CH719935A1 - Watch component with a monolithic flexible structure having a plurality of stable positions. - Google Patents

Abstract

The invention relates to a watch component for a watch mechanism (100), the mechanism (100) comprising a control member (9) and a transmission member (6). The transmission member (6) is movable between a winding position and at least one adjustment position. The watch component comprises a flexible structure (10) with: – an input portion arranged to be integral, in translation, with the control member (9), – an output portion distinct from the input portion and arranged to be integral, in translation, with the transmission member (6), and - at least one flexible portion arranged to pass reversibly from a first stable position, in which the transmission member (6) is in the winding position, towards a second stable position in which the transmission member (6) is in the adjustment position, passing through an unstable position.

Description

[0001] The present invention relates generally to the field of watchmaking, more particularly to the field of watch components, even more particularly, to the watch components involved in time setting and adjustment mechanisms, or even winding for a mechanical watch.

[0002] Document EP1538494 discloses a mechanism for controlling a mechanical watch movement, comprising three positions and provided with a wheel for winding its barrel spring, drive teeth for its date indicator and a drive mobile for its timer wheel, allowing the indication of the date and time to be corrected respectively.

[0003] We know the control mechanisms with a rocker, a pull tab and a pull spring. They may have two or three positions, depending on the number of functions to be corrected, in addition to winding. However, the user's perception when operating the rod in translation is often unpleasant, particularly for a control rod with three positions (winding, setting the time, correcting the date). The positions are defined by the pull spring, which includes indentations with which the pull can interact. With too little marking of the different positions, it is difficult to stop the rod in the intermediate position. With too strong a marking, the user may have the feeling that he risks breaking the mechanism when he pulls on the rod.

[0004] The present invention aims to propose a new construction of watch component, making it possible to improve the quality of detenting and thus improve the use of a control member, so that the user is assured of having positioned the control member in the desired position, flexibly and precisely.

[0005] Thus, the invention relates to a watch component for a watch mechanism, the mechanism comprising a control member and a transmission member, in which the transmission member is movable between a winding position and at least one adjustment position, in which the watch component comprises a flexible structure with: – an input portion arranged to be integral, in translation, with the control member, – an output portion distinct from the input portion and arranged to be integral, in translation, of the transmission member, and - at least one flexible element arranged to pass reversibly from a first stable position, in which the transmission member is in the winding position, towards a second stable position in which the transmission member is in the adjustment position, passing through an unstable position.

[0006] This makes it possible to provide a watch component improving the user experience, in particular by allowing the user to be assured of having moved the control member to the desired position. In addition, this allows antagonistic translation between the control member such as a rod and the transmission member such as a sliding pinion. In particular, the watch component can be adapted to any type of mechanical or electromechanical watch. In addition, this makes it possible to improve reliability, robustness, reduce assembly time and reduce or eliminate the need for lubrication.

[0007] By winding position we mean a first stable position, and by adjustment position a second stable position.

[0008] Advantageously, the watch component further comprises a nodal portion arranged to carry the at least one flexible element. A nodal portion is a rigid, mobile element, making it possible to group flexible elements located between the input and output interfaces and the base.

[0009] This makes it possible to improve the stability and the arrangement of the at least one flexible element, in particular in the case of a plurality of flexible elements.

[0010] Advantageously, the nodal portion is a carriage. By carriage we mean a mobile element of the flexible structure.

[0011] Advantageously, the nodal portion is guided in translation by the at least one flexible element.

[0012] Advantageously, the watch component comprises a plurality of flexible guides arranged to pass (each) reversibly from a first stable position, in which the transmission member is in the winding position, towards a second stable position in which the transmission member is in the adjustment position, passing through an unstable position.

[0013] Advantageously, the at least one flexible guide comprises a plurality of flexible elements, and in which – at least one flexible inlet element, such as a flexible inlet blade or a flexible inlet pivot, is arranged between the inlet portion and the nodal portion, – at least one flexible outlet element , such as a flexible output blade or a flexible output pivot, is arranged between the output portion and the nodal portion, and – optionally, at least one basic flexible articulation, such as a basic flexible blade table , is arranged between the nodal portion and a base of the flexible structure.

