EP3483668A1 - System for securing a clock movement in a watch case - Google Patents

Abstract

System (10) for fixing a watch movement (2) to a watch-case element (3) (30), the system comprising at least one flange (1), in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement on the one hand and with the watch case element on the other hand, the at least one flange being made of a superelastic alloy and / or a memory alloy of form, especially a nickel-titanium alloy such as Nitinol.

Description

The invention relates to a system for fixing a watch movement to a watch case element. The invention also relates to a watch assembly comprising such a system. The invention also relates to a timepiece comprising such a system or such an assembly. The invention finally relates to a method of operating such a system or such a set or such a timepiece.

Two or three casing flanges are generally used for assembling or fixing a watch movement within a watch case, in particular within a caseband.

When assembling the movement within the box, each casing flange is inserted into a cutout formed on the inner circumference of the middle part and then fixed to the movement by means of a fixing means.

This cut can in particular be shaped so that the flange can induce an adequate prestressing force, which allows to press the movement against the middle part of the box in order to meet predefined criteria. A criterion may, for example, be a minimization of the movement of the movement amplitude for a given shock intensity, as well as a given flange geometry and material, without risk of plasticizing the flanges.

The Figures 1 and 2 illustrate a construction of such a flanged casing device. At least one flange 1 * is pressed against flat surfaces 2a *, 3a * and parallel, which are respectively associated to a movement 2 * and to a middle 3 * of a box 30 *. The flange 1 * is thus elastically deformed during the assembly of the movement so that the elastic restoring force of the flange maintains a surface 2b * of the movement 2 * against a surface 3b * of the middle part * 3. The holding of the flange on the movement is here ensured by a screw 4 *.

However, such a solution can cause problems. There is indeed a risk of plastification of the flanges during assembly and / or under the effect of a shock. This can lead to a loss of unwanted contact with the movement and the middle part, or even the risk of undesirable disassembly of the flanges.

The object of the invention is to provide a watch movement fixing system in a watch case to overcome the disadvantages mentioned above and to improve the devices known from the prior art. In particular, the invention proposes a fastening system whose reliability and robustness is improved relative to the known systems of the prior art.

