driven flexible segments.

Summary of the invention

The invention proposes to provide a reliable and robust solution to the problem of providing a variable radial extension indicator according to its position and its control.

[0005] To this end, the invention relates to a timepiece display mechanism comprising at least one such elastic hand, which comprises a first drive bush integral with at least one flexible blade, according to claim 1.

Brief description of the drawings

Other characteristics and advantages of the invention will appear on reading the detailed description which follows, with reference to the appended drawings, where: FIG. 1 represents, schematically and in plan view, a watch, in particular an oval-shaped ladies' watch, comprising a display mechanism according to the invention, comprising an elastic hand of variable length, the end of which distal, which is formed by a vertex between two flexible blades, is arranged to follow a non-circular trajectory; this elastic hand is represented in a position at twelve o'clock, in which the elastic hand has an almond shape, and where the top is in its position farthest from an output axis; FIG. 2 represents, similarly to FIG. 1, the same watch, in a six o'clock position of the elastic hand which then has a heart shape, and where the top is in its position closest to a output axis; figure 3 represents, similarly to figure 1, the same watch, in the same position and in the almond shape of the elastic needle, this view shows a trajectory of the top which, with respect to the exit axis , is in elongation over an angle of 120° from eight o'clock to twelve o'clock, and in shortening over another angle of 120° from twelve o'clock to four o'clock; this same trajectory is substantially circular with respect to an eccentric circular axis, over an angle of approximately 240°, from the position at eight o'clock to the position at twelve o'clock, and from the latter to the position at four o'clock; figure 4 shows, similarly to figure 2, the same watch, where the top of the hand is in the four o'clock position, and where the shape of this elastic hand is now a heart shape, after a change of form intervened before this position at four o'clock; figure 5 represents, similarly to figure 4, the same watch, where the top of the hand is in the eight o'clock position, and where its shape is always the same heart, the top has traveled, between the representations of Figure 4 and Figure 5, a circle here centered on the output axis, and before a new change of shape after this position at eight o'clock, to find the almond shape of Figure 3; Figure 6 shows, schematically and in plan view, the elastic needle of Figures 1 to 5, in a constrained service position, where two end guns that it comprises, at the ends of its two flexible blades, are aligned and superimposed on each other, each driven by a different mobile; FIG. 7 is a variant of FIG. 6, where the top has an eye arranged to allow particular viewing on a dial; FIG. 8 represents, similarly to FIG. 1, the same watch, in the same position and in an empty, almond shape, of the elastic hand, which is free, in an unconstrained state, and fixed to a mobile training by only one of its guns; Figure 9 is a left view of the watch of Figure 8; FIG. 10 represents, similarly to FIG. 1, the same watch, in the same position and where the elastic hand comprises a breakable element connecting its two end barrels and facilitating its assembly on the watch movement, as well that the manipulation of the second barrel for its placement above the first, before the breakage by the watchmaker of the fragile fasteners connecting the breakable element to the two barrels; FIG. 11 is a block diagram, in exploded perspective, of a display mechanism according to the invention, where a power take-off, in the lower part of the figure, is arranged to drive two gear trains, the first for drive the first barrel, and the second to drive the second barrel; the arrows illustrate the transmission of motion; the gear trains comprise shaped gears, which are arranged to accelerate, stabilize, or slow down the rotation of one of the barrels relative to the other; the elastic needle is shown in an entirely free state, without a breakable element; this view again shows a conventional hand, coaxial with the elastic hand, for displaying other information, in particular the time; FIG. 12 is a perspective view of a display mechanism according to a first variant of the invention, in which an input wheel set, arranged to cooperate with an output wheel set of the clock movement, is coaxial with a drive shaft, and to a floor on which the first gun is shown mounted, the second gun being shown in the free state of the elastic needle before its positioning coaxial with the first gun on the drive shaft; each form wheel has an angular marking so as to correctly ensure the form wheel effect; FIG. 13, similar to FIG. 12, illustrates the positioning of a section plane, along which the section of FIG. 14 is made; FIG. 14 is a partial section, along the plane shown in FIG. 13, of a clockwork movement driving a mechanism according to the invention; FIG. 15 illustrates, in plan view, a two-stage gear train so as to weight the angular travel of each stage, and where each stage comprises a shaped gear train; FIG. 16 is a plan view of a display mechanism according to a second variant of the invention, in which an input mobile, arranged to cooperate with an output mobile of the clock movement, is separate from the output shaft, and where each gear train comprises two stages so as to weight the angular travel of each stage, and where each stage comprises a shaped gear train; Figures 17 to 20 illustrate the construction of the gear trains: figure 17 illustrates the choice of a space law to vary the radial length of the needle as a function of the angular difference between its two barrels, this figure illustrates the exit angle as a function of the angle d 'entrance ; FIG. 18 illustrates the calculation of the primitive profiles of the teeth, according to the center distance chosen for their production; FIG. 19 illustrates the calculation of the driving toothing, according to the number of teeth defined; FIG. 20 illustrates the calculation of the driven teeth, which then allows the cutting of the two wheels with the profile thus defined; FIG. 21, similar to FIG. 17 but reversed, illustrates three successive zones of radial extension of the needle, stabilization of the length of the needle, and shortening of the needle; FIG. 22 is a plan view of the superposition of the three states illustrated by FIGS. 3 to 5, and the arrows show a phase of contraction CO of the hand between the twelve o'clock and four o'clock positions of its top, a stability phase ST with constant elongation between the positions at four o'clock and at eight o'clock, and a relaxation phase DE between the positions at eight o'clock and at twelve o'clock; FIG. 23 is a diagram showing on the ordinate the evolution of the torque between the flexible segments of the elastic needle, as a function of the angle traversed, with a first zone of reduction in length of the elastic needle with consumption of torque, a second phase of maintaining the length of the needle at a substantially constant torque, and a third phase of lengthening the needle with restitution of the torque; FIG. 24 is a diagram showing on the ordinate the evolution of the torque on a barrel, as a function of the angle of rotation of a barrel; FIG. 25 is a diagram showing on the ordinate the radial extension of the needle, as a function of the angle of rotation of a barrel; FIG. 26 shows, in plan view, a shaped train comprising two wheels not of revolution, and comprising marks for their relative indexing with respect to each other; FIG. 27 represents such a wheel, with an involute toothing, magnified; FIG. 28 represents such a wheel, with sine toothing, magnified.