[0014] Advantageously, the at least one flexible portion comprises a plurality of flexible elements, and in which – at least one flexible inlet portion, such as a flexible inlet blade or a flexible inlet pivot or a flexible inlet guide, is arranged between the inlet portion and the nodal portion, – at least one flexible outlet portion, such as a flexible outlet blade or a flexible outlet pivot or a flexible outlet guide, is arranged between the outlet portion and the nodal portion, and – optionally, at least one flexible base portion, such as a table with flexible base blades, is arranged between a first nodal portion and a second nodal portion.

[0015] Advantageously, the watch component further comprises a base, in which the second nodal portion is arranged between the first nodal portion and the base, and in which the plurality of flexible elements further comprises at least one flexible element d the base arranged between the base and the nodal portion.

[0016] Advantageously, the base of the flexible structure is integral with a plate.

[0017] This makes it possible to transmit a movement of the control member carried out by a user, via the input portion, to the nodal portion, then to the output portion, thanks to the plurality of flexible elements. That is to say that the watch component can function as for example a knee joint or an articulated parallelogram, and allows for antagonistic translations of the input portion and the output portion, in the same direction but in opposite. This makes it possible to offer a flexible structure with two stable positions, allowing for example to wind the barrel spring in the first stable position, and to reset the time in the second stable position.

[0018] Advantageously, the flexible structure can have symmetry with respect to the plane passing through an axis of the control member and perpendicular to a plane of the plate, so as to cancel out possible moments applying to the portion of entry and/or the exit portion.

[0019] Advantageously, the watch component can further comprise a second nodal portion (equivalent to the previous base, which becomes a carriage) arranged between the previous nodal portion (called first nodal portion) and a new base, thanks to at least a second flexible guide.

[0020] This makes it possible to propose a flexible structure with three stable positions, allowing for example to rewind the barrel spring in the first stable position, to reset the time in the second stable position and to carry out the correction date in the third stable position.

Advantageously, the first nodal portion has a first translation axis and a second translation axis.

Advantageously, the transmission member is a sliding pinion, the input portion is engaged in a groove of the control member, and the output portion is engaged in a groove of the sliding pinion.

[0023] This ensures clear and reliable notching between each of the functions of the watch mechanism.

In other words, the input portion or the output portion is arranged to transmit a translation movement of the control member.

Preferably, the at least one flexible element is arranged to pass through a plurality of unstable positions.

Advantageously, the transmission member is a sliding pinion, a portable player and/or a date correction mobile.

Advantageously, the control member is arranged to cooperate with a crown.

[0028] Advantageously, the control member makes it possible to ensure the winding of the barrel spring, the setting of the date (date correction), the resetting of the time, and/or other functions such as the adjustment of the ringtone or countdown.

Advantageously, the flexible structure is monolithic.

Advantageously, the flexible structure is based on silicon. Advantageously, the watch component comprises a plurality of flexible structures, in particular two flexible structures or three flexible structures.

Advantageously, the watch component further comprises another flexible structure (or second flexible structure) having at least one other flexible portion arranged between a nodal portion of the flexible structure (or first flexible structure) and a fixed portion, such as 'a turntable.

[0032] This makes it possible to propose a third stable position in order to allow the adjustment of another function of the watch.

Advantageously, the at least one flexible guide is prestressed by the application of forces to their fixings. Advantageously, the at least one flexible portion is prestressed.

[0034] This makes it possible to improve the tilting from the first stable position of the at least one flexible guide to the second stable position of the at least one flexible guide while passing through an unstable state.

Advantageously, the flexible structure comprises an internal portion and an external portion, and in which the inlet portion is integral with one of the internal portion and the external portion; and the outlet portion is integral with the other of the internal portion and the external portion.

