EP2656150B1 - Assembly process of a component which does not have a plastic domain - Google Patents

Description

Field of the invention

The invention relates to an assembly of a part whose material does not comprise a plastic field with a member comprising another type of material.

Background of the invention

Current assemblies comprising a silicon-based part are generally bonded together. Such an operation requires extreme finesse of application which makes it expensive.

Document CH 700 260 gives an example of a current assembly. It discloses a rocker mounted elastically and then stuck on a tree.

Summary of the invention

The object of the present invention is to overcome all or part of the disadvantages mentioned above by proposing a glueless assembly capable of securing a part whose material does not include a plastic field with a member comprising a ductile material such as, for example, a metal or a metal alloy.

1. a) former la pièce avec une ouverture et des ajourages distribués autour de l'ouverture destinés à former des moyens de déformation élastique ;
2. b) introduire sans contrainte, dans l'ouverture, une partie évasée radialement dudit organe ;
3. c) déformer élastiquement et plastiquement la partie évasée dudit organe dans l'ouverture par rapprochement axial de deux outils respectivement au niveau des parties supérieure et inférieure de ladite partie évasée afin d'exercer une contrainte radiale contre la paroi de la pièce entourant l'ouverture en sollicitant lesdits moyens de déformation élastique de la pièce pour permettre de solidariser l'assemblage de manière non destructive pour ladite pièce.

For this purpose, the invention relates to a method for assembling an axially extending member made of a first material in a part made of a second material that does not comprise a plastic field, said method comprising the following steps:

1. a) forming the part with an opening and cut-outs distributed around the opening to form elastic deformation means;
2. b) introducing without constraint, in the opening, a flared portion radially of said member;
3. c) elastically and plastically deforming the flared portion of said member in the opening by axial approximation of two tools respectively at the upper and lower portions of said flared portion in order to exert a radial stress against the wall of the part surrounding the opening by soliciting said elastic deformation means of the workpiece to allow the assembly to be non-destructively joined to said workpiece.

This method advantageously makes it possible to radially fasten the member and the workpiece without any axial force being applied to the workpiece. Indeed, advantageously according to the invention, only a radial elastic deformation is applied to the workpiece. Finally, such a method makes it possible to secure the whole piece - organ by adapting to the manufacturing dispersions of the various constituents.

• la paroi externe de la partie évasée dudit organe dans l'ouverture est sensiblement de forme correspondante à l'ouverture de la pièce afin d'exercer une contrainte radiale sensiblement uniforme sur la paroi de la pièce entourant l'ouverture ;
• l'ouverture de la pièce est circulaire ;
• l'ouverture de la pièce est asymétrique afin d'éviter les déplacements relatifs entre les éléments dudit assemblage ;
• lors de l'étape b), la différence entre la section de l'ouverture circulaire et la section externe de la partie évasée dudit organe dans l'ouverture est d'environ 10 µm ;
• lors de l'étape c), la déformation exerce un serrage compris entre 8 et 20 µm ;
• lors des étapes b) et c), la partie évasée de l'organe dans l'ouverture est maintenue dans l'ouverture à l'aide d'un des deux outils ;
• le deuxième matériau est formé à base de silicium ;
• le premier matériau est formé à base de métal ou d'alliage métallique ;
• la pièce peut être, par exemple, un mobile d'horlogerie, une ancre d'horlogerie, un spiral d'horlogerie, un résonateur ou encore un MEMS.

According to other advantageous features of the invention:

• the outer wall of the flared portion of said member in the opening is substantially of a shape corresponding to the opening of the part in order to exert a substantially uniform radial stress on the wall of the part surrounding the opening;
• the opening of the room is circular;
• the opening of the part is asymmetrical in order to avoid relative displacements between the elements of said assembly;
• during step b), the difference between the section of the circular opening and the external section of the flared portion of said member in the opening is about 10 microns;
• during step c), the deformation exerts a tightening of between 8 and 20 μm;
• during steps b) and c), the flared portion of the member in the opening is held in the opening with one of the two tools;
• the second material is formed based on silicon;
• the first material is formed of metal or metal alloy;
• the piece may be, for example, a watch mobile, a watch anchor, a watch winder, a resonator or a MEMS.