Detailed Description of Preferred Embodiments

The invention relates to a display indicator for a timepiece.

[0008] The documents EP2863274 and EP3159751 in the name of MONTRES BREGUET SA describe a timepiece display by elastic needle, and their characteristics are directly usable for the production of a display mechanism according to this.

The invention is described here in the particular case, but not limiting, of a rotary indicator, and in particular of an elastic needle. Nevertheless, the principle thereof is applicable to an indicator provided with a mobility trajectory other than circular, for example to a linear cursor, or the like, in particular in space. The invention is more precisely described for this application of a flexible indicator with a needle, but it is applicable to other forms of indicators, in plan or even in three dimensions.

[0010] In the same way, drive means comprising cogs are described below, but the invention is equally applicable to analog display means for an electronic or electrical device, a quartz watch or other.

The principle of the invention is to produce a display mechanism, including at least one indicator, in particular a hand, for example the minute hand for a watch, has a variable length, or a variable radial extension, or a variable form.

[0012] The invention relates to a timepiece display mechanism 10 with variable geometry, which comprises at least one elastic needle 1. This elastic needle 1 comprises a first drive barrel 2, which is integral with at least one one-piece flexible blade 3, and a single flexible blade 3 in the particular and non-limiting case of the figures.

[0013] The display mechanism 10 comprises an input mobile 71, which is arranged to be driven in pivoting around an input axis by a movement 20, and which defines an input angle with respect to a reference direction.

The flexible blade 3 comprises a plurality of flexible segments 5, 5A, 5B, which are joined end to end at at least one vertex 6, and preferably two successive flexible segments are joined by such a vertex.

In the case of the figures, a first flexible segment 5A of the flexible blade 3 extends between the first barrel 2 and a first vertex 6.

More particularly the invention is illustrated in the most common case where the needle comprises two flexible segments 5 joined by a single vertex 6, which is used for the display.

The display mechanism 10 comprises first drive means 11 of the first barrel 2 around an output axis D, and comprises second means 12 for stressing at least the first flexible segment 5: these second means 12 are arranged to vary the position of at least the first vertex 6 with respect to the exit axis D. The first vertex 6 is thus at a variable distance from the first barrel 2, depending on the forces applied to the blade flexible 3 by the second means 12 of stressing.

[0018] Figures 1 to 5 show a particular case of such a mechanism, with an elastic needle 1 comprising a single vertex 6, which follows on an upper part of its stroke an eccentric circle with respect to the output axis, and on a lower part of its stroke another circle centered on the output axis. Naturally, this is a special case, and the mechanism 10, for the same egg-shaped watch, can also be sized to follow the outline of the case, or any other outline highlighting the product.

[0019] According to the invention, the first drive means 11 and/or the second stressing means 12, and in particular the second drive means 13 that they comprise, comprise a first shaped cog 111 and/ or respectively a second shaped cog 131, which is arranged or which are arranged to accelerate or stabilize in speed or slow down at least the first barrel 2, and/or the second barrel 4, over part of its angular stroke.