Other characteristics and advantages of the present invention will appear more clearly on reading the detailed description which follows, of embodiments of the invention given by way of non-limiting example and illustrated by the appended drawings, in which: – Figure 1 represents the watch component with a schematic representation of a first flexible structure in a first position of the first flexible structure, – Figure 2 represents the watch component with the schematic representation of the first flexible structure in a second position of the first flexible structure, – Figure 3 represents the watch component with a schematic representation of the first flexible structure and a second flexible structure which is in a first position of the second flexible structure. – Figure 4 represents the watch component with the schematic representation of the first flexible structure and the second flexible structure which is in a second position of the second flexible structure. – Figure 5 represents an energy level of the first flexible structure as a function of a movement of the first flexible structure, – Figure 6 represents the watch component with a sliding pinion and the first flexible structure in the first position of the first flexible structure, – Figure 7 represents the watch component with the sliding pinion and the first flexible structure in the second position of the first flexible structure, – Figure 8 represents the watch component with the sliding pinion, the first flexible structure in the first position of the first flexible structure, and the second flexible structure in the first position of the second flexible structure, – Figure 9 represents the watch component with the sliding pinion, the first flexible structure in the second position of the first flexible structure, and the second flexible structure in the first position of the second flexible structure, – Figure 10 represents the watch component with the sliding pinion, the first flexible structure in the second position of the first flexible structure, and the second flexible structure in the second position of the second flexible structure, – Figure 11 represents the watch component with the sliding pinion, the first flexible structure in the second position of the first flexible structure, and the second flexible structure in the second position of the second flexible structure, in an embodiment with an angle of inclination of the flexible structures, – Figure 12 represents another embodiment of the first flexible structure, in the first position of the first flexible structure and in the second position of the first flexible structure, – Figure 13 represents the other embodiment with the watch component having the sliding pinion and the first flexible structure, in the first position of the first flexible structure, – Figure 14 represents the other embodiment with the watch component having the sliding pinion and the first flexible structure, in the second position of the first flexible structure, - Figure 15 represents the other embodiment with the watch component having the sliding pinion, the first flexible structure, in the first position of the first flexible structure, and the second flexible structure in the first position of the second flexible structure, - Figure 16 represents the other embodiment with the watch component having the sliding pinion, the first flexible structure, in the second position of the first flexible structure, and the second flexible structure in the first position of the second flexible structure, - Figure 17 represents the other embodiment with the watch component having the sliding pinion, the first flexible structure, in the second position of the first flexible structure, and the second flexible structure in the second position of the second flexible structure, – Figure 18 represents an alternative embodiment with flexible guidance.

[0037] In the present description, the reference numbers between the figures and the embodiments are repeated as far as possible and necessary.

The different embodiments can be combined as much as possible and necessary.

[0039] Figures 1 to 2 schematically represent a watch component with a flexible structure having two stable positions. Figures 3 to 4 schematically represent the watch component with the flexible structure having three stable positions. Figures 6 to 7 represent the watch component with translational operation, at two stable positions. Figures 8 to 11 represent the watch component with translational operation, at three stable positions. Figures 12 to 14 represent the watch component with rotating operation, in two stable positions. Figures 15 to 17 represent the watch component with operation in translation and rotation, at three stable positions.

[0040] Figure 1 shows the watch component for a watch mechanism 100 which comprises the flexible structure 10 shown schematically, also called first flexible structure 10. The first flexible structure 10 is an example of a flexible structure.

[0041] We can refer to the work of Simon Henein: “Design of flexible guides” at Presses polytechniques et universitaire romandes, 2004, ISBN 9782880744816, which is part of general knowledge in the field of guides and other flexible structures applicable to watchmaking.

Flexible elements will be defined as being the elementary constituents of flexible structures such as for example blades, circular necks, rods or wires, or even torsion bars. We will define a flexible joint as being a set of flexible elements linked with rigid segments to achieve either a translation or an elementary rotation, such as a table or a pivot. We will call flexible guidance the singleness or plurality of flexible joints to carry out any movement between an entry and an exit. Finally, we will define the flexible structure as a set of flexible guides.