1. 1. Système de fixation d'un mouvement horloger à un élément de boîte de montre, le système comprenant :
   • au moins une bride, en particulier au moins deux brides, de préférence trois brides ou quatre brides, destinée à venir en contact avec le mouvement d'une part et avec l'élément de boîte de montre d'autre part, et
   • un dispositif de modification de la rigidité de l'au moins une bride, notamment de modification de la rigidité de flexion de l'au moins une bride, lorsque le mouvement est fixé et/ou déplacé relativement à l'élément de boîte de montre.
2. 2. Système selon la définition 1, caractérisé en ce que le dispositif de modification de la rigidité de l'au moins une bride est agencé de sorte que la longueur fléchie de l'au moins une bride est modifiée, notamment de sorte que la longueur fléchie de l'au moins une bride est diminuée, lorsque le mouvement est fixé à l'élément de boîte de montre ou déplacé relativement à l'élément de boîte de montre depuis une position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte.
3. 3. Système selon la définition 1 ou 2, caractérisé en ce que l'appui ou le contact d'une première extrémité fléchie de l'au moins une bride à l'encontre du mouvement et/ou l'appui ou le contact d'une deuxième extrémité fléchie de l'au moins une bride à l'encontre de l'élément de boîte est (sont) modifié lorsque le mouvement est fixé à l'élément de boîte de montre ou déplacé relativement à l'élément de boîte de montre depuis une position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte.
4. 4. Système selon l'une des définitions 1 à 3, caractérisé en ce que le dispositif de modification de la rigidité de l'au moins une bride comprend, à l'état fixé du mouvement à l'élément de boîte et le mouvement se trouvant en position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte, un premier jeu entre la bride et un point du mouvement contre lequel la bride peut venir en contact par flexion de la bride, la valeur du premier jeu étant inférieure à Lc1, voire inférieure à Lc1/3, voire inférieure à Lc1/4 et/ou la valeur du premier jeu est supérieure à Lc1/60, voire supérieure à Lc1/30, avec Lc1 étant la longueur d'une projection dans le plan du mouvement d'une troisième surface contre laquelle la bride peut venir en appui et la longueur Lc1 étant comprise entre Lf/10 et Lf avec Lf étant la longueur de bride fléchie, et/ou en ce que le dispositif de modification de la rigidité de l'au moins une bride comprend, à l'état fixé du mouvement à l'élément de boîte et le mouvement se trouvant en position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte, un deuxième jeu entre la bride et un point de l'élément de boîte contre lequel la bride peut venir en contact par flexion de la bride, la valeur du deuxième jeu étant inférieure à Lc2, voire inférieure à Lc2/3, voire inférieure à Lc2/4 et/ou la valeur du deuxième jeu est supérieure à Lc2/60, voire supérieure à Lc2/30, avec Lc2 étant la longueur d'une projection dans le plan du mouvement d'une cinquième surface contre laquelle la bride peut venir en appui et la longueur Lc2 étant comprise entre Lf/10 et Lf avec Lf mesurée à l'état de repos.
5. 5. Système selon l'une des définitions 1 à 4, caractérisé en ce que le dispositif de modification de la rigidité de l'au moins une bride comprend :
   • une troisième surface formant un premier angle non nul avec un quatrième surface contre laquelle la bride est en appui lorsque le mouvement est dans une position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte, et/ou
   • une cinquième surface formant un deuxième angle non nul avec une sixième surface contre laquelle la bride est en appui lorsque le mouvement est dans une position de repos dans laquelle une première surface du mouvement est en contact contre une deuxième surface de l'élément de boîte.
6. 6. Système selon la définition 5, caractérisé en ce que le premier angle est inférieur à 45°, voire inférieur à 20°, voire inférieur à 15°, voire inférieur à 10° et/ou est supérieur à 1°, voire supérieur à 2° et/ou en ce que le deuxième angle est inférieur à 45°, voire inférieur à 20°, voire inférieur à 15°, voire inférieur à 10° et/ou est supérieur à 1°, voire supérieur à 2°.
7. 7. Système selon la définition 5 ou 6, caractérisé en ce que la première surface est plane et/ou en ce que la deuxième surface est plane et/ou en ce que la troisième surface est plane et/ou en ce que la quatrième surface est plane et/ou en ce que la cinquième surface est plane et/ou en ce que la sixième surface est plane.
8. 8. Système selon la définition 5 ou 6, caractérisé en ce que la troisième surface est bombée, notamment la troisième surface est une portion de cylindre, et/ou en ce que la cinquième surface est bombée, notamment la cinquième surface est une portion de cylindre.
9. 9. Système selon l'une des définitions 1 à 8, caractérisé en ce que l'au moins une bride comprend une section transversale dont le moment quadratique évolue selon un axe longitudinal, notamment par évolution de la largeur et/ou de l'épaisseur et/ou de sorte que la section transversale est telle que le profil des contraintes maximales est constant ou au moins sensiblement constant sur au moins une partie de la longueur de l'au moins une bride, notamment sur au moins la moitié de la longueur de ladite bride.
10. 10. Système selon l'une des définitions 1 à 9, caractérisé en ce que l'au moins une bride est en un alliage superélastique et/ou en un alliage à mémoire de forme, notamment en un alliage nickel-titane tel que le Nitinol ou en ce que l'au moins une bride est en un alliage de nickel.
11. 11. Système selon l'une des définitions 1 à 10, caractérisé en ce que l'au moins une bride comprend un élément de fixation au mouvement ou à l'élément de boîte, notamment un trou de passage de vis.
    Selon le premier aspect de l'invention, un ensemble horloger est déterminé par les définitions qui suivent.
12. 12. Ensemble horloger, notamment mouvement horloger et/ou élément de boîte de montre ou boîte de montre, comprenant un système selon l'une des définitions 1 à 11.
13. 13. Ensemble horloger selon la définition 12, caractérisé en ce que l'élément de boîte de montre est une carrure.
14. 14. Ensemble horloger selon la définition 12 ou 13, caractérisé en ce que la troisième surface est réalisée sur le mouvement et/ou en ce que la quatrième surface est réalisée sur l'élément de boîte.
15. 15. Ensemble horloger selon la définition 12 ou 13, caractérisé en ce que l'élément de boîte comprend un cercle d'emboîtage et/ou en ce que la quatrième surface est réalisée au moins en partie sur un cercle d'emboîtage ou en ce que le mouvement comprend un cercle d'emboîtage et/ou en ce que la troisième surface est réalisée au moins en partie sur un cercle d'emboîtage.
    Selon le premier aspect de l'invention, une pièce d'horlogerie est déterminée par la définition qui suit.
16. 16. Pièce d'horlogerie, notamment montre bracelet, comprenant un ensemble selon l'une des définitions 12 à 15 et/ou ou un système selon l'une des définitions 1 à 11.
    Selon un deuxième aspect de l'invention, un système de fixation d'un mouvement horloger est déterminé par les définitions qui suivent.
17. 17. Système de fixation d'un mouvement horloger à un élément de boîte de montre, le système comprenant au moins une bride, en particulier au moins deux brides, de préférence trois brides ou quatre brides, destinée à venir en contact avec le mouvement d'une part et avec l'élément de boîte de montre d'autre part, l'au moins une bride étant en un alliage superélastique et/ou en un alliage à mémoire de forme, notamment en un alliage nickel-titane tel que le Nitinol.
18. 18. Système selon la définition 17, caractérisé en ce que l'au moins une bride comprend une section transversale dont le moment quadratique évolue selon un axe longitudinal, notamment par évolution de la largeur et/ou de l'épaisseur et/ou de sorte que la section transversale est telle que le profil des contraintes maximales est constant ou sensiblement constant sur au moins une partie de la longueur de l'au moins une bride, notamment sur au moins la moitié de la longueur de la bride.
19. 19. Système selon l'une des définitions 17 à 18, caractérisé en ce que l'au moins une bride comprend un élément de fixation au mouvement ou à l'élément de boîte de montre, notamment un trou de passage de vis.
20. 20. Système selon l'une des définitions 17 à 19, caractérisé en ce que l'épaisseur de l'au moins une bride est supérieure ou égale à 0,5 mm.
21. 21. Système selon l'une des définitions 17 à 20, caractérisé en ce que la longueur fléchie de l'au moins une bride est inférieure ou égale à 1,35 mm.
    Selon le deuxième aspect de l'invention, un ensemble horloger est déterminé par la définition qui suit.
22. 22. Ensemble horloger, notamment mouvement horloger ou élément de boîte de montre, comprenant un système selon l'une des définitions 17 à 21.
    Selon le deuxième aspect de l'invention, une pièce d'horlogerie est déterminée par la définition qui suit.
23. 23. Pièce d'horlogerie, notamment montre bracelet, comprenant un ensemble selon la définition 22 et/ou ou un système selon l'une des définitions 17 à 21.

According to a first aspect of the invention, a system for fixing a watch movement is determined by the following definitions.