[0020] More particularly, the first drive means 11 and the second stressing means 12, and in particular the second drive means 13 that they comprise, comprise at least one first shaped cog 111 and respectively at least a second shaped cog 131 which are arranged to accelerate or stabilize in speed or slow down the first barrel 2, and respectively the second barrel 4, over at least part of the angular travel of the first barrel 2, and respectively of the second barrel 4.

In a particular embodiment, illustrated by Figures 1 to 5, the first drive means 11 and the second stressing means 12 are arranged to drive the elastic needle 1 over its entire angular travel around of the output axis D, and give it, in projection on a display plane P or on a dial, and at different angular positions of the elastic needle 1, at least a first shape where the flexible segments 5: 5A , 5B, that comprises the flexible blade 3 do not intersect outside the first barrel 2, and at least a second form where the flexible segments 5: 5A, 5B, that comprises the flexible blade 3 intersect outside the first barrel 2 In the particular and non-limiting case illustrated by the figures, this first shape is an almond shape, and this second shape is a heart shape. In another variant where the elastic needle 1 traverses the surface defined by an ellipse, this needle can occupy successively, on its revolution, an alternation of first shapes and second shapes, for example an almond shape on each of the two ends of the major axis of the ellipse, and a heart shape on each of the two ends of the minor axis of the ellipse.

[0022] More particularly, and as taught by the documents EP2863274 and EP3159751, the elastic needle 1 comprises a second drive barrel 4 also integral with the flexible blade 3. The second stressing means 12 then comprise second drive means 13 of the second barrel 4 in a mounted state of the elastic needle 1. In this mounted state of the elastic needle, both the first barrel 2 is, advantageously but not necessarily in a prestressed operating state, driven by the first drive means 11, and the second barrel 4 is, advantageously but not necessarily in a prestressed operating state, driven by the second drive means 13. And at least one of the vertices 6 is, in a state unconstrained free of the elastic needle 1 in which both the first barrel 2 and the second barrel 4 are not subjected to any constraint, remote from the first barrel 2 and from the second barrel 4, the which first barrel 2 and second barrel 4 are spaced from each other in this free state of the elastic needle 1.

In the particular case of the figures where the flexible strip 3 has only a first flexible segment 5A and a second flexible segment 5B, this vertex 6 which joins them is unique. Thus, more particularly, this first flexible segment 5A carries the first barrel 2 at a first end 52, this second flexible segment 5B joined to the first flexible segment 5A carries the second barrel 4 at a second end 54. And, in the free state of the elastic needle 1, the first end 52 and the second end 54 are distant from each other, or form a non-zero angle with each other from the apex 6 of junction of the first flexible segment 5A and the second flexible segment 5B.

More particularly, the output of the second drive means 13 of the second barrel 4 is coaxial with the output of the first drive means 11 of the first barrel 2, in the mounted state of the elastic needle 1. This arrangement is however not obligatory, in particular in the case of a retrograde display, where the axes of the first barrel 2 and of the second barrel 4 can be distinct.

According to the invention, the first drive means 11 and the second drive means 13 comprise an accelerator or retarder device, which is arranged to accelerate or stabilize in speed or slow down at least the first barrel 2 and/or said second barrel 4 over at least part of its angular travel.

In a first variant, the first gun 2 has an advance or a delay with respect to the value of the entry angle which is symmetrical to the delay or the advance of the second gun 4 with respect to the angle input, so that the first vertex 6 always displays, with respect to the output axis D and the reference, an angle equal to the input angle.

In another variant, the first barrel 2 has an advance or a delay with respect to the value of the entry angle which is, in absolute value, different from the delay or the advance of the second barrel 4 by relative to the entry angle, so that the first vertex 6 displays, relative to the exit axis D and to the reference, a variable angle relative to the entry angle throughout his race. This particular arrangement of advance and/or delay relative to the entry barrel allows the hand to point to the time (or another display) just on the dial, and in particular for an irregular display, for example a square trajectory where the time is separated into twelve equidistant segments on the square trajectory, which cannot be managed in the same way as twelve indexes separated by 30°.

In yet another variant, the needle 1 is arranged to perform a non-retrograde total stroke, and, over the total stroke, the average speed of the first gun 2 is equal to the average speed of said second gun 4.

Many configurations can be envisaged: if the arms of the hand are symmetrical, a symmetrical advance and delay are necessary, so that the hand points to the correct time; if the arms of the hand are asymmetrical, it takes an advance and a delay so that the hand points to the correct time; it is assumed that the hand points to the correct time. It is also possible to have a graduation which is not separated every 30° as explained above.

[0030] In a particular embodiment which will be detailed later, the accelerator or retarder device comprises a first cog of shape 111 and/or respectively a second cog of shape 131.

In another particular embodiment which will be detailed later, the accelerator or retarder device comprises a device with a first differential on the drive train of the first gun 2 and/or a second differential on the drive train of the second barrel, and at least one cam, constituting an input of such a differential.