[0043] It can be specified that a flexible element is an element that is elastically deformable or which flexes easily or allows itself to be bent.

[0044] Hereinafter, the term flexible portion will mean one or more flexible elements, or one or more flexible joints, or even one or more flexible guides.

The watch mechanism comprises a control member 9 such as a winding stem 9, or simply called stem 9. The stem 9 is mounted on a plate 1 via a sliding pivot connection 3 in a conventional manner . The rod 9 is therefore movable in translation and in rotation with respect to the plate 1. The rod 9 can also be stopped in translation thanks to two stops 9b arranged on either side of the sliding pivot connection 3. The rod 9 is secured to a crown 2 in order to allow the user to act on the rod 9 via the crown 2. Note that it is possible to provide only one stop instead two stops 9b, or to provide the stop(s) on another component.

The watch mechanism 100 further comprises a transmission member 6, such as a sliding pinion 6. The watch mechanism 100 further comprises a winding pinion 4 arranged to be able to wind a barrel spring in a conventional manner.

The sliding pinion 6 is movable in rotation and in translation and can mesh with the winding pinion 4 at the level of a meshing portion 5. The sliding pinion 6 further comprises a toothed portion 7 arranged with a side opposite the meshing portion 5 with the winding pinion 4.

[0048] The flexible structure 10 is integral, in translation, at the level of an inlet portion (on the side of the crown 2) with the rod 9. The flexible structure 10 is integral, in translation, at the level of a output portion (on the side opposite the crown 2) with the sliding pinion 6. The input portion and the output portion are distinct.

[0049] In Figure 1, the sliding pinion 6 is shown in a first position, here a winding position, in which the toothed portion 7 is at rest, that is to say it is not engaged with another element. In the winding position, the sliding pinion 6 is meshed with the winding pinion 4, so as to allow the winding of a barrel spring.

[0050] The flexible structure comprises at least one flexible element, as will be detailed below with reference to the other figures, arranged to pass reversibly from a first stable position, in which the transmission member (here the pinion sliding pinion 6) is in the winding position (or first position), towards a second stable position in which the transmission member (here the sliding pinion 6) is in the adjustment position (or second position), passing through a unstable state.

[0051] In Figure 1, the flexible structure 10 is shown in the first stable position.

[0052] In Figure 2, the user has pulled on the crown 2 and the rod 9 so as to move the sliding pinion 6.

[0053] The sliding pinion 6 is no longer meshed with the winding pinion 4 at the level of the meshing portion 5. The toothed portion 7 is meshed with another element such as a wheel allowing the adjustment of the minutes (or another function, such as setting the date). The sliding pinion 6 is in the adjustment position (or second position), that is to say it allows a function of the watch to be adjusted, here the indication of the current time for example.

[0054] In Figure 2, the flexible structure 10 is shown in the second stable position. The transition from the first stable position to the second stable position is represented by arrows in Figure 2.

[0055] Thus, a translation of the rod 9 induces an antagonistic translation (i.e. in an opposite direction) of a part of the flexible structure 10, as will be detailed below with reference to the other figures.

Finally, the winding pinion 4 comprises a toothed portion 4d which can mesh with an opposite toothed portion 6d of the sliding pinion 6, at the level of the meshing portion 5.

The watch component may comprise a second flexible structure 20. The second flexible structure 20 is an example of a flexible structure.

The watch mechanism 100 comprises a first wheel 8a, a sliding wheel 8b and a second wheel 8c.

[0059] In the representation of Figure 3, the first flexible structure 10 is in the second stable position (as in Figure 2), and the second flexible structure 20 is in a first stable position of the second flexible structure 20. Thus , the user can reset the date by turning the crown 2, thanks to the meshing between the toothed portion 7 and the first wheel 8a.

The sliding pinion 6 is not meshed with the winding pinion 4 in Figure 3.

