EP4224257A1 - Monolithic spiral spring - collet assembly - Google Patents

Abstract

The invention relates to a monolithic spiral spring - ferrule assembly (1) comprising:- a first reception part which does not deform or substantially does not deform during operation or during assembly of the monolithic assembly on the balance shaft and intended to come to bear against a balance shaft, - a second reception part which does not deform or substantially does not deform during operation or during assembly of the monolithic assembly on the balance shaft and intended to bear against the shaft of the balance, - a first connecting part deforming elastically during operation or during assembly of the monolithic assembly on the balance shaft and intended to connect the first and second receiving parts, - a second connecting part deforming elastically during operation or during assembly of the monolithic assembly on the balance shaft and intended to connect the first and second receiving parts, and- an element capable of continuously surrounding the balance staff and comprising the receiving parts and the connecting parts.

Description

The invention relates to a ferrule. The invention also relates to a monolithic single or double spiral spring assembly - unsplit ferrule, intended to be driven onto a balance shaft, in particular a monolithic assembly including a ferrule according to the invention. According to another aspect, the invention also relates to a monolithic spiral spring-shell assembly comprising at least two stages as well as to a method of manufacturing such an assembly.

Background of the invention

One of the critical points for the use of a hairspring in a high-precision watch movement is the reliability of the attachments (embeddings) of the hairspring to the balance shaft and to the balance bridge. In particular, the attachment of the hairspring to the balance shaft is generally done by a ferrule, which was originally a small split cylinder intended to be driven onto the balance shaft and pierced laterally to receive the end interior of the spiral spring itself. The development of micro-fabrication techniques, such as DRIE processes for silicon, quartz and diamond or UV-Liga for Ni and NiP, open up possibilities in terms of the shapes and geometries used.

Silicon is a very interesting material for making watch hairsprings, and microfabrication techniques make it possible to make the ferrule monolithically and come from manufacture with the hairspring. A potential problem is that silicon does not have a plastic deformation domain. The ferrule can thus quickly break if the stresses exceed the stress allowable maximum and/or the elastic limit of the material. It is thus necessary to take care to dimension the ferrule both to maintain the spiral spring on the axis of the balance during the operation of the oscillator (minimum tightening torque) and also to be able to assemble the ferrule with axes whose diameters present fluctuations and this, without breaking or undergoing plastic deformation if the diameter of the balance shaft remains within a given tolerance interval.

Thus, several documents reveal shell geometries.

The European patent application published under no. EP 1 826 634 offers on his figure 4 in connection with line 34 of column 3, a ferrule comprising elastic zones consisting of curved arms. This document does not indicate where the hairspring must be fixed.

European patent applications published under numbers EP 1 513 029 And EP 2 003 523 offer ferrules having a triangular opening. The balance spring is fixed at a point of attachment (reference 3 in the figures of these documents) located at one of the vertices of the triangles. The ferrule is made up of an external stiffening structure to which are attached flexible arms which deform to accommodate the balance shaft.

The European patent application published under no. EP 1 655 642 described by its figure 10D a balance-spring resonator hairspring having a ferrule whose opening is circular. The fixing of the pendulum is carried out in this case using rounded arms.

We still know of the patent application WO2011026275 a spiral spring-shell assembly, with a shell having a bore provided with four bearing parts circular to receive the balance shaft. The support parts are delimited by longitudinal grooves made in the bore of the ferrule.

The geometries described in these documents are not entirely satisfactory, so that many hairsprings (in silicon, diamond, quartz, etc.) mounted on movements are fitted with a conventional ferrule which is then driven and/or glued onto the axis of the balance.

Brief description of the invention

The object of the invention is to propose new shell geometries giving full satisfaction, that is to say making it possible to obtain the highest possible tightening torque on the balance shaft and a stress in the material the most possible low. In addition, these ferrules must be as balanced as possible so as not to cause unbalance, which would degrade the chronometric properties of the hairspring.

According to one aspect of the invention, objects are defined by the appended claims.

• le contour de la virole est fermé,
• l'ouverture centrale de la virole destinée à recevoir un axe de balancier est non circulaire,
• le contour de l'ouverture centrale de la virole comporte au moins deux surfaces d'appui pour un axe de balancier ;

cet ensemble monolithique se distinguant en ce que :

• la virole est formée d'au moins deux parties de réception d'axe de balancier situées en regard, notamment à 180°, l'une de l'autre et dont l'une comprend au moins la première des surfaces d'appui pour l'axe de balancier ainsi que un point d'attache ou d'encastrement du ressort spiral, et l'autre au moins la deuxième des surfaces d'appui pour l'axe de balancier,
• ces deux parties de réception d'axe de balancier étant reliées l'une à l'autre par deux parties de liaison qui présentent une rigidité inférieure à celles des parties de réception, de façon à pouvoir se déformer élastiquement lors du chassage d'un axe de balancier.

According to another aspect, the invention relates to a monolithic single or double spiral spring - non-split ferrule assembly, in which:

• the contour of the shell is closed,
• the central opening of the ferrule intended to receive a balance shaft is non-circular,
• the outline of the central opening of the ferrule comprises at least two bearing surfaces for a balance shaft;

this monolithic set distinguishing itself in that:

• the shroud is formed of at least two balance shaft receiving parts located opposite, in particular at 180°, one from the other and one of which comprises at least the first of the bearing surfaces for the balance shaft as well as a point of attachment or embedding of the spiral spring, and the the other at least the second of the bearing surfaces for the balance shaft,
• these two balance shaft receiving parts being connected to one another by two connecting parts which have a lower rigidity than those of the receiving parts, so as to be able to deform elastically during the driving in of a shaft of pendulum.

These characteristics have the particular effect of preventing the point of attachment of the hairspring from moving significantly relative to the points of contact (of support) with the balance staff following the driving out of the latter. It follows that the positioning of the hairspring and its embedding point can be precisely defined.

According to another aspect, the invention relates to a monolithic single or double spiral spring-shroud assembly, the latter possibly being split or not. This assembly has the particularity of comprising at least two levels (or stages or parts), the spiral spring being located on a different level from that where the support surfaces of the ferrule for the balance shaft are located. This feature is particularly advantageous because it makes it possible to best optimize the holding torque of the ferrule on the balance staff without having to increase its size in the plane of the hairspring. According to another aspect of the invention, this characteristic makes it possible to bring the point of attachment of the spiral spring closer to the axis of the balance wheel, without being limited by the periphery of the ferrule.

The invention also relates to a process for the manufacture of a monolithic spiral spring - ferrule, split or not, in which the balance spring is produced on a level different from that where the bearing surfaces of the ferrule are located for the balance shaft.