[0032] In yet another embodiment, the accelerator or retarder device comprises simple cogs arranged suitably to perform the required accelerations or decelerations.

[0033] More particularly, and as seen in Figures 11 to 20, the first drive means 11 and the second drive means 13 comprise, respectively, at least one first shaped cog 111 and at least one second cog of shape 131, which are each arranged or which are arranged to accelerate or stabilize in speed or slow down the first gun 2 and respectively the second gun 4 over part of its angular travel. By form train is meant here that at least one wheel of the train is not of revolution; more particularly, at least two antagonist wheels of this gear train are not of revolution, and are arranged to permanently mesh with minimal play with each other at constant center distance.

[0034] More particularly, the first shaped cog 111 and the second shaped cog 131 are arranged to accelerate or respectively brake the first barrel 2, and to brake or respectively accelerate the second barrel 4 over at least part of the angular stroke of the elastic needle 1, or even over only part of the angular stroke of the elastic needle 1. Stated otherwise, one of the barrels takes an angular advance with respect to the entry angle, while the other barrel takes an angular delay with respect to the entry angle.

Thus, in a particular embodiment of the invention, the first gun 2 has an advance or a delay with respect to the value of said entry angle which is symmetrical to the delay or the advance of the second gun 4 relative to this same entry angle, so that the first vertex 6 always displays, relative to the exit axis D and to the reference direction, an angle equal to the entry angle.

Thus, considering the embodiment according to Figures 3 to 5, with a total angular stroke CAT of 360°, from a position in Figure 3 where the top 6 of hand 1 is at twelve o'clock, to pass into the position at four o'clock in Figure 4, rotating clockwise, the second barrel 4 of the second flexible segment 5B has slowed down by 60°, and the first barrel 2 of the first flexible segment 5A has accelerated by 60°. Indeed, none of the flexible segments 5 of hand 1 alone indicates the time, it is only the result of the rotation of the two barrels which determines a time indication by the top 6 of hand 1. Between the position of Figure 4 and the eight o'clock position of Figure 5, the guns remain synchronous with their offset. To pass from the position at eight o'clock in FIG. 5 to that at twelve o'clock in FIG. 3, it is the reverse, the second barrel 4 of the second flexible segment 5B has accelerated by 60°, and the first barrel 2 of the first flexible segment 5A slowed down 60°.

The invention is illustrated in the figures by the particular case of a continuous watch display displaying a complete turn, it is understood that the invention is applicable to any display, in particular a retrograde display.

[0038] More particularly, the first shaped cog 111 and the second shaped cog 131 are arranged to drive the first barrel 2 and the second barrel 4 symmetrically, so that the first flexible segment 5A and the second flexible segment 5B are symmetrical with respect to a radial coming from the output axis D and passing through the apex 6 of junction between the first flexible segment 5A and the second flexible segment 5B, over at least part of the angular stroke of the elastic needle 1. This configuration is not limiting, but it offers the advantage of subjecting the first flexible segment 5A and the second flexible segment 5B to symmetrical constraints.

[0039] More particularly, the first shaped cog 111 and the second shaped cog 131 each comprise at least one pair of wheels arranged to cooperate in mesh with each other and whose geometric supports are that is to say, the primitive curves of the teeth are not of revolution.

[0040] Even more particularly, the first drive means 11 and/or the second drive means 13 comprise at least a first gear train stage 115, 135, and a second gear train stage 116, 136, which are arranged to each control part of the shape transformation of the elastic needle 1 over at least part of its angular travel, with a weighting per stage. This weighting makes it possible to distribute a part of the deformation over each of the stages, which makes it possible, in each shaped cog, to retain wheels whose geometry is close to a circular geometry, so as to allow suitable meshing of the teeth, and prevent their wear. Indeed, the shaped cogs are not circular, but must not be too deformed, that is to say that their shape must allow meshing without buttressing, and without too much sensitivity to variations in center distance and manufacturing tolerances. It is thus possible to avoid the interference faults that cut teeth would present if the primitive curves of the teeth deviated too much from the circular shape. It is therefore a question of defining a compromise between a shape that is sufficiently non-circular to actuate the needle, and a shape that is resistant to use. The distribution over several stages makes it possible to fulfill these conditions: each stage participates in the deformation of the needle, but its primitive curves remain close to a circular shape, this is what is called here the weighting per stage, the overall accumulation of these stepped cogs making it possible to ensure the desired deformation at the level of the needle.

[0041] The figures illustrate, without limitation, a variant with two stages of cogs, but this number of two is not limiting, only the total thickness of the movement and the loss of performance due to friction limit the number of stages.

[0042] More particularly, both the first gear train stage 115, 135, and the second gear train stage 116, 136, respectively comprise a first gear train 111 and a second gear train 131.