The sliding pinion 6 is meshed with the first wheel 8a at the level of the toothed portion 7 in Figure 3.

[0062] In the representation of Figure 4, thanks to an additional translation of the rod 9 due to user action, the first flexible structure 10 is in the second stable position (as in Figure 3), and the second flexible structure 20 is in a second stable position of the second flexible structure 20. Thus, the user can set the time by turning the crown 2, thanks to the meshing between the sliding pinion 8b (or sliding pinion 8b ) and the second wheel 8c.

The sliding pinion 6 is not meshed with the winding pinion 4 in Figure 4.

The sliding pinion 6 is meshed with the first wheel 8a at the level of the toothed portion 7 in Figure 4.

[0065] It is understood that the winding position (stable position) is the position in which the sliding pinion 6 meshes with the winding pinion 4 (that is to say the position in which the crown is most retracted). . The central position (stable position) is the position in which the user has pulled crown 2 and stem 9 once. The extreme stable position is the stable position beyond the central position, after the user has pulled even more on crown 2 and stem 9 (i.e. the position in which the crown is most extended).

[0066] The player 8b is arranged to drive the date ring (not shown) in the movement. The player 8b can carry a finger (or two fingers for example) which can drive the date ring step by step. Thus, in the second stable position of the second flexible structure 20, the player 8b no longer drives with the date ring.

[0067] In a particular embodiment, it is also possible to provide the first flexible structure 10 with three stable positions, instead of having the first flexible structure 10 with two stable positions and the second flexible structure 20 with two positions stable.

[0068] In another particular embodiment, it is also possible to provide for the second flexible structure 20 to pull the slider 8b instead of pushing it, during extraction of the crown 2. In other words, the translation is antagonistic for the first flexible structure 10 and the translation may or may not be antagonistic for the second flexible structure 20. Therefore, Figure 3 is a particular example.

[0069] Figure 5 represents an energy level of the first flexible structure 10 as a function of a movement of the first flexible structure 10. By movement of flexible structures is meant the movement of their flexible elements, and by stable positions the stable positions of their flexible elements.

[0070] The energy is represented on the ordinate (Y) and the displacement on the abscissa (X).

[0071] During a movement of the at least one flexible guide of the first flexible structure 10, the energy level can pass from the first stable position 1001 to the second stable position 1002, passing through a series of positions unstable, including an extreme unstable position 1100, of maximum energy. The series of unstable positions defines an unstable state

[0072] This makes it possible to switch from the first stable position to the second stable position. There is thus an energy barrier between the stable position 1001 and the unstable position 1100. The extreme unstable position 1100 can be a point of zero derivative. The positions between the extreme unstable position 1100 and the stable positions 1001 and 1002 may also be other unstable positions.

[0073] The energy level of the first flexible structure 10 is also similar, in principle, to the energy level of the second flexible structure 20.

[0074] Figure 6 represents the watch component with the sliding pinion 6 and the first flexible structure 10 in the first (stable) position of the first flexible structure 10.

The flexible structure 10 comprises the inlet portion 51 arranged to be integral, in translation, with the rod 9.

The flexible structure 10 comprises the output portion 52 distinct from the inlet portion 51 and arranged to be integral, in translation, with the sliding pinion 6.

The flexible structure 10 comprises flexible elements 54, 56 (for example flexible blades) and a nodal portion 53, also called carriage 53.

[0078] The first flexible elements 54 are arranged between the carriage 53 and each of the input portion 51 and the output portion 52. In other words, a flexible input blade is arranged between the portion of entrance 51 and carriage 53; and a flexible output blade is arranged between the output portion 52 and the carriage 53.

The inlet portion 51 can be engaged in a groove in the rod 9. The same goes for the outlet portion 52 which can be engaged in a groove in the sliding pinion 6. The inlet portion 51 and the output portion 52 are arranged on either side of the sliding pinion 6.