• 1. Virole (100) comprenant un alésage (101) destiné à recevoir un axe de balancier, au moins une première partie (102) et une deuxième partie (103), les première et deuxième parties étant séparées par un plan (104) perpendiculaire à l'axe (107) de l'alésage, un élément (105) d'attache de la virole à un ressort spiral étant exclusivement situé sur la première partie et un élément (106) de liaison de la virole à l'axe de balancier étant essentiellement, voire exclusivement, situé sur la deuxième partie.
• 2. Virole selon la proposition 1, dans laquelle l'élément d'attache ou point d'attache se trouve à une distance (D1) du centre de la virole (107) inférieure à la moitié du diamètre (D2) d'un cylindre dans lequel s'inscrit la deuxième partie, notamment à une distance (D1) inférieure ou égale à la moyenne de la moitié du diamètre (D2) du cylindre dans lequel s'inscrit la deuxième partie et de la moitié du diamètre du cercle inscrit (d_max) dans une ouverture centrale de la virole.
• 3. Virole selon la proposition 1 ou 2, dans laquelle la deuxième partie s'étend, selon l'axe de l'alésage, sur une longueur supérieure à une fois l'épaisseur (E) du ressort spiral, voire supérieure à 3 fois l'épaisseur (E) du ressort spiral.
• 4. Ensemble monolithique ressort spiral - virole (1) comprenant :
  • une première partie de réception, notamment une première partie de réception indéformable, destinée à venir en appui contre un axe de balancier,
  • une deuxième partie de réception, notamment une deuxième partie de réception indéformable, destinée à venir en appui contre l'axe de balancier,
  • une première partie de liaison, notamment une première partie de liaison déformable, destinée à relier les première et deuxième parties de réception,
  • une deuxième partie de liaison, notamment une deuxième partie de liaison déformable, destiné à relier les première et deuxième parties de réception, et
  • un élément apte à entourer continûment l'axe de balancier et comprenant les parties de réception et les parties de liaison.
• 5. Ensemble monolithique selon la proposition 4, dans lequel les parties de liaison occupent 50% et plus, voire entre 50% et 90%, voire entre 60% et 80%, de la longueur totale du contour extérieur de la virole.
• 6. Ensemble monolithique selon la proposition 4 ou 5, dans lequel chaque partie de liaison occupe un secteur d'angle mesuré depuis le centre de la virole supérieur ou égal à 90°, voire compris entre 90° et 160°, voire compris entre 110° et 145°.
• 7. Ensemble monolithique selon l'une des propositions 4 à 6, dans lequel chaque partie de liaison présente une portion distante de l'axe de balancier d'au moins 0.5 fois le rayon de l'axe de balancier, voire d'au moins 0.9 fois le rayon de l'axe de balancier, une fois l'ensemble monté sur l'axe de balancier.
• 8. Ensemble monolithique selon l'une des propositions 4 à 7, dans lequel chaque partie de liaison est principalement sollicitée en flexion, une fois l'ensemble monolithique monté sur l'axe de balancier.
• 9. Ensemble monolithique selon l'une des propositions 4 à 8, dans lequel les parties de réception sont en regard l'une de l'autre, notamment à 180° l'une de l'autre par rapport au centre de la virole.
• 10. Ensemble monolithique selon l'une des propositions 4 à 9, dans lequel une lame du ressort spiral est attachée ou liée directement à une partie de réception, notamment, dans le cas d'un ensemble comportant un double spiral, dans lequel chaque lame est attachée à une partie de réception différente.
• 11. Ensemble monolithique selon l'une des propositions 4 à 10, dans lequel une ouverture centrale de la virole destinée à recevoir un axe de balancier est non circulaire.
• 12. Ensemble monolithique selon l'une des propositions 4 à 11, dans lequel le contour de l'ouverture centrale de la virole (1) comprend, sur une même partie de réception, au moins une surface d'appui (2,3 ; 4,5) pour l'axe de balancier.
• 13. Ensemble monolithique selon l'une des propositions 4 à 12, dans lequel le contour de l'ouverture centrale de la virole (1) comprend, sur une même partie de réception, au moins une paire de surfaces d'appui (2,3 ; 4,5) pour l'axe de balancier, les tangentes aux surfaces d'appui (2,3) aux points d'appui de cette paire formant entre elles un angle (α) supérieur à 90 degrés et inférieur à 170 degrés.
• 14. Ensemble monolithique selon l'une des propositions 4 à 13, dans lequel le contour de l'ouverture centrale de la virole (1) comprend deux paires (2,3 ; 4,5) de surfaces d'appui.
• 15. Ensemble monolithique selon l'une des propositions 4 à 14, dans lequel les surfaces d'appui (2,3 ; 4,5) sont au moins partiellement situées sur des bras (6,7 ; 8,9) ou extensions s'étendant depuis le corps des parties de réception.
• 16. Ensemble monolithique selon l'une des propositions 13 à 15, dans lequel des surfaces d'appui sont planes ou à courbure négative ou à courbure positive avec un rayon supérieur à 0,51 fois le diamètre (d_max) du cercle inscrit dans une ouverture centrale de la virole.
• 17. Ensemble monolithique selon l'une des propositions 4 à 16, dans lequel deux parties de réception sont disposées à 180° l'une de l'autre par rapport à l'axe de la virole.
• 18. Ensemble monolithique selon l'une des propositions 4 à 17, dans lequel les différentes parties de liaison ont une géométrie identique et/ou les différentes parties de réception ont une géométrie identique.
• 19. Ensemble monolithique selon l'une des propositions 4 à 18, dans lequel le ressort spiral est un ressort spiral double comprenant une première lame dont le point d'attache (10) à la virole (1) est relié à une première partie de réception et une deuxième lame dont le point d'attache (11) à la virole (1) est relié à une deuxième partie de réception.
• 20. Ensemble monolithique selon l'une des propositions 4 à 19, dont la géométrie de la virole a une symétrie de réflexion d'ordre 2.
• 21. Ensemble monolithique selon l'une des propositions 4 à 20, dont la géométrie de la virole a une symétrie de rotation d'ordre 2.
• 22. Ensemble monolithique selon l'une des propositions 4 à 21, l'ensemble étant en silicium, éventuellement avec une couche externe et/ou une couche interne en oxyde de silicium.
• 23. Ensemble monolithique selon l'une des propositions 4 à 22 dans lequel le ou les point(s) d'attache du spiral simple ou double est (sont) plus proche(s) de l'ouverture centrale de la virole que ne l'est le contour de la virole.
• 24. Ensemble monolithique selon l'une des propositions 4 à 23, l'ensemble étant réalisé en un matériau fragile ou en un matériau ne présentant pas de domaine de déformation plastique.
• 25. Ensemble monolithique selon l'une des propositions 4 à 24, l'ensemble comprenant une virole selon l'une des propositions 1 à 3.
• 26. Procédé de fabrication d'un ensemble monolithique selon la proposition 25, dans lequel on réalise le ressort spiral sur une partie différente de celle où se trouvent les surfaces d'appui de la virole contre l'axe de balancier.
• 27. Procédé de fabrication selon la proposition 26, dans lequel on utilise comme matériau de départ une tranche SOI dont la couche de SiO₂ a une épaisseur supérieure à 3 microns.
• 28. Procédé de fabrication d'une virole selon l'une des propositions 1 à 3, dans lequel on réalise un élément (105) d'attache de la virole à un ressort spiral sur une partie différente de celle où se trouve un élément (106) de liaison de la virole à l'axe de balancier.
• 29. Procédé de fabrication selon la proposition 28, dans lequel on utilise comme matériau de départ une tranche SOI dont la couche de SiO₂ a une épaisseur supérieure à 3 microns.
• 30.- Ensemble monolithique ressort spiral - virole (1) réalisé dans un matériau ne présentant pas de domaine de déformation plastique, dans lequel :
  • le contour de la virole (1) est fermé,
  • l'ouverture centrale de la virole (1) destinée à recevoir un axe de balancier est non circulaire,
  • le contour de l'ouverture centrale de la virole comporte au moins deux surfaces d'appui (2,3;4,5;14) pour un axe de balancier ;
  caractérisé en ce que
  la virole (1) est formée de deux parties de réception d'axe de balancier situées en regard l'une de l'autre et dont l'une comprend au moins la première des surfaces d'appui (2 ou 3) pour l'axe de balancier ainsi qu'un point d'attache (10,11) du ressort spiral, et l'autre au moins la deuxième des surfaces d'appui (4, 5 ou 14) pour l'axe de balancier, ces deux parties de réception d'axe de balancier étant reliées l'une à l'autre par deux parties de liaison qui présentent une rigidité inférieure à celles des parties de réception, de façon à pouvoir se déformer élastiquement lors du chassage d'un axe de balancier.
• 31.- Ensemble monolithique ressort spiral - virole (1) selon la proposition 30, dans lequel les deux parties de liaison présentent une largeur moyenne inférieure à la largeur moyenne des parties de réception.
• 32.- Ensemble monolithique ressort spiral - virole (1) selon la proposition 30, dans lequel les deux parties de liaison présentent une largeur minimale et/ou une largeur à mi-distance des parties de réception, inférieure(s) à la largeur maximale des parties de réception.
• 33.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 32, dans lequel le contour de l'ouverture centrale de la virole (1) comprend, sur une même partie de réception, au moins une paire de surfaces d'appui (2,3 ; 4,5) pour l'axe de balancier, les surfaces d'appui (2,3) de cette paire formant entre elles un angle (α) supérieur à 90 degrés et inférieur à 170 degrés.
• 34.- Ensemble monolithique ressort spiral - virole (1) selon la proposition 33, dans lequel le contour de l'ouverture centrale de la virole (1) comprend deux paires (2,3 ; 4,5) de surfaces d'appui.
• 35.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 34, dans lequel les surfaces d'appui (2,3 ; 4,5) sont au moins partiellement situées sur des bras (6,7 ; 8,9).
• 36.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 35, dans lequel les parties de liaison ont une géométrie identique.
• 37.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 36, dans lequel le ressort spiral est un ressort spiral double comprenant une première lame (10) dont le point d'attache à la virole (1) est relié à une première partie de réception et une deuxième lame (11) dont le point d'attache à la virole (1) est relié à une deuxième partie de réception.
• 38.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 37, dont la géométrie de la virole a une symétrie de réflexion d'ordre 2.
• 39.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 38, dont la géométrie de la virole a une symétrie de rotation d'ordre 2.
• 40. - Ensemble monolithique ressort spiral - virole selon l'une des propositions 30 à 39, cet ensemble étant en silicium, éventuellement avec une couche externe et/ou un étage en oxyde de silicium.
• 41.- Ensemble monolithique ressort spiral - virole (1) selon l'une des propositions 30 à 40, formé sur deux niveaux, le ressort spiral étant situé sur un niveau différent de celui où se trouvent les surfaces d'appui (2,3 ; 4,5 ; 14) pour l'axe de balancier.
• 42.- Ensemble monolithique ressort spiral - virole ayant au moins deux niveaux, le ressort spiral étant situé sur un niveau différent de celui où se trouvent les surfaces d'appui de la virole pour un axe de balancier.
• 43.- Ensemble monolithique ressort spiral - virole selon la proposition 41 ou 42, dans lequel le ou les point(s) d'attache du spiral simple ou double est (sont) plus proche (s) de l'ouverture centrale de la virole que ne l'est le contour de la virole.
• 44.- Procédé de fabrication d'un ensemble monolithique ressort spiral - virole selon l'une des propositions 41 à 43, dans lequel on réalise le ressort spiral sur un niveau différent de celui où se trouvent les surfaces d'appui de la virole pour l'axe de balancier.
• 45.- Procédé de fabrication selon la proposition 44, dans lequel on utilise comme matériau de départ une tranche SOI dont la couche de SiO₂ a une épaisseur supérieure à 3 microns.
• 46.- Oscillateur comprenant un ensemble monolithique selon l'une des propositions 4 à 25 ou 30 à 45 et un axe de balancier à section circulaire.
• 47.- Mouvement horloger ou pièce d'horlogerie comprenant un ensemble monolithique selon l'une des propositions 4 à 25 ou 30 à 45 ou comprenant un oscillateur selon la proposition précédente ou comprenant une virole selon l'une des propositions 1 à 3.