[0043] Figures 11 to 20 detail certain particular arrangements of such shaped cogs.

[0044] Figure 11 schematically shows the operation of such a mechanism 10, the arrows symbolize the transmission of movement to the barrels, from a power take-off 21 at the level of a clockwork movement 20, which can be both mechanical and electronics, symbolized in the lower part of the figure, and which is arranged to drive by the same input mobile 71 two gear trains: a first gear train comprises idler wheels 79 and 80 around a first axis DA and wheels 73, 78, and 81 around the main pivot axis D to drive the first barrel 2, and a second gear train has idler wheels 74, 75 around a second axis DB and a wheel 76 around the main pivot axis D to drive the second barrel 4.

[0045] It is noted that the entire gear train is under tension, due to the backlash of the elastic needle due to its prestressing.

Figure 11 shows, again, a conventional needle 100, coaxial with the elastic needle 1, for displaying other information, including time.

[0047] Figures 12 to 14 more specifically illustrate a display mechanism 10 according to a first variant of the invention, for displaying the minutes with the elastic hand 1. In this first variant, an input mobile 71 is arranged to cooperate with an output wheel set 21 of the clock movement 20, along an input axis D0, and is guided on a fixed tube 70. This input wheel set 71, which is a roadway, is arranged to drive , directly or through a lanterning by friction allowing adjustment of the time, a driveway 72 which is coaxial with it.

This driving floor 72 is of revolution, and drives a first shaped wheel 78, which meshes with a second wheel of complementary shape 79 mounted crazy (with play compensation) around the first axis DA, and which is integral in pivoting a third wheel of shape 80, which meshes with a fourth idler wheel of complementary shape 81, which here pivots around the output axis D of the barrels, and which comprises a floor 82 for fixing the first barrel 2.

The same drive road 72 drives a fifth shaped wheel 73, which meshes with a sixth wheel of complementary shape 74 mounted loose around the second axis DB, and which is integral in pivoting with a seventh shaped wheel 75, which meshes with an eight idler wheel of complementary shape 76, which here pivots around the output axis D of the barrels, and is integral with a shaft 77 on which the second barrel 4 is fixed.

[0050] Each form wheel has an angular marking so as to ensure the correct indexing of the form train, as detailed in Figure 26 which details a form train comprising two wheels 75 and 76 not of revolution, and comprising markers 276 for their relative indexing with respect to each other, as well as oblongs 175 and 176 facilitating their installation, which makes it possible in particular to secure them and to index them by means of a pin or the like.

[0051] The driving floor 72 further drives a ninth wheel 91 which comprises a wheel set pivoting about an hour axis DH, which comprises a pinion 92 driving the wheel 93 of an hour floor 94 receiving the hour hand 100 .

[0052] Figures 15 and 16 illustrate a second variant of the invention, in which an input mobile, arranged to cooperate with an output mobile of the clock movement, pivots around an input axis D0 which is here distinct from the output axis D, and where each gear train comprises two stages so as to weight the angular travel of each stage, and where each stage comprises a gear train of the form: a first gear train comprises a first stage with a first shaped wheel 101 pivoting around the input axis D0, which meshes with a second wheel of complementary shape 102, mounted loosely around a first secondary axis D1. This second wheel of complementary shape 102 is integral in pivoting with a third wheel of shape 103, which meshes with a fourth wheel of complementary shape 104, pivotally mounted on the output shaft D, and designed for fixing one of the two guns; a second gear train, isolated in figure 16, comprises a first stage with a first shaped wheel 201 pivoting around the input axis D0, which meshes with a second wheel of complementary shape 202, loosely mounted around a second secondary axis D2. This second wheel of complementary shape 202 is integral in pivoting with a third wheel of shape 203, which meshes with a fourth wheel of complementary shape 204, pivotally mounted on the output shaft D, and designed for fixing the other cannon.

[0053] The case of a construction with a radial symmetry of movement between the two flexible segments of one and the same needle 1 uses two similar sets of cogs of identical shape, one mounted upright, the other towards.

[0054] Figures 17 to 20 illustrate the construction of the cogs, which begins with the choice of a space law to vary the radial length of the needle according to the angular difference between its two guns, FIG. 17 illustrates the exit angle as a function of the entry angle for one of the two barrels of the needle. This space law allows the calculation of the primitive profiles of the teeth, according to the center distance chosen for their production, as shown in figure 18. The calculation of the driving teeth is then carried out according to the number of teeth defined, and the type of profile chosen, in particular involute or sine type, according to FIG. 19, then the calculation of the driven teeth, according to FIG. 20, then allows the cutting of the two wheels with the profile thus defined;

[0055] Figures 17 and 20 illustrate the law of space, with three successive zones of radial extension of the needle, stabilization of the length of the needle or the ratio between the exit angle of one of the two barrels and the angle of entry into the mechanism is substantially constant, and of shortening of the needle.