[0080] The second flexible joints 56 (also called basic flexible blades, here four flexible blades without being limited to this number) are arranged between the carriage 53 and a nodal portion 55 of the flexible structure 10. The nodal portion 55 can be integral with the plate 1 (or mobile, in the second flexible structure 20 as will be detailed below).

[0081] In Figure 6, the sliding pinion 6 is meshed with the winding pinion 4 and is not meshed with the first wheel 8a, which allows the winding of the barrel spring.

[0082] Concerning an example of the dimensions of the flexible blades 56, we can consider a length of the blades greater than ten times their width, which can be adapted according to the strokes and forces desired in the flexible structure. Regarding the materials, it can be considered that the flexible blades 56 (and generally the flexible portions), the flexible structures 10, 20, and the input and output portions 51, 52 can be made of silicon , titanium, aluminum, steel, bronze, or any suitable material, without being limited to those listed. With regard to manufacturing, the flexible blades 56 (and generally the flexible elements), the flexible structures 10, 20 and the input and output portions 51, 52 can be produced by additive manufacturing, growth, deep engraving, electroerosion laser cutting, LIGA, or any suitable process, without being limited to those listed. The general size of the flexible blades 56 (or flexible elements), the flexible structures 10, 20 and the inlet and outlet portions 51, 52 is typically 6 mm by 8 mm, with a thickness of 0.5 to 1.5 mm. , without being limited to these values. The typical actuation force on rod 9 is 2 to 15 N, but not limited to these values. The traction force of the rod 9 is greater than or equal to the pressure force of the rod 9. The stroke of the rod is typically 0.2 to 1.5 mm, without being limited to these values. The stroke of the sliding pinion is typically 0.2 to 0.5 mm, without being limited to these values.

[0083] Thus, the watch component here comprises the flexible structure 10 with the carriage 53, the flexible elements 54, the flexible joints 56, the entry and exit portions 51, 52 and the nodal portion 55.

[0084] In Figure 7, the sliding pinion 6 is not meshed with the winding pinion 4 and is meshed with the first wheel 8a at the toothed portion 7, which allows the adjustment of a function of the watch (e.g. date).

[0085] In Figure 7, the first stable position is shown in phantom and the second stable position is shown in strong lines. Piece movements are indicated by arrows.

[0086] In Figure 8, the sliding pinion 6 is meshed with the winding pinion 4 and is not meshed with the first wheel 8a, which allows the winding of the barrel spring.

[0087] In this embodiment, the watch component comprises the second flexible structure 20. The nodal portion 55 is no longer anchored or secured to the plate 1 but is mounted on the second flexible structure 20, via at least one flexible base articulation 57 (here four flexible blades without being limited to this number). The second flexible structure 20 comprises at least one flexible base articulation 57 and a base 58. The base 58 is integral with the plate 1. Thus, the nodal portion 55 acts as a carriage. The nodal portion 55 is thus guided in translation by the flexible base joints 57.

[0088] The watch component comprises another reference 11 and a date corrector 12.

[0089] The first wheel 8a is here a first gear and the other gear 11 is a timer gear. The first return can be returned by a return spring to return the return to the initial position when the rod 9 passes from the extreme position to the winding position; and to keep it in the central position and avoid disengagement of the transmission with the sliding pinion 6. The date corrector 12 is pivotally mounted relative to the plate 1 and meshes with the first wheel 8a in the central position, but no longer engages in the extreme position (the reference 8a then meshing with the other reference 11).

[0090] In Figure 9, the sliding pinion 6 meshes with the first wheel 8a and the first wheel 8a meshes with the date corrector 12.

[0091] In Figure 10, the sliding pinion 6 meshes with the first wheel 8a and the first wheel 8a meshes with the other gear.

[0092] In Figure 11, the base 58 is integral with the plate 1. The operation is similar to the above except for the angle of inclination.

[0093] The angle of inclination is chosen such that the movement of the control member 9 causes the translation of the elements 55, 56 and 53 via the flexible joints 54, without causing additional movement at the level of the sliding pinion 6 .