According to another aspect, the invention is defined by the following propositions:

• 1. Ferrule (100) comprising a bore (101) intended to receive a balance shaft, at least a first part (102) and a second part (103), the first and second parts being separated by a plane (104) perpendicular to the axis (107) of the bore, an element (105) for attaching the ferrule to a spiral spring being located exclusively on the first part and an element (106) for connecting the ferrule to the axis of balance being essentially, or even exclusively, located on the second part.
• 2. Ferrule according to proposition 1, in which the attachment element or attachment point is at a distance (D1) from the center of the ferrule (107) less than half the diameter (D2) of a cylinder in which the second part is inscribed, in particular at a distance (D1) less than or equal to the average of half the diameter (D2) of the cylinder in which the second part is inscribed and of half the diameter of the inscribed circle ( d _max ) in a central opening of the shell.
• 3. Ferrule according to proposal 1 or 2, in which the second part extends, along the axis of the bore, over a length greater than once the thickness (E) of the spiral spring, or even greater than 3 times the thickness (E) of the spiral spring.
• 4. Monolithic spiral spring assembly - ferrule (1) comprising:
  • a first reception part, in particular a non-deformable first reception part, intended to bear against a balance shaft,
  • a second reception part, in particular a non-deformable second reception part, intended to bear against the balance staff,
  • a first connecting part, in particular a first deformable connecting part, intended to connect the first and second receiving parts,
  • a second connecting part, in particular a second deformable connecting part, intended to connect the first and second receiving parts, and
  • an element capable of continuously surrounding the balance shaft and comprising the receiving parts and the connecting parts.
• 5. Monolithic assembly according to proposal 4, in which the connecting parts occupy 50% and more, or even between 50% and 90%, or even between 60% and 80%, of the total length of the outer contour of the shell.
• 6. Monolithic assembly according to proposal 4 or 5, in which each connecting part occupies an angle sector measured from the center of the shell greater than or equal to 90°, or even between 90° and 160°, or even between 110 ° and 145°.
• 7. Monolithic assembly according to one of proposals 4 to 6, in which each connecting part has a portion distant from the balance shaft by at least 0.5 times the radius of the balance shaft, or even at least 0.9 times the radius of the balance shaft, once the assembly is mounted on the balance shaft .
• 8. Monolithic assembly according to one of proposals 4 to 7, in which each connecting part is mainly stressed in bending, once the monolithic assembly is mounted on the balance shaft.
• 9. Monolithic assembly according to one of proposals 4 to 8, in which the receiving parts face each other, in particular at 180° to each other with respect to the center of the ferrule.
• 10. Monolithic assembly according to one of proposals 4 to 9, in which a blade of the spiral spring is attached or linked directly to a receiving part, in particular, in the case of an assembly comprising a double spiral, in which each blade is attached to a different receiving part.
• 11. Monolithic assembly according to one of proposals 4 to 10, in which a central opening of the shell intended to receive a balance shaft is non-circular.
• 12. Monolithic assembly according to one of proposals 4 to 11, wherein the contour of the central opening of the shell (1) comprises, on the same receiving part, at least one bearing surface (2,3; 4.5) for the balance shaft.
• 13. Monolithic assembly according to one of proposals 4 to 12, in which the outline of the central opening of the ferrule (1) comprises, on the same receiving part, at least one pair of bearing surfaces (2, 3; 4.5) for the balance shaft, the tangents to the support surfaces (2.3) at the support points of this pair forming between them an angle (α) greater than 90 degrees and less than 170 degrees .
• 14. Monolithic assembly according to one of proposals 4 to 13, wherein the contour of the central opening of the shell (1) comprises two pairs (2.3; 4.5) of bearing surfaces.
• 15. Monolithic assembly according to one of proposals 4 to 14, in which the bearing surfaces (2.3; 4.5) are at least partially located on arms (6.7; 8.9) or extensions s extending from the body of the receiving parts.
• 16. Monolithic assembly according to one of proposals 13 to 15, in which bearing surfaces are flat or negatively curvature or positively curvature with a radius greater than 0.51 times the diameter (d _max ) of the circle inscribed in a central opening of the ferrule.
• 17. Monolithic assembly according to one of proposals 4 to 16, in which two receiving parts are arranged at 180° to each other with respect to the axis of the shell.
• 18. Monolithic assembly according to one of proposals 4 to 17, in which the various connecting parts have a identical geometry and/or the various receiving parts have identical geometry.
• 19. Monolithic assembly according to one of proposals 4 to 18, in which the spiral spring is a double spiral spring comprising a first blade whose point of attachment (10) to the ferrule (1) is connected to a first part of reception and a second blade whose point of attachment (11) to the ferrule (1) is connected to a second reception part.
• 20. Monolithic assembly according to one of the propositions 4 to 19, the geometry of the ferrule of which has a reflection symmetry of order 2.
• 21. Monolithic assembly according to one of the propositions 4 to 20, the geometry of the ferrule of which has rotational symmetry of order 2.
• 22. Monolithic assembly according to one of proposals 4 to 21, the assembly being made of silicon, optionally with an outer layer and/or an inner layer of silicon oxide.
• 23. Monolithic assembly according to one of proposals 4 to 22 in which the attachment point(s) of the single or double hairspring is (are) closer to the central opening of the ferrule than it is. is the outline of the ferrule.
• 24. Monolithic assembly according to one of proposals 4 to 23, the assembly being made of a fragile material or of a material having no plastic deformation domain.
• 25. Monolithic assembly according to one of proposals 4 to 24, the assembly comprising a ferrule according to one of proposals 1 to 3.
• 26. A method of manufacturing a monolithic assembly according to proposal 25, in which the spiral spring is produced on a part different from that where the support surfaces of the ferrule are located against the balance shaft.
• 27. Manufacturing process according to proposal 26, in which an SOI wafer is used as starting material, the SiO ₂ layer of which has a thickness greater than 3 microns.
• 28. A method of manufacturing a ferrule according to one of proposals 1 to 3, in which an element (105) for attaching the ferrule to a spiral spring is produced on a part different from that where an element ( 106) connecting the ferrule to the balance shaft.
• 29. Manufacturing process according to proposal 28, in which an SOI wafer is used as starting material, the SiO ₂ layer of which has a thickness greater than 3 microns.
• 30.- Monolithic spiral spring assembly - ferrule (1) made of a material having no plastic deformation range, in which:
  • the outline of the shell (1) is closed,
  • the central opening of the shell (1) intended to receive a balance shaft is non-circular,
  • the contour of the central opening of the ferrule comprises at least two bearing surfaces (2,3; 4,5; 14) for a balance shaft;
  characterized in that
  the shroud (1) is formed of two balance shaft reception parts located opposite each other and one of which comprises at least the first of the bearing surfaces (2 or 3) for the balance shaft as well as an attachment point (10,11) of the spiral spring, and the other at least the second of the bearing surfaces (4, 5 or 14) for the balance shaft, these two parts balance shaft reception being connected to one another by two connecting parts which have a lower rigidity than those of the reception parts, so as to be able to deform elastically during the driving out of a balance shaft.
• 31.- Monolithic spiral spring assembly - ferrule (1) according to proposal 30, in which the two connecting parts have an average width less than the average width of the receiving parts.
• 32.- Monolithic spiral spring - ferrule assembly (1) according to proposal 30, in which the two connecting parts have a minimum width and/or a width halfway between the receiving parts, less than the maximum width receiving parts.
• 33.- Monolithic spiral spring - ferrule assembly (1) according to one of proposals 30 to 32, in which the outline of the central opening of the ferrule (1) comprises, on the same receiving part, at least one pair of bearing surfaces (2,3; 4,5) for the balance shaft, the bearing surfaces (2,3) of this pair forming an angle (α) between them greater than 90 degrees and less than 170 degrees.
• 34.- Monolithic spiral spring assembly - ferrule (1) according to proposal 33, in which the contour of the central opening of the ferrule (1) comprises two pairs (2,3; 4,5) of bearing surfaces.
• 35.- Monolithic spiral spring assembly - ferrule (1) according to one of proposals 30 to 34, in which the bearing surfaces (2.3; 4.5) are at least partially located on arms (6.7 ;8.9).
• 36.- Monolithic spiral spring assembly - ferrule (1) according to one of proposals 30 to 35, in which the connecting parts have an identical geometry.
• 37.- Monolithic spiral spring - ferrule assembly (1) according to one of proposals 30 to 36, in which the spiral spring is a double spiral spring comprising a first blade (10) whose point of attachment to the ferrule (1 ) is connected to a first receiving part and a second blade (11) whose point of attachment to the ferrule (1) is connected to a second receiving part.
• 38.- Monolithic spiral spring - ferrule assembly (1) according to one of proposals 30 to 37, the geometry of the ferrule of which has a reflection symmetry of order 2.
• 39.- Monolithic spiral spring - ferrule assembly (1) according to one of proposals 30 to 38, the geometry of the ferrule of which has rotational symmetry of order 2.
• 40. - Monolithic spiral spring assembly - shell according to one of proposals 30 to 39, this assembly being made of silicon, optionally with an outer layer and / or a stage of silicon oxide.
• 41.- Monolithic spiral spring - shell assembly (1) according to one of proposals 30 to 40, formed on two levels, the spiral spring being located on a different level from that where the bearing surfaces are located (2,3 ; 4.5; 14) for the balance shaft.
• 42.- Monolithic spiral spring - ferrule assembly having at least two levels, the spiral spring being located on a different level from that where the bearing surfaces of the ferrule are located for a balance shaft.
• 43.- Monolithic spiral spring - ferrule assembly according to proposal 41 or 42, in which the attachment point(s) of the single or double spiral is (are) closer to the central opening of the ferrule than is the outline of the ferrule.
• 44.- A method of manufacturing a monolithic spiral spring - ferrule assembly according to one of proposals 41 to 43, in which the spiral spring is produced on a level different from that where the bearing surfaces of the ferrule are located to the balance shaft.
• 45.- Manufacturing process according to proposal 44, in which an SOI wafer is used as starting material, the SiO ₂ layer of which has a thickness greater than 3 microns.
• 46.- Oscillator comprising a monolithic assembly according to one of proposals 4 to 25 or 30 to 45 and a pendulum axis with a circular section.
• 47.- Timepiece movement or timepiece comprising a monolithic assembly according to one of proposals 4 to 25 or 30 to 45 or comprising an oscillator according to the previous proposal or comprising a ferrule according to one of proposals 1 to 3.