1. A system for attaching a watch movement to a watch case element, the system comprising:
   • at least one flange, in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement on the one hand and with the watch case element on the other, and
   • a device for modifying the rigidity of the at least one flange, in particular for modifying the flexural stiffness of the the at least one flange, when the movement is fixed and / or displaced relative to the watch case element.
2. 2. System according to definition 1, characterized in that the device for modifying the rigidity of the at least one flange is arranged so that the bent length of the at least one flange is modified, in particular so that the length flexed of the at least one flange is decreased, when the motion is attached to the watch case member or moved relative to the watch case member from a rest position in which a first surface of the movement is in contact against a second surface of the box element.
3. 3. System according to definition 1 or 2, characterized in that the support or the contact of a first end bent of the at least one flange against the movement and / or the support or the contact of a bent second end of the at least one flange against the box member is (are) modified when the movement is attached to the watch case member or moved relative to the watch case member from a rest position in which a first surface of the movement is in contact with a second surface of the box member.
4. 4. System according to one of the definitions 1 to 3, characterized in that the device for modifying the rigidity of the at least one flange comprises, in the fixed state of movement to the box element and the movement is in the rest position in which a first surface of the movement is in contact against a second surface of the box member, a first clearance between the flange and a point of the movement against which the flange can come into contact by bending the flange , the value of the first game being less than Lc1, or even lower than Lc1 / 3, or even lower than Lc1 / 4 and / or the value of the first set is greater than Lc1 / 60, or even greater than Lc1 / 30, with Lc1 being the length of a projection in the plan of the movement of a third surface against which the flange can come into abutment and the length Lc1 being between Lf / 10 and Lf with Lf being the flange length bent, and / or in that the rigidity modification device of the at least one flange comprises, in the fixed state of movement to the box member and the movement being in the rest position in which a first surface of the movement is in contact with a second surface of the element of box, a second clearance between the flange and a point of the box member against which the flange can come into contact by bending the flange, the value of the second set being lower than Lc2, or even lower than Lc2 / 3, or lower at Lc2 / 4 and / or the value of the second I u is greater than Lc2 / 60, or even greater than Lc2 / 30, with Lc2 being the length of a projection in the plane of movement of a fifth surface against which the flange can come into abutment and the length Lc2 being between Lf And Lf with Lf measured at rest.
5. 5. System according to one of the definitions 1 to 4, characterized in that the device for modifying the rigidity of the at least one flange comprises:
   • a third surface forming a first non-zero angle with a fourth surface against which the flange bears when the motion is in a rest position in which a first surface of the movement is in contact with a second surface of the can element, and or
   • a fifth surface forming a second non-zero angle with a sixth surface against which the flange is supported when the movement is in a rest position in which a first surface of the movement is in contact with a second surface of the box member.
6. 6. System according to definition 5, characterized in that the first angle is less than 45 °, or even less than 20 °, or even less than 15 °, or even less than 10 ° and / or is greater than 1 °, or even greater than 2 ° and / or in that the second angle is less than 45 °, or even less than 20 °, or even less than 15 °, or even less than 10 ° and / or is greater than 1 °, or even greater than 2 °.
7. 7. System according to definition 5 or 6, characterized in that the first surface is flat and / or in that the second surface is flat and / or in that the third surface is plane and / or in that the fourth surface is planar and / or in that the fifth surface is planar and / or in that the sixth surface is flat.
8. 8. System according to definition 5 or 6, characterized in that the third surface is curved, in particular the third surface is a cylinder portion, and / or in that the fifth surface is curved, in particular the fifth surface is a portion of cylinder.
9. 9. System according to one of the definitions 1 to 8, characterized in that the at least one flange comprises a cross section whose quadratic moment evolves along a longitudinal axis, in particular by evolution of the width and / or the thickness. and / or so that the cross section is such that the profile of the maximum stresses is constant or at least substantially constant over at least a part of the length of the at least one flange, in particular over at least half the length of the said flange.
10. 10. System according to one of the definitions 1 to 9, characterized in that the at least one flange is a superelastic alloy and / or a shape memory alloy, in particular a nickel-titanium alloy such as Nitinol or in that the at least one flange is made of a nickel alloy.
11. 11. System according to one of the definitions 1 to 10, characterized in that the at least one flange comprises a fastening element to the movement or to the box member, in particular a screw hole.
    According to the first aspect of the invention, a watch assembly is determined by the following definitions.
12. 12. Watchmaking assembly, in particular a watch movement and / or a watch case element or a watch case, comprising a system according to one of the definitions 1 to 11.
13. Clock set according to definition 12, characterized in that the watch case element is a middle part.
14. 14. Watchmaking assembly according to definition 12 or 13, characterized in that the third surface is formed on the movement and / or in that the fourth surface is formed on the box element.
15. 15. Clock assembly according to definition 12 or 13, characterized in that the box element comprises a casing ring and / or in that the fourth surface is made at least partly on a casing ring or in that that the movement comprises a casing ring and / or in that the third surface is made at least partly on a casing ring.
    According to the first aspect of the invention, a timepiece is determined by the following definition.
16. 16. Timepiece, in particular a wristwatch, comprising an assembly according to one of the definitions 12 to 15 and / or or a system according to one of the definitions 1 to 11.
    According to a second aspect of the invention, a system for fixing a watch movement is determined by the following definitions.
17. 17. A system for fixing a watch movement to a watch case element, the system comprising at least one flange, in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement of the watch. on the one hand and with the watch case element on the other hand, the at least one flange being made of a superelastic alloy and / or a shape memory alloy, in particular a nickel-titanium alloy such as Nitinol .
18. 18. System according to definition 17, characterized in that the at least one flange comprises a cross section whose quadratic moment evolves along a longitudinal axis, in particular by evolution of the width and / or thickness and / or of the cross section is such that the profile of the maximum stresses is constant or substantially constant over at least a part of the length of the at least one flange, in particular over at least half the length of the flange.
19. 19. System according to one of the definitions 17 to 18, characterized in that the at least one flange comprises a fastening element at movement or to the watch case element, including a screw hole.
20. 20. System according to one of the definitions 17 to 19, characterized in that the thickness of the at least one flange is greater than or equal to 0.5 mm.
21. 21. System according to one of the definitions 17 to 20, characterized in that the bent length of the at least one flange is less than or equal to 1.35 mm.
    According to the second aspect of the invention, a watch ensemble is determined by the following definition.
22. 22. Watchmaking assembly, in particular a watch movement or a watch case element, comprising a system according to one of definitions 17 to 21.
    According to the second aspect of the invention, a timepiece is determined by the following definition.
23. 23. Timepiece, in particular a wristwatch, comprising an assembly according to definition 22 and / or a system according to one of definitions 17 to 21.

Unless logical or technical incompatibility, any combination of the features of the first and second aspects can be achieved.