The additional translation movement is transmitted to the date corrector mobile (not shown here) but pivoted on the part 55 which meshes with the gear 8a and which meshes or not with another gear (not shown here).

[0095] In the central position, the sliding pinion 6 is already in abutment at the bottom of the teeth with the first gear 8a.

[0096] Figure 12 represents another embodiment of the first flexible structure 10, in the first position of the first flexible structure 10 (to the right of Figure 12) and in the second position of the first flexible structure 10 (at left of Figure 12).

[0097] In this embodiment, the first flexible structure 10 comprises the inlet 51 and outlet 52 portions as indicated previously.

The first flexible structure 10 further comprises an external portion 55 (twill) and an internal portion 53 (nodal portion). The first flexible structure 10 has an axis of rotation 59 centered on the internal portion 53.

The inlet portion 51 is arranged to enable the internal portion 53 to be actuated and the outlet portion 52 is arranged to enable the external portion 55 to be actuated. The internal portion 53 and the external portion 55 are connected pivot with the plate not shown.

[0100] The flexible elements 54 are pre-stressed flexible blades which make it possible to define two stable positions (as illustrated on the left and right of Figure 12) and at least one unstable position between them. These stable positions allow antagonistic translation as explained previously.

[0101] Stops (not shown) are positioned to allow one of the parts (53) or (55) to pivot at an angle sufficient to cross the energy barrier, causing the other part to pivot, until then at the stop, in the opposite direction of rotation, to reach the second stable position.

[0102] Figure 13 represents a second embodiment with the watch component having the sliding pinion 6 and the first flexible structure 10, in the first (stable) position of the first flexible structure 10.

[0103] In this position, the sliding pinion 6 meshes with the winding pinion 4 in order to allow winding.

[0104] In the position of Figure 14, the sliding pinion 6 meshes with the first wheel 8a in order to allow the adjustment of a function of the watch (for example date).

[0105] In the position of Figure 15, the sliding pinion 6 meshes with the winding pinion 4 in order to allow winding.

[0106] In Figure 16, the second flexible structure 20 is interposed: the parts 53 and 55 of the first flexible structure 10 are pivotally mounted relative to the second flexible structure 20 at the level of the axis 59, on a plate 61. This plate 61 translates between two stable positions relative to the plate 1 (not shown) by means of bistable blades 62 relative to the base part 63, secured to the plate 1.

[0107] In this position, the sliding pinion 6 meshes with the first wheel 8a.

[0108] The first wheel 8a meshes with the date corrector 12.

[0109] In Figure 17, the flexible blades 62 buckle in order to allow passage between the first stable position and the second stable position of the blades of the second flexible structure 20. In fact, by being compressed in the longitudinal direction, a buckling of the flexible blades 62 appears, which is also valid for the other figures and embodiments. Thus, in particular with reference to Figure 12 but this can apply to other embodiments, there is an inversion of curvature between the first position and the second position for the blades 54.

[0110] The user's action on the crown 2 and the rod 9 from the central position activates the bistable blades 62 which engage in their second stable position.

[0111] The second flexible structure 20 is in a stable position and is held in this position by means of stops (not shown).

[0112] By means of stops and/or a cam at the end of the output portion 52 in contact with the groove of the sliding pinion 6, there is no additional movement at the level of the sliding pinion 6.

[0113] The first flexible structure 10 and the second flexible structure 20 can be one and the same monolithic structure, forming a single flexible structure.

[0114] The additional translation movement is transmitted to the date corrector mobile 12 (pivoting on the plate 61 at the level of the axis 64) which meshes with the gear 8a and which meshes or not with another gear 11.

[0115] Figure 18 represents an alternative embodiment with a flexible guide, in which the flexible guide replaces the flexible blade. Figure 18 represents an alternative embodiment with a conventional mechanical connection assembly capable of achieving the desired kinematics at the level of portion 154. Those skilled in the art will be able to translate this kinematic principle diagram composed of conventional mechanical connections into flexible guidance composed flexible joints.