• figure 1 : une virole selon l'art antérieur EP 1 513 029 et EP 2 003 523 ;
• figure 2 : une virole de la figure 10D de l'art antérieur EP 1 655 642 ;
• figure 3 : une virole selon l'art antérieur WO2011026725 ;
• figure 4 : un ensemble monolithique ressort spiral double - virole à contour fermé selon l'invention ;
• figures 5 à 7 : d'autres ensembles monolithiques ressort spiral double - virole à contour fermé selon l'invention ;
• figure 8 : les principales étapes du procédé d'obtention d'un ensemble monolithique ressort spiral double - virole selon un second aspect de l'invention ;
• figures 9 à 11 : un ensemble monolithique ressort spiral double - virole selon un second aspect de l'invention ;
• figures 12 et 13 : d'autres ensembles monolithiques ressort spiral double - virole selon le second aspect de l'invention ;
• figure 14 : un graphe montrant l'évolution du couple de maintien M des viroles des ensembles des figures 12, 13 et 3 en fonction du diamètre de l'axe de balancier ;
• figure 15 : un graphe montrant l'évolution de la contrainte s des viroles des ensembles des figures 12, 13 et 3 en fonction du diamètre de l'axe de balancier ;
• figures 16 à 17 : une représentation des contraintes au sein des viroles des ensembles des figures 12 et 13 une fois un axe de balancier chassé dans l'ouverture (noir : très faible déformation élastique, contraintes inférieures à la moitié de la contrainte maximale ; en gris : déformation élastique significative, contraintes supérieures à la moitié de la contrainte maximale);
• figure 18 : une représentation des zones rigides (en noir) et flexibles (en gris) pour la virole de la figure 12 ;
• figure 19 : un ensemble monolithique ressort spiral double - virole selon une variante avantageuse du second aspect de l'invention, dans lequel les points d'attache des lames du spiral double sont proches de l'ouverture centrale ;
• figure 20 : une vue en coupe d'une virole selon une variante avantageuse du second aspect de l'invention ;
• figure 21 : un ensemble monolithique ressort spiral double - virole selon le premier aspect de l'invention avec indication de la position des points d'encastrement ; et
• figure 22 : un ensemble monolithique ressort spiral double - virole selon le second aspect de l'invention avec indication de la position des points d'encastrement.

Other characteristics and advantages of the invention will now be described in detail in the following description which is given with reference to the appended figures, which schematically represent:

• figure 1 : a ferrule according to the prior art EP 1 513 029 And EP 2 003 523 ;
• figure 2 : a ferrule of figure 10D of the prior art EP 1 655 642 ;
• picture 3 : a ferrule according to the prior art WO2011026725 ;
• figure 4 : a monolithic double spiral spring assembly - closed-contour ferrule according to the invention;
• figures 5 to 7 : other monolithic double spiral spring - closed-contour ferrule assemblies according to the invention;
• figure 8 : the main steps of the process for obtaining a monolithic double spiral spring - ferrule assembly according to a second aspect of the invention;
• figures 9 to 11 : a monolithic double spiral spring - ferrule assembly according to a second aspect of the invention;
• figures 12 and 13 : other monolithic double spiral spring - ferrule assemblies according to the second aspect of the invention;
• figure 14 : a graph showing the evolution of the holding torque M of the shells of the sets of figures 12, 13 And 3 depending on the diameter of the balance shaft;
• figure 15 : a graph showing the evolution of the stress s of the shells of the sets of figures 12, 13 And 3 depending on the diameter of the balance shaft;
• figures 16 to 17 : a representation of the stresses within the shells of the sets of figures 12 and 13 once a pendulum axis has been pushed into the opening (black: very low elastic deformation, stresses less than half the maximum stress; in grey: significant elastic deformation, stresses greater than half the maximum stress);
• figure 18 : a representation of the rigid (in black) and flexible (in gray) zones for the ferrule of the figure 12 ;
• figure 19 : a monolithic double spiral spring - ferrule assembly according to a variant advantageous of the second aspect of the invention, in which the points of attachment of the blades of the double hairspring are close to the central opening;
• figure 20 : a sectional view of a ferrule according to an advantageous variant of the second aspect of the invention;
• figure 21 : a monolithic double spiral spring - ferrule assembly according to the first aspect of the invention with indication of the position of the embedding points; And
• figure 22 : a monolithic double spiral spring assembly - ferrule according to the second aspect of the invention with indication of the position of the embedding points.

Detailed disclosure of the invention

On the figure 1 shown is the ferrule proposed in the aforementioned European patent applications EP 1 513 029 And EP 2 003 523 .

On the figure 2 is shown the ferrule described in Figure 10D of the aforementioned European patent application EP 1 655 642 .

On the picture 3 the ferrule proposed in the patent application is shown WO2011026725 .