[0056] Figure 22 shows the superposition of the three states illustrated by Figures 3 to 5, and the arrows highlight a phase of contraction CO of the hand 1 between the positions at twelve o'clock and at four o'clock from its top 6 , a stability phase ST with constant elongation between the four o'clock and eight o'clock positions, and a relaxation phase DE between the eight o'clock and twelve o'clock positions. This weighting is made possible by the use of form trains, and in particular mechanisms with several stages of form train, which make it possible to impose sufficient angular displacements on the barrels, to authorize significant changes in form, and in particular for to be able to proceed with the crossing of the flexible segments as in the shape of a heart. These shaped cogs make it possible to safely slow down one barrel relative to the other.

The wheel of Figure 27 is an example of optimizing the case of this Figure 22; to correct the trajectories on angles of 140°-80°-140° as illustrated, instead of 120°-120°-120° which would be more balanced, it is necessary, without weighting per particular floor, i.e. - say if the upper stage and the lower stage each carry out half of the angular transformation, to design wheels with very strong deformations, and very inclined teeth, which are difficult to machine and fragile. Another weighting, for example 20% of the deformation on the lower floor and 80% on the upper floor, makes it possible to have wheels closer to a round shape, easier to machine, and with teeth close to the standard , therefore with better kinematic and tribological parameters, and less wear.

[0058] Figure 23 shows the evolution of the torque between the flexible segments of the elastic needle, as a function of the angle traveled, with a first zone of reduction in the length of the elastic needle with consumption of torque, a second phase of maintaining the length of the needle at a substantially constant torque, and a third phase of lengthening the needle with restitution of the torque, figure 24 illustrates the evolution of the torque on a barrel, as a function of the angle of rotation of a barrel, and Figure 25 shows the radial extension of the needle, as a function of the angle of rotation of a barrel.

The elastic needle 1 can be made in different ways.

In a first variant, in the free state, the elastic needle 1 extends over a single plane level comprising the first barrel 2 and the second barrel 4, and the elastic needle 1 is then arranged to be mounted twisted into a constrained service position in which the first barrel 2 and the second barrel 4 are superimposed on one another.

In a second variant, in the free state, the elastic needle 1 extends over a first plane level comprising the first barrel 2 and over a second plane level comprising the second barrel 4, and comprises a connection zone between the first plane level and the second plane level at the level of a vertex 6 between a first flexible segment 5A carrying the first barrel 2 and a second flexible segment 5B adjoining the first flexible segment 5A and carrying the second barrel 4, and the elastic needle 1 is arranged to be mounted without twisting in a constrained service position in which the first barrel 2 and the second barrel 4 are superimposed on one another. In another particular variant, when the elastic needle 1 comprises more than two flexible segments 5, in the free state, the elastic needle 1 extends over, at most, as many parallel levels as there are flexible segments 5, and is arranged to be mounted without twisting in a constrained service position in which the first barrel 2 and the second barrel 4 are superimposed on one another.

In a particular variant intended to facilitate assembly, visible in Figure 10, in the free state, the elastic needle 1 comprises a breakable element 24 joining the first barrel 2 and the second barrel 4, to facilitate the mounting of the elastic needle 1 on a driving wheel of the first barrel 2 or of the second barrel 4, this breakable element 24 being arranged to be broken and to allow the passage of the elastic needle 1 in a service position under constraint in which the first barrel 2 and the second barrel 4 are superimposed on each other.

[0063] Figure 7 illustrates a particular variant where the elastic needle 1 comprises at least one eye 60, which is arranged to constitute a window for reading an indication appearing on a dial that comprises the mechanism 10, and in front of which s extends the elastic needle 1, or that includes a clockwork 20, on which the mechanism 10 is arranged to be attached. For example, this eye makes it possible to view a city in a GMT application, or to distinguish morning time from 0 to 12 from afternoon time from 13 to 24, in a particular application where training of the display mechanism is made on two revolutions, the first with a certain extension of the elastic hand 1 for the display of the morning hours, and the second with a different extension for the display of the afternoon hours ; of course this variant can also accommodate a display by the top 6 of the needle 1, the presence of such an eye 60 provides reading comfort to the user. FIG. 7 further illustrates two indexes, interior and exterior, on either side of this eye 60, which also allow particular readings, depending on the dial configuration adopted. One of the great advantages of the invention is to allow great freedom in the design of the dial, and the transfer of certain display zones outside unavailable zones, for example due to the presence of a tourbillon, or even of another complication.