[0116] The reference numbers are repeated as much as necessary with reference to the previous embodiments.

[0117] The flexible structure 10 comprises the output portion 52 distinct from the inlet portion 51 and arranged to be integral, in translation, with the sliding pinion 6, as indicated previously.

[0118] The second flexible joints 56 (also called basic flexible blades, here four flexible blades without being limited to this number) are arranged between the carriage 53 (nodal portion) and the nodal portion 55 of the flexible structure 10. The portion nodal 55 can be integral with the plate 1 or mobile, in the second flexible structure 20 as detailed above.

[0119] The alternative concerns flexible guides 154 in place of the flexible blades 54 mentioned above, for example with reference to Figures 6 and 7.

[0120] Finally, note that it is also possible to provide as flexible elements flexible rods, flexible wires or torsion bars, or even circular necks, without being limited to these examples, and as flexible joints of tables in translation or flexible pivots.

[0121] It will be understood that various modifications and/or improvements obvious to those skilled in the art can be made to the different embodiments of the invention described in the present description.

[0122] In particular, reference is made to the possibility of providing several flexible structures, another arrangement of flexible blades or other watch functions to be adjusted. It is also possible to change the order of the positions and set functions of the watch, as well as to change the functions set on the watch.

Claims (10)

1. Watch component for watch mechanism (100), the mechanism (100) comprising a control member (9) and a transmission member (6), in which the transmission member (6) is movable between a winding position and at least one adjustment position, in which the watch component comprises a flexible structure (10) with: – an input portion arranged (51) to be integral, in translation, with the control member (9), – an output portion (52) distinct from the input portion (51) and arranged to be integral, in translation, with the transmission member (6), and – at least one flexible element (54, 56) arranged to pass reversibly from a first stable position, in which the transmission member (6) is in the winding position, towards a second stable position in which the transmission member (6) is in the adjustment position, passing through an unstable position. 2. Watch component according to the preceding claim, further comprising a nodal portion (53) arranged to carry at least one flexible portion (54, 56). 3. Watch component according to the preceding claim, in which the at least one flexible portion comprises a plurality of flexible elements, and in which – at least one flexible inlet portion, such as a flexible inlet blade or a flexible inlet pivot or a flexible inlet guide, is arranged between the inlet portion (51) and the nodal portion ( 53), – at least one flexible outlet portion, such as a flexible outlet blade or a flexible outlet pivot or a flexible outlet guide, is arranged between the outlet portion (52) and the nodal portion (53), and – optionally, at least one flexible base portion (56), such as a table with flexible base blades, is arranged between a first nodal portion (53) and a second nodal portion (55). 4. Watch component according to the preceding claim, further comprising a base (58), in which the second nodal portion (55) is arranged between the first nodal portion (53) and the base (58), and in which the plurality of flexible elements further comprises at least one flexible base element (57) arranged between the base (58) and the nodal portion (55). 5. Watch component according to the preceding claim, in which the nodal portion (53) has a first translation axis and a second translation axis. 6. Watch component according to one of the preceding claims, in which the transmission member is a sliding pinion (6), – the inlet portion (51) is engaged in a groove of the control member (9), and – the output portion (52) is engaged in a groove of the sliding pinion (6). 7. Watch component according to one of the preceding claims, further comprising another flexible structure (20) having at least one other flexible portion arranged between a nodal portion (55) of the flexible structure and a fixed portion, such as a platinum. 8. Watch component according to one of the preceding claims, wherein the at least one flexible portion (54, 56) is prestressed. 9. Watch component according to one of the preceding claims, wherein the flexible structure (10) is monolithic. 10. Watch component according to one of claims 1 to 3, and 6 to 9, in which the flexible structure (10) comprises an internal portion (53) and an external portion (55), and in which the inlet portion (51) is integral with one of the internal portion (53) and the external portion (55); And the outlet portion (52) is integral with the other of the internal portion (53) and the external portion (55).