The invention applies both to assemblies with a single hairspring and to those with a double hairspring. However, it is for the latter that it is best suited.

By "double hairspring", it is meant here a hairspring comprising two blades wound in the same direction, but with an offset of 180 degrees, as described in the application EP 2 151 722 A1 . The respective inner ends of these blades are integral with the ferrule and their respective attachment points are arranged symmetrically on opposite sides of the periphery of the ferrule.

The "attachment point" or "embedding point" of the hairspring is generally well defined in the case of a hairspring assembled on a ferrule made of a material other than the hairspring. In the case of a monolithic ferrule-hairspring assembly for which balance spring and ferrule have been manufactured, produced for example by a microfabrication technique from a Silicon wafer or "Silicon-on-Insulator", the point of Embedment can be defined as the point where the local stiffness along the neutral fiber reaches a value which is 10x higher than the stiffness of the hairspring blade. In the case of a hairspring with variable blade thickness, the minimum value of the local stiffness along the blade will be considered. The local stiffness is equivalent to the bending stiffness, determined during the bending of the blade or the operation of the hairspring, over a portion of given length, for example 1 μm. The corresponding embedding points 10,11 are indicated by way of example on the ferrule-spiral assemblies of the figures 21 and 22 . In the case of the figure 21 (which corresponds to the ferrule geometry of the figure 12 ), we see that the embedding point is located on the extension of the outer contour or periphery 32 of the ferrule. In the case of the figure 22 (which corresponds to the ferrule geometry of the figure 19 ), it can be seen that the embedding point is located in the immediate vicinity of the balance shaft, closer to the central opening of the ferrule than is the contour 33 of the level of the ferrule which does not include the spiral.

The ferrules according to the invention are dimensioned both to hold the hairspring on the balance shaft during operation of the oscillator, and also to be able to be assembled with shafts whose diameter shows a certain dispersion (no breakage or plastic deformation on driving out for a shaft diameter within a given tolerance interval). These shells normally have at least 2, and preferably 4, bearing surfaces for the balance shaft.

According to the invention, the precise shape of the connecting parts is not crucial, as long as they manage to deform elastically, in particular in bending, during the driving out of a balance shaft. Under normal conditions of use of the ferrule, the receiving parts are therefore rigid or non-deformable parts and the connecting parts, deformable parts, in particular deformable in bending or flexible. The flexibility of the latter comes from the fact that they are thinned with respect to the reception parts. The deformable parts have sections with smaller areas than the non-deformable parts. This thinning is achieved, according to the invention, by providing the deformable parts less wide than the receiving parts. By "width" is meant here the thickness measured in the plane of the ferrule, in other words, the distance between the contour of the ferrule and the contour of its central opening (for example, the minimum width e or e' or the width halfway between the rigid receiving parts b or b' on the figures 12 and 13 ).

The junctions between the receiving parts and the connecting parts are generally located substantially at the base of a support surface (see below, as well as at as examples, the figure 18 , or the figure 5 where they can be located each time on one side of the curved part 14). Preferably, it is sought to maximize the length of the connecting parts, therefore to maximize the angular sector that they occupy.

There figure 4 represents the central part of an example of a monolithic double spiral spring/unsplit ferrule assembly according to the invention.

As can be seen on the figure 4 , the shell 1, in particular the receiving parts 17,18, comprises two pairs of support points 2,3 and 4,5 located on substantially flat arms 6,7 and 8,9 which are not elastic and are placed two by two close to the attachment points 10,11 of the blades 12,13 of the double hairspring. The non-elastic arms of the same pair protrude into the central opening of the ferrule and they form between them an angle α which is preferably less than 170 degrees, more preferably greater than 90 degrees and less than 170 degrees, and is here about 120 degrees. Each arm 6,7,8 or 9 has a free end.

The V-shape of the pairs of rigid arms has the effect of better wedging the balance shaft than a single fulcrum would do. The important thing is in fact that the ferrule-axle embedding is as rigid as possible, so that the points of contact between the ferrule and the balance shaft do not move under the effect of the torque developed by the balance spring during operation in motion, that is to say during oscillations of the balance-spring once the balance-spring assembly - ferrule has been driven out or assembled on the axis of a balance wheel. The geometry with two reception parts facing each other (in particular at 180° from each other) and each comprising a pair of surfaces support can act as a vice held by the flexible connecting parts. Under the effect of their elastic deformation, the connecting parts exert elastic return actions bringing the receiving parts towards each other and each in contact against the balance shaft. Nevertheless, it is also possible (but less favourable) to use a single point of support, such as for example a flat, convex or concave contact surface with a radius of curvature greater than the radius which is provided for the axis of the balance.

On the figure 4 , the arms 6,7,8 and 9 and the corresponding support surfaces 2,3,4 and 5 are flat, that is to say that their radius of curvature on the side of the central opening 26 is infinite. The support surfaces can also be convex, that is to say that their radius of curvature can be negative on the side of the central opening 26, or concave, that is to say that their radius of curvature can be positive on the side of the central opening 26.

In the latter case, however, the positive radius of curvature is strictly greater than 0.51 times the diameter d _max of the largest circle that can be traced inside the contour of the central opening (when the ferrule n is not deformed, in particular when it is not mounted on the balance shaft), a circle which is also called an “inscribed circle” in the remainder of the description. Preferably, the positive radius of curvature is greater than 0.62 times the diameter d _max , which makes it possible to define a single point of contact between the support part and the balance shaft. A radius of curvature greater than 0.75 times, or even 1 time, the diameter d _max of the inscribed circle is also suitable. In the case of a balance shaft with a circular section, the shaft diameter is slightly greater than d _max , for example included in a tolerance interval between 1.01 and 1.02 d _max .

It is important to ensure that there is no flexible part between the ferrule/balance shaft contact points and the hairspring attachment point, so that the distance between the point of embedding or attachment and the bearing surfaces varies as little as possible and in particular does not vary substantially following driving in.

The shroud 1 has rotational symmetry of order 2, and has two axes of symmetry in reflection, one being formed by the bisector of the angle α, the other being perpendicular to the latter and located at an equal distance from the intersection of the arms. It can be considered that it comprises two rigid balance shaft receiving parts connected by two flexible connecting parts, as can be seen in the figure 18 which will be detailed below. The rigid parts 17 and 18 (in black on the figure 18 ) are those from which leave both the arms 6.7 and 8.9 and the blades 12 and 13 of the double hairspring. The flexible parts 15 and 16 (in gray on the figure 18 ) are connecting parts symmetrically connecting the rigid parts, so as to form the shell 1 with its central opening. These flexible parts are thinner than the rigid parts and their elasticity or flexibility makes it possible to ensure the deformation of the shroud 1 during driving in on the balance shaft while guaranteeing a minimum holding torque. In addition, the non-circular central opening makes it possible to offset the flexible parts and to maximize their length.

The symmetry of the geometry of the ferrule of the figure 4 aims to obtain a balance so as not to create any imbalance. The non-circular central opening of the ferrule may be defined as including a central recess 26 for receiving the balance shaft, substantially delimited by the 4 bearing surfaces 2,3,4 and 5, and two peripheral recesses 27,28 formed substantially and symmetrically between the arms 6,8, on the one hand and 7, 9 on the other hand, and the elastic parts 15 and 16. The recesses 27 and 28 are symmetrical to each other with respect to the bisector of the angle α.

Thus, the geometry makes it possible to precisely define the support points, four in number in the case of the figure 4 . The arms 6 to 9 make it possible to precisely define the bearing points of the ferrule on the balance shaft, while maximizing the length of the flexible elastic parts. On the other hand, these arms 6 to 9 do not flex or flex negligibly and cannot be considered as elastic arms.

This is confirmed by numerical simulations reported on the figures 16 and 17 , which indicate the stress levels present following the driving in of a balance shaft with a nominal diameter of 0.503 mm in two shells of different geometry shown on the figures 12 and 13 (you can also refer to figures 14 and 15 which indicate the holding torques and the maximum stresses for these shells for different shaft diameters). The parts which are not or only slightly deformed elastically, and which can be considered as being rigid, are indicated in black on the figures 16 and 17 (stress level less than half of the maximum stress reached following the driving out of the pin, i.e. approximately 500 MPa in the case of figures 16 and 17 ). The parts which are elastically deformed, and which can be considered as being flexible, are indicated in gray in the same figures (level of stresses greater than half of the maximum stress). These numerical simulations show that the arms 6 to 9 carrying the bearing surfaces are not elastically deformed, unlike the flexible parts 15,16. The distance between the support points and the attachment points of the hairspring is thus always constant and perfectly defined.