Advantageously, the needle 1 is made of micro-machinable material according to a "LIGA" process, in particular nickel-phosphorus NiP12 or similar. Such a needle can be gilded, or receive another coloring, the adhesion being satisfactory on such a material. The needle 1 can be colored by different processes: PVD, CVD, ALD, galvano, paint, lacquer, or other coating or ionization.

[0065] The hand 1 may comprise a gem or similar crimping, and/or a decoration by guillochage, engraving, bevelling, or even enameling, the latter being reserved for areas with low deformation such as the turn of the barrels, a turn of eye, tip, or similar.

[0066] More particularly, the mechanism 10 constitutes an additional module, which is arranged to be attached to a clock movement 20, and the first drive means 11 and the second stressing means 12 comprise a common input 71 , which is arranged to be driven by a single output 21 included in the movement 20, such as the roadway which turns in one hour, or the minute wheel.

In a variant, in addition to or instead of the shaped cogs, the mechanism 10 comprises, between on the one hand the input mobile 71 arranged to be driven by the movement 20, and on the other hand the first gun 2 and/or the second gun 4, at at least one stage, a cam. This cam is arranged to drive a differential, a first input of which consists of the input wheel set 71, a second input of which is a wheel set, in particular a rake, controlled by this cam, and the output of which meshes with the transmission cog movement to the first barrel 2 or respectively to the second barrel 4.

In a first application of this variant, the mechanism 10 comprises, between the input mobile 71 and the first barrel 2 at the level of at least one stage, a single cam arranged to control a first differential, a first input consists of the input wheel set 71, a second input of which is a first wheel set or a first rake controlled by the cam, and the output of which meshes with the gear train for transmitting movement to the first barrel 2, and between the wheel set input 71 and the second barrel 4, the same single cam arranged to drive a second differential, a first input of which consists of the input wheel set 71, a second input of which is a second wheel set or a second rake controlled by the cam, and the output of which meshes with the cog transmitting the movement to the second barrel 4.

In a second application of this variant, the mechanism 10 comprises, between the input mobile 71 and the first barrel 2 at the level of at least one stage, a first cam arranged to drive a first differential, a first input consists of the input wheel set 71, a second input of which is a first wheel set or first rake controlled by the first cam, and the output of which meshes with the gear train for transmitting movement to the first barrel 2; and, between the input wheel set 71 and the second barrel 4, a second cam driven by the input wheel set and arranged to drive a second differential, a first input of which is formed by the input wheel set 71, a second input of which is a second rake controlled by the second cam, and whose output meshes with the gear train for transmitting movement to the second barrel 4.

[0070] The use of a cam allows highly non-circular trajectories, and also with needle jumps. The use of a single cam for the two differentials makes it possible to carry out a simultaneous jump of the two barrels, for example at midnight; the first differential adds the cam information for the first barrel, and the second differential subtracts the information for the second barrel.

In another particular variant, at least one wheel that comprises the cog mechanism arranged between on the one hand the input mobile 71 arranged to be driven by a movement 20, and on the other hand the first barrel 2 and / or the second barrel 4, at the level of at least one stage, comprises an incomplete toothing, each missing tooth allowing relaxation of the elastic needle 1, by rotation of only one of the barrels 2, 4, during the passage of the space corresponding to a missing tooth, or to the missing teeth, so as to command a retreat of the top 6 of the elastic needle 1.

[0072] In particular, it is then possible to use a gear train comprising one or more, or even all, of the circular wheels, of which at least one circular wheel is devoid of one or more teeth to allow the needle to relax, and to perform a jump at the end of the so-called display spiral path performed by the top 6 of the needle 1. If, for example, the first barrel rotates faster than the second barrel, and if the driving road 72 is locally devoid of teeth, the needle tends to contract, for example over two turns, and, when the missing teeth release the first barrel, the needle tightens but the second barrel does not move, the top of the needle performs a recoil. The advantage of such a variant is to allow conventional machining of the wheels.

[0073] Figure 24 shows the very low level of torque consumption for the deformation of such a hand 1 in LIGA, during its shortening, which has only a very small influence on the rate of the movement. Due to the proximity of the exhaust, it is nevertheless advantageous to reduce this disturbance as much as possible, which can be obtained with very thin flexible segments 5, typically less than 100 micrometers in width and 200 micrometers in height for a LIGA building. We understand in figure 24, where we see that the curve of torque as a function of the angle is U-shaped with a very flat bowl, that it is advantageous, during the design, to choose an angular range of deformation corresponding to the lowest level of the torque curve, so as to minimize the induced parasitic torque, and therefore to minimize the disruption of the rate of the watch. A stepwise design with special weighting helps to choose the optimal angular domains. The correct choice of this angular range also makes it possible to thicken the segments 5 of the needle 1 to make it more visible, without notably increasing its disturbing torque.

By way of comparison, the disturbance induced on the rate is less than that caused by a date change at midnight for a date mechanism.