• Les figures 1 et 2 sont des vues en coupe d'un assemblage connu de l'art antérieur.
• Les figures 3 et 4 sont des vues d'un premier mode de réalisation d'une pièce d'horlogerie dans deux états.
• Les figures 5 et 6 sont des vues d'un deuxième mode de réalisation d'une pièce d'horlogerie dans deux états.
• La figure 7 est une vue en perspective de détail d'une première géométrie de bride pouvant être utilisée dans un système de fixation selon l'invention.
• La figure 8 est un tableau récapitulatif illustrant le comportement de brides de même géométrie dans différents modes de réalisation.
• La figure 9 est un graphique illustrant les comportements de systèmes de de fixation de la figure 8 lorsque le mouvement est déplacé relativement à la boîte.
• La figure 10 est une vue en perspective de détail d'une deuxième géométrie de bride pouvant être utilisée dans un système de fixation selon l'invention.
• La figure 11 est une vue en coupe longitudinale d'une troisième géométrie de bride pouvant être utilisée dans un système de fixation selon l'invention.
• Les figures 12 et 13 sont des vues de détail d'exemples de géométries de surfaces de mouvement destinées à coopérer avec des brides.
• La figure 14 est une vue d'un troisième mode de réalisation d'une pièce d'horlogerie dans un état de repos.
• Les figures 15 à 17 sont des graphiques représentant des efforts de rappel d'un mouvement en fonction de son déplacement relativement à une boîte pour différents types de brides.

The appended figures represent, by way of example, two embodiments of a timepiece according to the invention.

• The Figures 1 and 2 are sectional views of an assembly known from the prior art.
• The figures 3 and 4 are views of a first embodiment of a timepiece in two states.
• The figures 5 and 6 are views of a second embodiment of a timepiece in two states.
• The figure 7 is a detailed perspective view of a first flange geometry that can be used in a fastening system according to the invention.
• The figure 8 is a summary table illustrating the behavior of flanges of the same geometry in different embodiments.
• The figure 9 is a graph illustrating the behaviors of fastening systems of the figure 8 when the movement is moved relative to the box.
• The figure 10 is a detailed perspective view of a second flange geometry that can be used in a fastening system according to the invention.
• The figure 11 is a longitudinal sectional view of a third flange geometry that can be used in a fastening system according to the invention.
• The figures 12 and 13 are detail views of exemplary motion surface geometries for cooperating with flanges.
• The figure 14 is a view of a third embodiment of a timepiece in a state of rest.
• The Figures 15 to 17 are graphs representing recall efforts of a movement as a function of its displacement relative to a box for different types of flanges.

A first embodiment of a timepiece 400 is described below with reference to the figures 3 and 4 . The timepiece is for example a watch, in particular a wristwatch. The timepiece comprises a watch case or a watch case comprising a caseband 3. The watch case 30 contains a watch movement 2. The movement may be a mechanical movement or an electronic movement.

The watch movement 2 and / or an element 3 of the watch case and / or the watch case 30 may constitute or be part of a watch assembly 200 comprising or participating in a system 10 for fastening the watch movement 2 to the watch. watch box element 3. The watch case element may for example be a middle or an enlargement circle.

• au moins une bride 1, en particulier au moins deux brides, de préférence trois brides ou quatre brides, destinée à venir en contact avec le mouvement d'une part et avec l'élément de boîte de montre d'autre part, et
• un dispositif 2a' de modification de la rigidité de l'au moins une bride, notamment de modification de la rigidité de flexion de l'au moins une bride, lors de la fixation du mouvement à l'élément de boîte et/ou lorsque le mouvement est déplacé relativement à l'élément de boîte de montre.

The system 10 for fixing the watch movement 2 to the watch case element 3 comprises:

• at least one flange 1, in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement on the one hand and with the watch case element on the other, and
• a device 2a 'for modifying the rigidity of the at least one flange, in particular for modifying the bending rigidity of the at least one flange, when fixing the movement to the element of box and / or when the movement is moved relative to the watch case element.

The system has the particularity of implementing elastic casing flanges whose stiffnesses are likely to vary according to the stresses applied to them, in particular during the movement of the watch movement opposite the watch case in the event of impact. or when assembling the movement to the box. In another aspect, the system has the particularity of implementing a particularly rigid casing and insensitive to variations in manufacturing and / or assembly tolerances. Such an embodiment has the advantage of providing a perennial fastening system, which avoids in particular the risk of plastic deformation of the flanges involved in the assembly and / or the risk of inadvertent disassembly of the fastening means of said flanges, especially in case of shock of the watch.

The rigidity of a flange can be characterized by the intensity of its arrow following a request or a given effort. It is possible to modulate the rigidity of a flange by modifying its active length and / or by modifying its points or bearing surfaces during its loading. The rigidity modification device exploits this possibility.

The device for modifying the stiffness of the at least one flange is preferably arranged so that the bent length of the at least one flange is modified, in particular so that the bent length of the at least one flange is reduced. when the movement is attached to the watch case member or moved relative to the watch case member from a rest position in which a first movement surface 2b is in contact with a second surface 3b of the element of box. The first surface 2b is for example a face of the movement. The second surface 3b is for example a bearing surface made in the box, for example in the middle part.

In the assembled state of movement in the box, at least one flange 1 is pressed against a surface 2A of the movement. The at least one flange bears against a surface 3A of the box, in particular against one end of a surface 3A of the box. The surface 3A is for example a range of a cutout 31 or a recess 31 made in the box element, especially in the middle part. The flange 1 is thus deformed elastically during the assembly of the movement so that the elastic restoring force of the flange maintains the surface 2b of the movement 2 against the surface 3b of the box 3. The holding the flange on the movement is here ensured by a screw 4. The screw 4 is for example screwed into a tapping provided in the movement. The screw passes through a hole 14 formed in the flange 1. The head of the screw bears against a surface of the flange 1. The first and second surfaces 2b and 3b are for example planar. They are preferably perpendicular to an axis A1 of the movement. This axis A1 is perpendicular to a plane of the movement, in particular to a plane of a frame of the movement and / or the axis A1 is parallel to the direction in which the movement is introduced into the element 3 of the watch case.

The active bending length Lf of the flange corresponds to a limited portion of the total length L of the flange. The active bending length Lf extends between a first zone forming a first bent end 12 and a second zone forming a second bent end 13. The first end 12 is at the limit of contact between the movement and the flange. The second end 13 is at the contact limit between the box and the flange. The length La is the length of the flange which bears on the movement. This length can possibly discontinuous. It extends between the extreme limits where the flange 1 bears on the movement.