The ferrule is thus formed of two rigid balance shaft reception parts 17,18 symbolized in black on the figure 18 , connected to each other by two flexible or elastic connecting parts 15,16, symbolized in gray on the figure 18 . The advantage of this arrangement is to maximize the length of the flexible connecting parts, while guaranteeing a sufficient holding torque on the balance shaft, with a level of stress clearly lower than the maximum allowable stress for the material. The simulations show that the shroud according to the invention makes it possible to obtain a holding torque (M) on the axis that is higher than with flexible arms located inside a closed contour (for the same size). By the theory of small deformations applied to the case of a flexible beam, it can be shown that the holding torque M depends on the length of the flexible parts L, M being proportional to L ³ . The longer the flexible parts, the higher the holding torque. The advantage of the ferrule according to the invention is to maximize the length of the flexible parts. On the example of the figure 18 , the flexible parts occupy about 70% of the total length of the outline. Preferably, the flexible parts occupy 50% or more of the total length of the outline, in particular between 50% and 90%, more preferably between 60 and 80%. Alternatively, the angle sectors measured from the center of the ferrule (which corresponds to the center of the circle inscribed in the central opening) and occupied respectively by a rigid receiving part and by a flexible connecting part are approximately 54° and 126°. Preferably, the angle sector measured from the center of the shroud and occupied by a flexible connecting part is greater than or equal to 50°, in particular between 90° and 160°, more preferably between 110° and 145°. This angle sector is for example defined as the smallest continuous angle sector between two reception parts where there is a zone where the stress in the material is greater than 50% of the maximum stress reached following the driving out of the axis.

Another exemplary embodiment of the invention is shown in the figure 5 . In this figure, the shell comprises only one pair of non-elastic arms 2.3. Opposite the V formed by the latter, on the other side of the non-circular central opening, is a domed part 14 intended to serve as a third support surface for the balance staff. The geometry here comprises only a symmetry of reflection around the bisector of the angle α (if the point of attachment of the blades of the hairspring is not taken into account). The shape and dimensions of the domed part 14 are chosen so as to balance the ferrule as much as possible. Alternatively, the third bearing surface can also be flat or even concave, with a radius of curvature strictly greater than 0.51 times, preferably greater than 0.62, 0.75 or 1 time the inscribed diameter d _max .

The ferrule according to the invention is particularly suitable for attaching a double hairspring to a balance staff. Indeed, most of the ferrules known from the state of the art do not deform symmetrically with respect to the attachment points. With a ferrule like the one shown on the figure 1 , one of the blades would be fixed at the same point as the blade of the simple hairspring represented, ie at the top of the triangle formed by the stiffening structure. The second blade must have an attachment point located 180° from the first, or opposite, in the middle of one side of the triangle. The displacement of the attachment points following the driving in with respect to the center of the hairspring and/or to the external attachments would therefore not be equivalent for the two attachment points, which would degrade the chronometric performance. In addition, the embedding point of the second blade would be liable to deform during the expansion and contraction of the hairspring, which would also adversely affect chronometric performance.

Second aspect of the invention

According to another aspect, the invention relates to a shell having at least two levels or stages or parts. The point of attachment or anchoring of the hairspring (or the points of attachment in the case of a double hairspring) is then located on a level different from that where the major part, or even all of the surfaces of the spring are located. support. This is particularly applied to a monolithic spiral spring-shell assembly.

The inventors have in fact discovered that it was possible to maximize the torque resistance of the ferrule, while minimizing its bulk, by lengthening the ferrule in the plane perpendicular to the hairspring. This makes it possible to separate the function of attaching the hairspring to the shaft via the ferrule (first level, in the plane of the hairspring) from that of holding the shaft, in particular holding the ferrule on the shaft (first and second level, and preferably exclusively on the second level, outside the plane of the hairspring), while distributing the elastic stress in the most balanced way possible along the flexible parts.

A monolithic spiral spring-shell assembly corresponding to that of the figure 4 built on 2 levels is represented in front and rear perspectives on the figures 9 and 10 .

As can be seen in these figures, the sides are not perfectly superimposed, they have a shift of a few microns between the first and the second layer.

There figure 11 represents the entire spring-spring assembly according to the figures 9 and 10 , with the outer ends of the blades of the double hairspring which are integral with a fixing element intended to be connected to the movement of a timepiece.

It is obvious that such a monolithic hairspring-shell spring assembly produced on 2 levels can also be applied to other types of shells, in particular to split shells, and to other types of hairsprings, in particular to simple hairsprings.

Manufacturing process

The ferrule or the spiral-ferrule assembly can be manufactured according to known methods, such as that forming the subject of patent application no. EP 1 655 642 . The ferrule or the spiral spring-ferrule assembly according to the second aspect of the invention can be manufactured according to known methods, such as those forming the subject of patent applications no. EP 1 835 339 Or EP 2 104 007 .

The main stages of a process for manufacturing a ferrule or a monolithic spiral spring-ferrule assembly carried out on 2 levels, stages or parts are represented on the figure 8 .

The starting substrate used is a slice (“wafer” in English) of the “SOI” (“Silicon-on-Insulator”) type, composed of two parts of monocrystalline Si separated by a thin layer of silicon oxide, SiO ₂ ( figure 8a , with monocrystalline Si in white and SiO ₂ in oblique hatching). After a first cleaning, the wafer is oxidized to form a layer of SiO ₂ on the surface on either side of the substrate ( figure 8b ) which will serve as a mask for deep etching by reactive ions (“Deep Reactive Ion Etching”, “DRIE” in English). A photolithography is then carried out on a first face to define a first pattern in photoresist ( figure 8c , resin shown in hatched right) and this pattern is reproduced in the underlying oxide layer by dry etching ( figure 8d ). After cleaning ( figure 8e ), the same steps are reproduced on the second side with a second pattern: photolithography is used to define a second pattern in photosensitive resin ( figure 8f ), which is reproduced in the underlying oxide layer by dry etching ( figure 8g ). A deep DRIE etching step is then performed on the second side to etch the pattern in the second Si layer ( figure 8 o'clock ). Then, a deep DRIE etch is performed on the first layer ( figure 8i ). The exposed parts of SiO ₂ (outer layers and central layer) are finally dissolved by BHF attack (buffered HF, ie a mixture of HF and NH ₄ F which serves as a buffer to stabilize the attack rate; figure 8d ).

• le dépôt de couches fonctionnelles (oxydes, nitrures, couches à base de carbone) sur tout ou une partie de la surface, par exemple par des techniques de type PVD, CVD, ou ALD ;
• le dépôt d'une couche d'oxyde SiO₂ pour thermocompenser l'oscillateur balancier-spiral selon EP 1 422 436 ;
• la réalisation d'une partie de la structure, par exemple des bras 6,7,8 et 9, en métal ou alliage métallique par une technique d'électroformage de type LiGA.

Different steps additional to the methods set out above can be provided, such as for example (and in a non-limiting way):

• the deposition of functional layers (oxides, nitrides, carbon-based layers) on all or part of the surface, for example by techniques of the PVD, CVD or ALD type;
• the deposition of a layer of SiO ₂ oxide to thermocompensate the balance-spring oscillator according to EP 1 422 436 ;
• the production of a part of the structure, for example of the arms 6,7,8 and 9, in metal or metal alloy by a technique of electroforming of the LiGA type.

Advantageous variant of the second aspect of the invention

According to an advantageous variant of the second aspect of the invention, the ferrule has at least two levels, and the point of attachment or embedding of the hairspring (or the points of attachment in the case of a double hairspring) is located on a level different from that where the support surfaces are located and at a distance from the center of the ferrule less than the distance between the center of the ferrule and its contour or periphery.

As shown in figure 20 , the shell 100 comprises a bore 101 intended to receive the balance shaft, as well as at least a first part 102 and a second part 103. The first and second parts are separated by a plane 104 perpendicular to the axis 107 of the bore, this axis also representing the center of the ferrule. The element(s) 105 for attaching the ferrule to a spiral spring are located exclusively on the first part. The element 106 for connecting the ferrule to the balance shaft, for example formed from bearing surfaces, is essentially, preferably exclusively, located on the second part. By "an element connecting the ferrule to the balance shaft is essentially located on the second part”, it is meant that more than half of the forces connecting the ferrule to the balance staff are applied at the level of the second part. The bore 101 forms a central opening intended to receive the balance shaft.