The invention is illustrated in the figures with a simple shape, but it can be declined with very different shapes of needles. For example, an asymmetrical needle, made up of two vees nested one inside the other and in the same direction, each arm of each vee being attached to one of the barrels, and the extreme end of the other arm being linked to the similar end of the other v. Or a needle with double arms, with two segments joining a first vertex and fixed to the two barrels, and two other segments joining a second vertex distant from the first, and fixed to the same barrels. Or even a needle comprising thickened zones on a middle zone of the flexible segments, for better visualization of the needle.

Claims (10)

1. Variable geometry timepiece display mechanism (10), comprising at least one elastic hand (1) comprising at least one one-piece flexible blade (3) and on the one hand a first integral drive barrel (2) of the said at least one flexible blade (3), which comprises a plurality of flexible segments (5; 5A; 5B) joined end to end at the level of at least one vertex which the elastic needle (1) comprises, of which a first flexible segment (5A) extends between said first barrel (2) and a first vertex (6), the elastic needle further comprising a second drive barrel (4) also integral with said at least one flexible blade (3), said display mechanism (10) comprising an input mobile (71) arranged to be driven in pivoting around an input axis by a movement (20) and defining an input angle with a reference, and said display mechanism (10) comprising first drive means (11) of said first barrel (2) around an axis outlet (D) parallel or coinciding with said input axis, and second means (12) for stressing at least said first flexible segment (5A) which are arranged to vary the radial position by at least said first vertex (6) with respect to said output axis (D), means said first drive means (11) and second stressing means (12) comprising a common input constituted by the input mobile (71) , said first vertex (6) being at a variable distance from said first barrel (2) depending on the forces applied to said flexible blade (3) by said second stressing means (12), where said second means (12) of stressing comprise second drive means (13) of said second gun (4), characterized in that said first drive means (11) and/or said second drive means (13) comprise an accelerator device or retarder which is arranged to accelerate or stabilize speed up or slow down at least said first barrel (2) and/or said second barrel (4) over at least part of its angular travel. 2. Display mechanism (10) according to claim 1, characterized in that said first barrel (2) has an advance or a delay with respect to the value of said entry angle which is symmetrical to the delay or to the advance of said second barrel (4) with respect to said entry angle, so that said first vertex (6) always displays, with respect to said exit axis (D) and to said reference, an angle equal to said entry angle . 3. Display mechanism (10) according to claim 1, characterized in that said first barrel (2) has an advance or a delay with respect to the value of said entry angle which is, in absolute value, different from the delay or of the advance of said second barrel (4) with respect to said entry angle, so that said first vertex (6) displays, with respect to said exit axis (D) and to said reference, an angle varying by relative to said entry angle throughout its travel. 4. Display mechanism (10) according to one of claims 1 to 3, characterized in that said elastic needle (1) is arranged to perform a non-retrograde total stroke, and that, over said total stroke, the average speed said first gun (2) is equal to the average speed of said second gun (4). 5. Display mechanism (10) according to one of claims 1 to 4, characterized in that said accelerator or retarder device comprises at least one shaped cog (111, 131), that is to say a cog comprising at least one wheel which does not have a shape of revolution. 6. Display mechanism (10) according to one of claims 1 to 5, characterized in that said accelerator or retarder device comprises a device with a first differential on the drive train of said first barrel (2) and/or a second differential on the drive train of said second barrel, and at least one cam constituting an input of said differential. 7. Display mechanism (10) according to claim 5, characterized in that said first drive means (11) and/or said second drive means (13) comprise at least a first gear train stage (115; 135) and a second gear train stage (116; 136) each arranged to control part of the shape transformation of said elastic needle (1) over part of its angular travel, with a weighting per stage. 8. Display mechanism (10) according to claim 5, characterized in that said first drive means (11) comprise at least one first shaped cog (111) and said second drive means (13) comprise at least one at least one second form train (131), each of the form trains being arranged to accelerate or stabilize in speed or slow down said first barrel (2), and respectively said second barrel (4), over at least part of the angular travel of said first barrel (2), and respectively of said second barrel (4). 9. Display mechanism (10) according to one of claims 1 to 8, characterized in that said first drive means (11) and said second stressing means (12) are arranged to drive said elastic needle (1) over its entire angular travel around said output axis (D), and give it, in projection on a display plane P or on a dial, and at different angular positions of said elastic needle (1) , at least a first shape where said flexible segments (5; 5A; 5B) that said flexible blade (3) does not intersect outside of said first barrel (2), and at least a second shape where said flexible segments (5 5A; 5B) that comprises said flexible blade (3) intersect outside said first barrel (2). 10. Display mechanism (10) according to claim 9, characterized in that said first shape is an almond shape, and said second shape is a heart shape.