In the first embodiment, the bearing surface 2A of the movement comprises at least a portion 2a 'of surface forming an angle α with the frame of the movement. This portion 2a 'is adjacent to a portion 2a against which the screw 4 plates the flange against the frame of the movement. The portion 2a is for example flat. Thus, the surface portion 2a 'forms the non-zero angle α with the portion 2a against which the flange bears when the movement is in a rest position in which the first surface 2b of the movement is in contact against the second surface 3b of the box element.

During the assembly of the movement 2 within the box 30, the flange 1 is elastically deformed by contact with all or part of the surface 3A under the action of the screw 4. The flange is elastically deformed over an axial distance interference corresponding to the interference of material between the flange and the box before elastic deformation of the flange. Once the movement is engaged, the flange is pressed against the surface 2A and maintained in pre-tensioned state by means of the screw 4. In the various configurations, the bending length Lf of the flange is defined in particular. by the geometry of the surface 2A. Within the specific construction illustrated on the figure 3 , Lf ~ La / 1.5, which gives the flange a first stiffness it keeps until the flange comes into contact with the portion 2a ', especially during a shock whose intensity is greater than one given threshold value. When this threshold value is reached, as shown on the figure 4 the movement is moved axially by a distance d relative to the box. As a result, the flange comes into contact with the portion 2a '. This contact modifies the points of support of the flange, which makes it possible in particular to increase the restoring force of the flange while obviating its plastic deformation, in particular by a minimized axial displacement of the movement due to the increase of the return force. The geometry of the portion 2a 'thus gives the flange at least a second stiffness that it is likely to retain until the return of the elastic restoring force of said flange, either as long as the flange is in contact with the flange. portion 2a '. Moreover, the portion 2a 'makes it possible to distribute the stresses over a larger surface area of the flange and thus avoids the concentrations of stresses that are too large, which may exceed the elastic limit of the material in which the flange is made.

When going through the configuration of the figure 3 to that of the figure 4 , the bending length Lf of the flange may vary, it may especially be between La / 4 ( figure 4 ) and La / 1.5 ( figure 3 ). In particular, the length Lf here is likely to vary abruptly from La / 1.5 to La / 4 between the configuration of the figure 3 and the configuration of the figure 4 . The mode of stresses of the flange is also likely to be changed abruptly by moving from a similar configuration to that of a recessed beam to a configuration similar to that of a beam in four-point flexion.

The angle α is preferably strictly less than 45 °, or even less than 20 °, or even less than 15 °, or even less than 10 °. This angle α is preferably greater than 1 °, especially greater than 2 °. Thus, the portion 2a 'must be distinguished from a simple chamfer resulting from the manufacture of the surface 2A. The portion 2a 'may, moreover, occupy all or part of the surface 2A.

Of course, it is possible to press the flange against the portion 2a 'from the assembly, that is to say during assembly or when fixing the movement within the box, to know when the distance of separating the movement and the box is zero. Such a configuration has the advantage of increasing the restoring force produced by the flange as soon as the movement is assembled, and without generating stresses likely to cause residual deformation of the flange.

Thus, the support or the contact of the bent first end 12 of the flange against the movement is changed when the movement is attached to the watch case member or moved relative to the watch case element from a rest position in which the first surface 2b of the movement is in contact against the second surface 3b of the box member.

In this first embodiment, the device for modifying the rigidity of the at least one flange comprises the portion 2a '. The portion 2a 'is for example flat.

A second embodiment of a timepiece 400 is described below with reference to figures 5 and 6 . According to the second embodiment, the timepiece can differ from that of the first mode only by the device for modifying the rigidity of the at least one flange.

In the second embodiment, the bearing surface 3A of the box comprises at least one portion 3a 'of surface forming an angle β with the frame of the movement or with a plane perpendicular to the axis A1 of the movement. This portion 3a 'is adjacent to a portion 3a against which the flange rests in the rest position of the movement or during fixation of the movement in the box. The portion 3a is for example flat and is for example perpendicular to the axis A1 of the movement. Thus, the portion 3a 'of surface 3A forms an angle β with the portion 3a of surface 3A.

During the assembly of the movement 2 within the box 30, the flange 1 is elastically deformed by contact with all or part of the surface 3A under the action of the screw 4. The flange is elastically deformed over an axial distance interference corresponding to the interference of material between the flange and the box before elastic deformation of the flange. Once the movement is engaged, the flange is pressed against the surface 2A and maintained in pre-tensioned state by means of the screw 4. In the various configurations, the bending length Lf of the flange is defined in particular. by the geometry of the surface 3A. Within the specific construction illustrated on the figure 5 , Lf ~ La / 2.5, which gives the flange a first stiffness it keeps until the flange comes into contact with the portion 3a ', especially during a shock whose intensity is greater than one given threshold value. When this threshold value is reached, as shown on the figure 6 the movement is moved axially by a distance d relative to the box. As a result, the flange comes into contact with the portion 3a '. This contact modifies the points of support of the flange, which makes it possible in particular to increase the restoring force of the flange while obviating its plastic deformation, in particular by a minimized axial displacement of the movement due to the increase in the restoring force. The geometry of the portion 3a 'thus gives the flange at least a second stiffness that it is likely to retain until the return of the elastic restoring force of said flange, either as long as the flange is in contact with the flange. portion 3a '.

When going through the configuration of the figure 5 to that of the figure 6 , the bending length Lf of the flange may vary, it may especially be between La / 4 ( figure 6 ) and La / 2.5 ( figure 5 ). In particular, the length Lf is here likely to vary from La / 2.5 to La / 4 between the configuration of the figure 5 and the configuration of the figure 6 . The angle β is preferably strictly less than 45 °, or even less than 20 °, or even less than 15 °, or even less than 10 °. This angle β is preferably greater than 1 °, especially greater than 2 °. Thus, the portion 3a 'must be distinguished from a simple chamfer resulting from the manufacture of the surface 3A. The portion 3a 'may, moreover, occupy all or part of the surface 3A.

Of course, it is possible to press the flange against the portion 3a 'from the assembly of the movement within the box, namely when the distance d between the movement and the box is zero. Such a configuration has the advantage of increasing the restoring force produced by the flange as soon as the movement is assembled, and without generating stresses likely to cause residual deformation of the flange.

Thus, the support or contact of the bent second end 13 of the flange against the box member is changed when the movement is attached to the watch case member or moved relative to the box member. watch case from a rest position in which the first surface 2b of the movement is in contact against the second surface 3b of the box member.