Preferably, an SOI wafer is used to produce such a ferrule or a monolithic ferrule-hairspring assembly including such a ferrule, the first and the second part being made of silicon and separated by a layer of silicon oxide. Indeed, the use of SOI wafers where the internal layer of SiO ₂ separating the two layers of Si is thick, even very thick (for example 2-3 microns as usual, but preferentially of thickness greater than 5, even than 10 microns) makes it possible to produce a flexible shell superimposing the turns as shown in the figure 19 , which shows such a monolithic double spiral spring assembly - ferrule made on 2 levels. The flexible shell is in all respects similar to that of the figure 4 . On the other hand, the attachment points of the hairspring are not located on the contour as on the figure 21 , but as close as possible to the central opening of the ferrule and therefore to the balance staff, as in the example of the figure 22 . The blades of the hairspring are thus partially superimposed on the ferrule, over a little less than 180° in the example of the figure 19 (corresponding to a little less than half a winding turn of the hairspring blade). The two-level manufacturing process makes it possible to produce this kind of structure, because the dissolution attack of the SiO ₂ ( figure 8j ) will also attack the oxide which secures the blades to the shell if the attack time is sufficient, thus releasing the latter.

Thus, the attachment element of the hairspring to the ferrule or the embedding point 10, 11 is at a distance D1 of the axis of the bore 107 less than half the diameter D2 of a cylinder in which the second part fits, in particular at a distance D1 less than or equal to the average of half the diameter D2 and half the diameter of the inscribed circle dmax. This is the case for the spiral-shell assembly of the figure 22 , for which D1 is 0.330mm, while D2 is 1.180mm and the average of half the diameter D2 and half the diameter of the inscribed circle dmax is (1.180mm/2+0.495mm/2)/2 = 0.41875 mm. This is equivalent to placing the embedding point 10.11 to 85 microns away from the axis in the case of the figure 22 , against 275 microns in the case of the figure 21 . Alternatively, the embedding point is closer to the central opening than is the outline 33 of the ferrule.

A ferrule as described above can in particular be included in a monolithic spiral spring-ferrule assembly.

Bringing the attachment point closer to the balance wheel axis considerably improves the chronometric properties. Moreover, this type of approach is not limited to a double hairspring, but is also perfectly suitable for a single hairspring, and is not limited to a closed contour ferrule, but is also suitable for a split ferrule. Any combination of ferrule and hairspring can be obtained in this way, resulting in a balance spring-ferrule assembly with significantly improved chronometric properties.

Simulations

Simulations by the finite element technique were carried out on two monolithic spring assemblies double hairspring - two-piece unsplit ferrule, of the type shown in the figures 9 and 10 .

These two similar sets A and B are represented on the figures 12 and 13 . Their dimensions are comparable on several points: the size is 1.17mm along the major axis (dimension d in the figures), the distance c is 0.550mm, the diameter inscribed at the center of the opening is 0.495mm, l angle α is 120°, the radius of curvature of the outer contour at the top of the flexible connecting parts is 0.538 mm. Only the thickness of the flexible connection parts differs significantly: if we note b the width at the level of the top of the connection parts (that is to say in their middle, halfway from the reception parts) and e the minimum width of the connecting parts, b = 0.085mm and e = 0.050mm for the shell of the figure 12 and b' = 0.070mm and e' = 0.050mm for the shell of the figure 13 . The maximum width of the rigid receiving parts a also differs: a = 0.224mm for the shell of the figure 12 and a' = 0.200mm for the shell of the figure 13 , but the distance between the attachment points of the double hairspring is identical.

The layer height of the hairspring (first part) is 150 microns and the layer height of the level bearing the support surfaces (second part) is 500 microns.

The balance shafts have a tolerated diameter of between 0.5 and 0.506 mm, with a nominal value of 0.503 mm.

The graph of the figure 14 shows the evolution of the simulated holding torque M of the ferrule as a function of the diameter of the balance shaft for each of the hairspring/ferrule assemblies of the figures 12, 13 And 3 , respectively. The minimum holding torque is indicated on the figure 14 through the interrupted line.

It can be seen, for each of the assemblies, that the holding torque is greater than the minimum torque required, even for small diameters below the minimum tolerance.

The graph of the figure 15 shows the evolution of the stress s of the ferrule as a function of the diameter of the balance shaft for each of the hairspring/ferrule assemblies of the figures 12, 13 And 3 , respectively. The maximum allowable stress for the material (elastic limit, with a safety factor) is indicated by the broken line.

It is observed, for each of the assemblies according to the invention, that the maximum stresses are well below the maximum permitted value. The advantage of the ferrule of the figure 13 is that it is more flexible, that its level of stresses is lower and that the slope of the couple according to the diameter of the axis is weaker than for the ferrule of the figure 12 . As a corollary, the holding torque is lower.

For the assembly according to the prior art, on the other hand, the stress very quickly exceeds the maximum allowed value. It can therefore be seen that this type of ferrule is not suitable for assembly by driving in. In fact, such a geometry of the contour does not make it possible to ensure both good hold and deformation without breakage of the ferrule following the driving in of the balance shaft. In addition, the inscribed diameter is only 0.2 micron less than the lower limit of the tolerance so that the stresses are lower than the maximum allowable stress for the lower limit of the tolerance, which requires extremely precise manufacturing tolerances.

The same behavior is predicted for other shells of the prior art, such as that shown in Figure 10D of the document EP 1 655 642 . The increase in constraints with the diameter of the axis is less strong than for the case of the ferrule of the picture 3 , but the maximum admissible stress is nevertheless largely exceeded before reaching the upper limit of the tolerance.

This example illustrates the advantage of a closed-contour ferrule, with rigid receiving parts connected by flexible connecting parts. This difference in stiffness can be estimated as a first approximation by the theory of beams with small deformations: for a beam, the stiffness k of an element of width e, thickness h and length L is proportional to e ³ ×h/ L ³ . By making the approximation that the width e is constant along the parts, the ratio between the rigidity of a receiving part, k _r , and of a connecting part, k _f , is therefore equal to k _r /k _f = (e _r ³ ×h _r ×L _f ³ ) / (e _f ³ ×h _f ×L _r ³ ) = (e _r ³ ×L _f ³ ) / (e _f ³ ×L _r ³ ), if the thickness is identical. Reducing the average width of the connecting parts with respect to the receiving parts and maximizing the length of these same connecting parts thus makes it possible to very significantly reduce the rigidity of the connecting parts. Preferably, a k _r /k _f ratio greater than 10, more preferably greater than 50, even more preferably greater than 100 is chosen.

Since the rigidity depends on the cubed width, the difference in width between the rigid receiving parts and the flexible connecting parts is preferable to obtain a lower rigidity on the connecting parts than on the receiving parts.

Different possibilities exist to obtain a lower rigidity: thus, the average width of the connecting parts can be preferentially lower than the average width of the receiving parts, more preferably less by a factor of two than the average width of the receiving parts.

Alternatively or cumulatively, the two connecting parts have a minimum width and/or a width at mid-distance of the receiving parts that is less than the maximum width of the receiving parts.

The minimum width e of the connecting parts is then preferably less than 0.5×a, even more preferably equal to or less than 0.3×a, where a is the maximum width of the receiving parts.

Alternatively or cumulatively, the width in the middle of the connecting parts, halfway between the receiving parts, is preferably less than 0.7×a, even more preferably equal to or less than 0.5×a.

It is also possible to vary the thickness of the receiving parts and of the connecting parts, in particular by thinning the connecting parts with respect to the receiving parts, but it is more favorable to vary the width than the thickness in order to vary the rigidity.

Of course, those skilled in the art will be able to adapt the dimensions of the ferrule from case to case, depending on the thickness of the hairspring, the size available, taking care to ensure sufficient torque resistance and to maintain the constraints well below of the maximum allowable stress in order to remain in the elastic deformation domain.

The interest in a monolithic hairspring/shell assembly with at least two levels can be explained as follows. For a single-layer hairspring/ferrule assembly, the height is determined by the dimensions of the hairspring, among other things by the torque required and the size (diameter). The height of the ferrule, and therefore of the arms carrying the bearing surfaces and flexible parts, will necessarily be fixed by the height of the hairspring and cannot be freely adjusted. For a monolayer assembly 150 microns high, the holding torque values are lower by a ratio of 500/150 compared to a multilayer assembly equipped with a hairspring of the same height (150 microns), since the holding is performs on 150 microns instead of 500 microns. As a result, these holding torque values would be lower than the minimum value (broken line on fig. 14 ) required for shaft diameters close to the minimum tolerance (0.5 micron).