In this second embodiment, the device for modifying the rigidity of the at least one flange comprises the portion 3a '. The portion 3a 'is for example flat.

A third embodiment of a timepiece 400 is described below. This mode is represented on the figure 14 . It combines the first embodiment and the second embodiment. Thus, in this third embodiment, the device for modifying the rigidity of the at least one flange comprises a portion inclined on the movement intended to cooperate with the at least one flange (especially as the portion 2a 'of the first embodiment shown on the figures 3 and 4 ) and an inclined portion on the box member for cooperating with the at least one flange (particularly as the portion 3a 'of the second embodiment shown on the figures 5 and 6 ).

Thus, the support or the contact of the first bent end 12 of the flange against the movement and the support or the contact of the second bent end 13 of the flange against the box element are modified when the movement is attached to the watch case member or moved relative to the watch case member from a rest position in which the first movement surface 2b is in contact with the second surface 3b of the element of box.

In the various embodiments, a device for modifying the flange rigidity is advantageously provided at each flange. Preferably, in the same timepiece, the devices for modifying the flange rigidity are identical for each flange.

Each flange may be of parallelepipedal or substantially parallelepipedal shape as shown in FIG. figure 7 .

Advantageously, a flange or each flange comprises a cross section S whose quadratic moment evolves along a longitudinal axis 11 of the flange.

In a first variant represented on the figure 10 , the width L 'of the flange changes along the longitudinal axis 11. This evolution is present between the fastening element 14 and the end 15 of the flange, in particular over more than half of the portion s' extending between the element of fastener 14 and the end 15 of the flange. The width L decreases preferably as one approaches the end 15.

In a second variant represented on the figure 11 , the thickness e of the flange changes along the longitudinal axis 11. This evolution is present between the fastening element 14 and the end 15 of the flange, in particular over more than half of the portion s' extending between the fastener 14 and the end 15 of the flange. The thickness e decreases preferably as one approaches the end 15.

The evolution of the width and / or the thickness and / or the geometry of the flange may be such that the transverse sections evolve so that the profile of the maximum stresses in the sections is constant or substantially constant at least over a part of the length of the flange, in particular between the fastening element 14 and the end 15 of the flange, in particular over more than half of the portion extending between the fastening element 14 and the end 15 of the bridle. In other words, the flange may, in particular, have a profile of equal resistance to bending or "iso-stress". More generally, the sections of the flange can evolve so as to best distribute the constraints within it, and thus to minimize them.

In all the embodiments described above, the portions 2a 'have been described as made on the movement and the portions 3a' have been described as made on the box member.

In all the embodiments described above, the movement is intended to be assembled directly within a middle part. However, alternatively, the movement can be assembled on another box element, such as a bottom or a telescope, intended to be attached to a caseband.

Of course, the watch assembly 200 may also comprise a casing ring or enlarging circle, this casing or enlargement ring being able to be secured to the movement or the middle part by associated fastening means. In such a situation, the portions 2a 'can be made at least partly on the casing ring or the portions 3a' can be made at least partly on the casing ring.

In all the embodiments described above, the casing flanges have been described fixed on the movement. Alternatively, the fastening means of the flanges can be mounted on a casing ring. Alternatively again, the means for fixing the flanges can be mounted on a box element, in particular on a middle part.

In all the embodiments described above, the portions 2a 'and 3a' have been described as planar portions.

However, alternatively, the portion 2a 'and / or the portion 3a' may (wind) be convex (s) or curved (s), in particular be in the form of a cylinder portion, as shown in FIG. figure 12 for portion 2a '.

Alternatively again, the portion 2a 'and / or the portion 3a' can (wind) be discontinuous (s), in particular be formed by a staircase, as shown on the figure 13 for portion 2a '.

More generally, preferably, in the fixed state of movement to the box member, the movement being in the rest position in which the first surface 2b of the movement is in contact with the second 3b surface of the box element, there may exist a game e1 ( Figure 3 ) between the flange and a point of the movement against which the flange can come into contact by bending the flange. The value of the set e1 is lower than Lc1, or even lower than Lc1 / 3, or even lower than Lc1 / 4 and / or the value of the set e1 is greater than Lc1 / 60, or even greater than Lc1 / 30, with Lc1 the length of L1. the projection in the plane of the frame of the movement of the portion 2a '. In addition, the length Lc1 is between Lf / 10 and Lf with Lf measured in the idle state.

More generally, preferably, in the fixed state of movement to the box member, the movement being in the rest position in which the first surface 2b of the movement is in contact with the second surface 3b of the box member. , there may be a game e2 ( Figure 14 ) between the flange and a point of the box member against which the flange can come into bending contact with the flange. The value of the clearance e2 is less than Lc2, or even less than Lc2 / 3, or even less than Lc2 / 4 and / or the value of the clearance e2 is greater than Lc2 / 60, or even greater than Lc2 / 30, with Lc2 the length of L2. the projection in the plane of the box element of the portion 3a '. In addition, the length Lc2 is between Lf / 10 and Lf with Lf measured in the idle state.

Whatever the flange variant, each flange has a fastener element 14 to the movement or to the box element. This element is for example a passage hole 14 for the passage of a screw 4.

Whatever the flange variant, the flange may be made of steel or a superelastic alloy and / or a shape memory alloy, in particular a nickel-titanium alloy such as Nitinol or a nickel alloy.

Whatever the flange variant, the flange 1 may be flat or not. Thus, the flange may have a bent geometry. The flange 1 may have a symmetrical profile or not.

The figure 8 illustrates a summary table showing the behavior of flanges with the same geometry (L = 3.3 mm, L = 2.05 mm Lf = 1.0 mm and e = 0.35 mm) with constant sections and made of the same material (durnico steel) for different configurations A, B, C, D assembly.

Configuration A corresponds to an encasing configuration according to the prior art illustrated by the Figures 1 and 2 .

Configuration B corresponds to the casing configuration of the first embodiment illustrated by the figures 3 and 4 .

The configuration C corresponds to the casing configuration of the second embodiment illustrated by the figures 5 and 6 .