It is also possible to envisage carrying the support parts also by the level comprising the hairspring, which would make it possible in the example mentioned above to increase the holding torque values to a ratio of 650/150 compared to a together at one level. However, the tolerances of the manufacturing process make the production of continuous surfaces on two levels very delicate. It is therefore preferable to separate the functions of attaching the hairspring and connecting the ferrule to the balance staff on two distinct levels, and not to provide support parts on the level which presents the element or elements ( s) for attaching the ferrule to the spiral spring.

Thus, one way of increasing the holding torque of a single layer or stage ferrule is to increase the torque developed by the flexible parts without increasing the stress, which implies a larger diameter of the ferrule. This has the consequence that the point of attachment of the blades of the hairspring must be far from the balance axis, which degrades the chronometric properties.

It emerges from the foregoing that a monolithic hairspring/ferrule assembly with at least two levels, for example with two silicon stages separated by a layer of silicon oxide, offers the possibility of maximizing the holding torque by optimizing its size, that is to say by avoiding increasing the diameter of the ferrule. A shroud in which the second part 103 extends, along the axis of the bore 107, over a length greater than once the thickness E of the spiral spring, or even greater than 3 times the thickness E of the spiral spring, is therefore particularly suitable, in particular for forming a monolithic hairspring-shell assembly.

THE figures 6 and 7 represent variants of the monolithic hairspring/shell assembly according to the invention.

On the figure 6 , it can be seen that the elastic parts are curved at their center towards the inside of the peripheral recesses.

The monolithic 2-stage hairspring/ferrule assembly of the figure 7 has flexible parts that are not symmetrical.

Thermo-compensation of the hairspring of the single or double hairspring-shroud assembly is carried out by known means. It is for example possible to use a layer of material on the surface of the turns which compensates for the first thermal coefficient of the Young's modulus of the base material. In the case of an Si hairspring, a suitable material for the layer is SiO ₂ .

Preferably, in the different variants and embodiments, each connecting part is mainly stressed in bending, once the monolithic assembly is mounted on the balance shaft.

By "mainly stressed in bending", it is meant that, in each connecting part, one can identify a neutral fiber oriented substantially in a direction along which extends the connecting part and separating a zone stressed in tension, from a zone stressed in compression.

Preferably, in the different variants and embodiments, each connecting part has a portion remote from the balance shaft by at least 0.5 times the radius of the balance shaft, or even by at least 0.9 times the radius of the balance shaft, once the assembly is mounted on the balance shaft.

Preferably, in the different variants and embodiments, the receiving parts and the connecting parts form an element capable of continuously surrounding the balance shaft, that is to say capable of surrounding the shaft without topological interruption. of pendulum. They thus form a closed ferrule, as opposed to a split ferrule.

In this document, the term "non-deformable part" or "rigid part" means a part which does not deform or substantially does not deform during operation or during assembly of the monolithic assembly on the balance shaft or a part whose deformation is not desired and/or does not perform any function during operation or during assembly of the monolithic assembly.

In this document, the term "deformable part" means a part that deforms elastically during operation or during mounting of the monolithic assembly on the balance shaft or a part whose elastic deformation is sought or performs a function during operation or during assembly of the monolithic assembly.

• une première partie de réception destinée à venir en appui contre un axe de balancier,
• une deuxième partie de réception destinée à venir en appui contre l'axe de balancier,
• une première partie de liaison destinée à relier les première et deuxième parties de réception, et
• une deuxième partie de liaison destiné à relier les première et deuxième parties de réception.

According to one aspect of the invention, the monolithic spiral spring - ferrule assembly comprises:

• a first reception part intended to bear against a balance shaft,
• a second reception part intended to bear against the balance shaft,
• a first connecting part for connecting the first and second receiving parts, and
• a second connecting part intended to connect the first and second receiving parts.

These different parts are preferably included in a ferrule.

Claims (16)

Monolithic spiral spring - ferrule assembly (1) comprising: - a first reception part which does not deform or substantially does not deform during operation or during assembly of the monolithic assembly on the balance shaft and intended to bear against a balance shaft, - a second reception part which does not deform or substantially does not deform during operation or during assembly of the monolithic assembly on the balance shaft and intended to bear against the balance shaft, - a first connecting part deforming elastically during operation or during assembly of the monolithic assembly on the balance shaft and intended to connect the first and second reception parts, - a second connecting part deforming elastically during operation or during assembly of the monolithic assembly on the balance shaft and intended to connect the first and second reception parts, and - an element capable of continuously surrounding the balance shaft and comprising the receiving parts and the connecting parts. Monolithic assembly according to claim 1, in which: - the connecting parts occupy 50% and more, even between 50% and 90%, or even between 60% and 80%, of the total length of the outer contour of the ferrule, and/or - each connecting part occupies an angle sector measured from the center of the ferrule greater than or equal to 90°, or even between 90° and 160°, or even between 110° and 145°, and/or - each connecting part has a portion remote from the balance shaft by at least 0.5 times the radius of the balance shaft, or even at least 0.9 times the radius of the balance shaft, once the assembly mounted on the balance shaft, and/or - the receiving parts face each other, in particular at 180° from each other with respect to the center of the ferrule, and/or - each connecting part is mainly stressed in bending, once the monolithic assembly is mounted on the balance shaft. Monolithic assembly according to one of Claims 1 to 2, in which: - a leaf of the spiral spring is attached or linked directly to a receiving part, in particular, in the case of an assembly comprising a double balance spring, in which each leaf is attached to a different receiving part, and/or - a central opening of the ferrule intended to receive a balance shaft is non-circular, and/or - the contour of the central opening of the shell (1) comprises, on the same receiving part, at least one bearing surface (2.3; 4.5) for the balance shaft. Monolithic assembly according to one of Claims 1 to 3, in which the contour of the central opening of the shell (1) comprises, on the same receiving part, at least one pair of bearing surfaces (2.3; 4.5) for the balance shaft, the tangents to the bearing surfaces (2.3) at the points of support of this pair forming between them an angle (α) greater than 90 degrees and less than 170 degrees. Monolithic assembly according to one of Claims 1 to 4, in which the contour of the central opening of the ferrule (1) comprises two pairs (2,3; 4,5) of bearing surfaces. Monolithic assembly according to one of Claims 1 to 5, in which the bearing surfaces (2,3; 4,5) are at least partially located on arms (6,7; 8,9) or extensions extending from the body of the receiving parts. Monolithic assembly according to one of Claims 4 to 6, in which the bearing surfaces are flat or negatively curvature or positively curvature with a radius greater than 0.51 times the diameter (d _max ) of the circle inscribed in an opening center of the ferrule. Monolithic assembly according to one of Claims 1 to 7, in which: - two reception parts are arranged at 180° from each other with respect to the axis of the shell, and/or - the different connecting parts have an identical geometry and/or the different receiving parts have an identical geometry. Monolithic assembly according to one of Claims 1 to 8, in which: - the spiral spring is a double spiral spring comprising a first leaf whose point of attachment (10) to the ferrule (1) is connected to a first receiving part and a second leaf whose point of attachment (11) to the ferrule (1) is connected to a second reception part, and/or, - the assembly being made of silicon, optionally with an outer layer and/or an inner layer of silicon oxide, and/or - the assembly being made of a fragile material or of a material having no plastic deformation range. Monolithic assembly according to one of Claims 1 to 9, the geometry of the ferrule of which has a reflection symmetry of order 2 and/or the geometry of the ferrule of which has a rotational symmetry of order 2. Monolithic assembly according to one of Claims 1 to 10, in which the attachment point(s) of the single or double hairspring is (are) closer to the central opening of the ferrule than is the outline of the ferrule. Monolithic assembly according to one of Claims 1 to 11, the assembly comprising a ferrule (100) comprising a bore (101) intended to receive a balance shaft, at least a first part (102) and a second part (103) , the first and second parts being separated by a plane (104) perpendicular to the axis (107) of the bore, an element (105) for attaching the ferrule to a spiral spring being located exclusively on the first part and an element (106) for connecting the ferrule to the balance shaft being essentially, or even exclusively, located on the second part. Method of manufacturing a monolithic assembly according to claim 12, in which the spiral spring is produced on a part different from that where the contact surfaces of the ferrule are located against the balance shaft. Manufacturing process according to claim 13, in which an SOI wafer is used as starting material, the SiO ₂ layer of which has a thickness greater than 3 microns. Oscillator comprising a monolithic assembly according to one of Claims 1 to 12 and a balance shaft of circular section. Timepiece movement or timepiece comprising a monolithic assembly according to one of Claims 1 to 12 or comprising an oscillator according to the preceding claim.

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