The configuration D corresponds to the casing configuration of the third embodiment illustrated by the figure 14 .

Note that for the same interference I-flanges defining a given elastic deformation of the flanges, the elastic return forces F produced by the flanges, following an impact of a given intensity on the workpiece, vary substantially according to the configurations. This results in axial displacements of movements vis-à-vis their respective box, which vary significantly, and thus residual deformations Def flanges that can support more or less depending on configurations.

The table of the figure 8 highlights in particular the fact that the configurations B, C, D make it possible to propose a particularly rigid assembly, while minimizing the residual deformations of the flanges, whereas the flanges of the configuration A are greatly plasticized because, in particular, of a axial displacement d too much produced during the shock. Since in this configuration Def> I, the plasticization of the flange here induces the displacement of the movement of the middle part, namely the loss of contact between the movement and the middle part. After shock, the movement is no longer assembled satisfactorily in the box. Advantageously, the configuration D allows, as for it, to limit as much as possible the displacement of the movement vis-à-vis the box and to limit as much as possible the residual deformation of the flanges.

The figure 9 illustrates the stiffness characteristics of the flanges in each of the configurations A, B, C, D as a function of their displacement or axial deformation of, with d = d + I. Unlike the curve representing the rigidity characteristic of the flange taking part in the configuration A, the curves representing the stiffness characteristics of the flanges taking part respectively in the configurations B, C and D are provided with a point of inflection. This results in a first flange rigidity especially during the assembly of the movement (of ≤ I + d ₀ ) and a second flange rigidity in particular during a shock of a predefined intensity when the movement is moved from the box with a distance d greater than d ₀ (resulting in an axial flange deformation of> I + d ₀ ), with the distance d ₀ specific to the geometry of the embodiment and which can correspond to the displacement of movement causing a new contact of flange with movement or with box element. In a more general manner, the flanges may have a first and a second stiffness when assembling the movement within the box element or have a second rigidity once the assembled movement, following a shock of a predefined intensity for example.

The figure 9 thus highlights a modulus of rigidity of the flanges of the configurations B, C, and D due to a modification of their active length or a modification of their points or of their bearing surfaces when these are requested, whether during the assembly of the movement or during a shock of the watch case after assembly of the movement.

As seen above, the flange can be made of steel, especially Durnico steel. A shape memory alloy, such as Nitinol, can advantageously be chosen for its superelastic properties. A flange formed of such an alloy has, in fact, the advantage of generating a force varying significantly less than a flange made of durnico steel beyond a given threshold of prestressing, and this because of the phase change of material according to its rate of deformation according to the solicitations it undergoes during the casing or that it is likely to undergo during an impact. This property is therefore particularly advantageous in order to best compensate for the variations in force induced by the variations in assembly configurations caused by manufacturing and / or assembly tolerances of the movement and of the box, and thus makes it possible to propose a device for particularly robust assembly.

Moreover, a flange formed of such a superelastic alloy makes it possible to generate very substantial elastic restoring forces compared with those known from the flanged fitting devices known from the prior art. The choice of such a material is therefore particularly advantageous in order to increase the rigidity of the casing, the advantages of which are those highlighted by means of studies of the applicant, and which are set out in the patent application EP2458456 , namely in particular a dramatic decrease in the acceleration experienced by the movement, for example during a shock on a hard surface.

The invention also relates to a method of operating a fastening system which is the subject of the invention, in particular a method of operating the embodiments described above. According to this operating method and / or in the various embodiments described above, the fastening system has an operation comprising a step of modifying the rigidity of the at least one flange, in particular modifying the flexural stiffness of the flange. at least one flange, when the movement is fixed and / or when the movement is moved relative to the watch case element.

In particular, the flexed length of the at least one flange is modified, in particular the flexed length of the at least one flange is reduced, when the movement is fixed and / or when the movement is moved relative to the element of a watch case from a rest position in which the first surface 2b of the movement is in contact with the second surface 3b of the watch case element.

Thus, according to a second aspect of the invention, the timepiece 400, in particular a wristwatch, or the assembly 200 comprises a system 10 for fixing a watch movement 2 to a watchcase element 3, the system comprising at least one flange 1, in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement on the one hand and with the watch case element on the other hand, the at least one flange being a superelastic alloy and / or a shape memory alloy, especially a nickel-titanium alloy such as Nitinol.

Nitinol is a superelastic and shape memory alloy. Indeed, in a temperature range corresponding to the use that is made of the flanges (-10 ° C to 40 ° C for example), Nitinol is austenitic phase, so superelastic.

Nitinol is an alloy of nickel and titanium in which these two elements are approximately present in the same percentages, ie approximately 55% by weight or 60% by weight of nickel and approximately 45% by weight or 40% by weight of titanium and possibly elements of nickel. addition in less proportion such as chromium, cobalt, or niobium. Other shape memory alloys exist such as AuCd, CuAlBe, CuAlNi or CuZnAl in monocrystalline or polycrystalline form.

The alloys can also undergo particular heat treatments to acquire their superelasticity character.

For example, the 60NiTi alloy is nominally 60% by weight nickel and 40% by weight titanium. The 55NiTi alloy is nominally 55% by weight of nickel and 45% by weight of titanium. The Nitinol # 1 alloy consists of 54.5 wt.% At 57.0 wt.% Nickel and between 43.0 wt.% And 45.5 wt.% Titanium with a maximum of 0.25 wt.% Of other elements such as chromium, cobalt, copper, iron or niobium in particular.

The Nitinol alloy has been studied and the results are shown on the Figures 15 to 17 It consists in particular of about 56% by weight of nickel and about 44% by weight of titanium and addition elements such as Cr, Cu, and Fe.

For example, the alloy CuAl12Be (0.45-0.68) is nominally 12% by weight of aluminum and 0.45% by weight with 0.68% by weight of Beryllium, with a balance of copper.

For example, CuAl13Ni4 alloy is nominally 83% by weight of copper, 13% by weight of aluminum and 4% by weight of nickel.

All materials mentioned above are suitable for making flanges.

For example, the figure 15 illustrates a graph showing the evolution of the restoring force generated by two flanges in their elastic domain, made respectively of Durnico steel (Curve 6) and Nitinol (Curve 5a, 5b), according to their state of pre- voltage "interference I", once the movement nested in a configuration A. Their geometry "iso-constrained" is here comparable to that illustrated on the figure 10 with Lf = 1.35 mm and a width L 'of greater dimension of 2.05 mm. The thicknesses differ, however, with e = 0.37 mm for the durnico steel flange and e = 0.7 mm for the Nitinol flange.

This graph shows a curve 5a, 5b having two distinct portions 5a, 5b of substantially different slopes, unlike the curve 6 which has only one limited portion. In assembled configuration, the Nitinol flange is prestressed in such a way that it behaves according to the characteristic of the portion 5b of the curve. Thus, for a given variation of interference, the variation of force produced by a Nitinol flange is minimized compared with that which a Durnico steel flange can produce.

In order to better stiffen the casing and to contain the superelastic character of the alloy in the casing phase, the geometry of a Nitinol flange can evolve with respect to the known flanges of the prior art. The thickness e of a Nitinol flange may, for example, be increased with respect to that of a flange made of Durnico steel, and / or the flexural length Lf, constant or not depending on the stresses, may be minimized. .

Preferably, e≥0.5 mm for a Nitinol flange.

Preferably, Lf≤1.35 mm for a Nitinol flange.

For example, the figure 16 illustrates a graph showing the evolution of the return force generated respectively by two flanges in their elastic domain, respectively made of durnico steel (curve 6) and Nitinol (curve 5a, 5b), depending on their state of pre -tension "interference I", once the movement nested in a configuration A. Their "iso-constrained" geometry is here comparable to that of the figure 10 with Lf = 1.35 mm and a width L 'of greater dimension of 2.05 mm. The thicknesses differ, however, with e = 0.37 mm for the durnico steel flange and e = 1.75 mm for the Nitinol flange.

Note here a considerably increased elastic restoring force compared to that produced by a Durnico steel flange, and this without risk of residual deformation of the Nitinol flange.

To limit the increase in thickness of the flange, it is possible at the same time to reduce the length Lf of the flange. For example, the figure 17 illustrates a graph showing the evolution of the return force generated respectively by two flanges in their elastic domain, respectively made of durnico steel (curve 6) and Nitinol (curve 5a, 5b), depending on their state of pre "interference I" voltage, once the movement is in a configuration A. geometry "iso-constraint here assimilable to that of the figure 10 with a width L 'of greater dimension of 2.05 mm. The thicknesses differ, however, with e = 0.37 mm for the durnico steel flange and e = 0.5 mm for the Nitinol flange. The lengths Lf also differ with Lf = 1.35 mm for the Durnico steel flange and Lf = 0.72 mm for the Nitinol flange.

Note also a considerably increased elastic return force compared to that produced by a durnico steel flange, and without risk of residual deformation of the Nitinol flange. Moreover, for a given variation of interference, the variation of force produced by a Nitinol flange is minimized compared with that which can be produced by a Durnico steel flange. Thus, according to a second aspect of the invention, the system has the particularity of implementing a particularly rigid casing and insensitive to variations in manufacturing and / or assembly tolerances.

In the known embodiment of the prior art and represented on the Figures 1 and 2 , the active bending length Lf * of the flange corresponds to a limited portion of the total length L * of the flange. The length Lf * is notably substantially less than the support length La * of the flange against the movement, in particular Lf * ~ La * / 4. This length Lf * may be insufficient during assembly of the movement in the box, which may induce a residual deformation of the flange may reduce the elastic return force potentially produced by said flange. This situation may in particular lead to the loss of contact between the surfaces 2b * and 3b *, which are respectively associated with the movement 2 * and the box 3 *. This situation can also reduce the forces under the head of the screw 4 *, which can lead to a risk of inadvertent unscrewing of said screw 4 *.

On the other hand, if the length Lf * is increased with regard to these considerations, this length Lf * may then prove to be excessive once the movement has been assembled in the box, in particular with respect to a predefined threshold of impact resistance and / or a given amplitude of displacement of the movement, which may also induce a residual deformation of the flange may reduce the elastic return force initially produced by said flange.

Thus, the volume available at the interface of the movement and the box, the materials known from the prior art can be chosen to achieve the flanges, and can not suffice to completely obviate the risk of residual plasticization of said flanges to from a given threshold value of shock.

Thanks to the solutions described in this document, these problems can be solved and the fastening systems can be more robust and / or more reliable, because of the materials used for the flanges and / or geometries on which the flanges are based. Indeed, in particular according to the solutions described in this document the stiffness of elastic casing flanges are likely to vary depending on the stresses applied to them, in particular as a function of the movement of the watch movement opposite the watch case, in particular when fitting and / or during an impact.

In this document, the term "superelastic alloy" is preferably understood to mean an alloy whose deformation at the elastic limit is greater than 2%, or even greater than 5%, or even greater than 8%.

In this document, the percentages by weight of the elements are denoted "% wt".

Claims (7)

System (10) for fixing a watch movement (2) to a watch-case element (3) (30), the system comprising at least one flange (1), in particular at least two flanges, preferably three flanges or four flanges, intended to come into contact with the movement on the one hand and with the watch case element on the other hand, the at least one flange being made of a superelastic alloy and / or a memory alloy of form, especially a nickel-titanium alloy such as Nitinol. System according to the preceding claim, characterized in that the at least one flange comprises a cross section whose quadratic moment evolves along a longitudinal axis (11), in particular by evolution of the width and / or thickness and / or so that the cross section is such that the profile of the maximum stresses is constant or substantially constant over at least a portion of the length of the at least one flange, in particular over at least half the length of the flange. System according to one of the preceding claims, characterized in that the at least one flange comprises a fastening element (14) to the movement or to the watch case element, in particular a screw hole (4). System according to one of the preceding claims, characterized in that the thickness (e) of the at least one flange is greater than or equal to 0.5 mm. System according to one of the preceding claims, characterized in that the bent length (Lf) of the at least one flange is less than or equal to 1.35 mm. Watchmaker assembly (200), in particular a watch movement or a watch case element, comprising a system according to one of the preceding claims. Timepiece (400), in particular a wristwatch, comprising an assembly according to the preceding claim and / or or a system according to one of Claims 1 to 5.

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