Brief description of the drawings

• la figure 1 est une vue schématique partielle d'un mouvement horloger comportant trois assemblages selon l'invention ;
• la figure 2 est une vue schématique partielle d'un spiral horloger comportant un quatrième assemblage selon l'invention ;
• les figures 3 à 6 sont des vues de variantes selon un premier mode de réalisation de moyens de déformation élastique selon l'invention ;
• les figures 7 et 8 sont des vues de variantes selon un deuxième mode de réalisation de moyens de déformation élastique selon l'invention ;
• les figures 9 à 11 sont des représentations schématiques d'étapes successives du procédé d'assemblage selon l'invention.

Other particularities and advantages will emerge clearly from the description which is given hereinafter, by way of indication and in no way limiting, with reference to the appended drawings, in which:

• the figure 1 is a partial schematic view of a watch movement comprising three assemblies according to the invention;
• the figure 2 is a partial schematic view of a watch hairspring comprising a fourth assembly according to the invention;
• the Figures 3 to 6 are views of variants according to a first embodiment of elastic deformation means according to the invention;
• the Figures 7 and 8 are views of variants according to a second embodiment of elastic deformation means according to the invention;
• the Figures 9 to 11 are schematic representations of successive steps of the assembly method according to the invention.

Detailed Description of the Preferred Embodiments

As explained above, the invention relates to an assembly and its method for joining a fragile material, that is to say not having a plastic domain such as a material based on silicon, with a ductile material such as a metal or a metal alloy.

This assembly was designed for applications in the watchmaking field. However, other areas can be perfectly imagined such as aeronautics, jewelery, automotive and tableware.

In the field of watchmaking, this assembly is made necessary by the growing share of fragile materials such as those based on silicon, quartz, corundum or more generally ceramic. One can for example consider forming the hairspring, the balance, the anchor, bridges or even mobiles such as exhaust wheels totally or partially based on fragile materials.

However, the fact of always being able to use usual steel axes whose production is controlled, is a constraint that is difficult to reconcile with the use of parts that do not include a plastic field. Indeed, during tests carried out, the driving of a steel shaft is impossible and systematically breaks the fragile parts, that is to say not having a plastic field. For example, it has been found that the shear generated by the entry of the metal axis into the opening of a silicon part breaks the latter systematically.

This is why the invention relates to an assembly between an axially extending member made of a first material, for example ductile such as steel, in the opening of a part made of a second material that does not include a domain. plastic, as a silicon-based material, by deformation of a portion of the member which is mounted in the opening of said piece.

According to the invention, said member comprises a radially flaring portion and elastically and plastically deformed in order to clamp radially the wall of said part surrounding the opening by biasing its elastic deformation means to non-destructively fasten the assembly for said part.

In addition, preferably, the outer wall of the radially flaring portion of the member present in the opening is substantially of corresponding shape to the opening of the part in order to exert a radial stress. substantially uniformly on the wall of the room surrounding said opening. Indeed, during the research carried out, it appeared preferable that the flared portion of the member present in the opening evenly distribute the radial stresses induced by its deformation on the wall of the room surrounding the opening.

Therefore, if the opening in the fragile part is circular, it is preferable that the outer wall of the flared part of the member present in the opening is in substantially continuous cylinder shape, that is to say without radial slot or axial opening, to avoid localized stresses on part of the wall of the room surrounding the opening which are suitable for initiating break points.

Of course, the shape of the opening in the fragile part may differ in being, for example, asymmetrical in order to avoid relative displacements between the elements of the assembly. Such an asymmetric opening can thus be, for example, substantially elliptical.

This interpretation also justifies the non-use of a washer on the upper or lower part of the flared portion of the member present in the opening. Indeed, during the deformation, such a washer would transmit a portion of the axial strain force on the top (or bottom) of the fragile part. Therefore, the shear exerted in particular by the edges of the washer on the top (or bottom) of the fragile part generates in the same manner localized stresses suitable to initiate break points.

Therefore, the flared portion of the member present in the opening with a shape corresponding to the opening can be interpreted, if the section of the opening is circular, as a solid disc whose outer wall is continuous, c that is to say without groove or more generally material discontinuity. The corresponding shape of the flared part of the member present in the opening thus makes it possible, by elastic and plastic deformation, to generating only substantially uniform radial stress on a maximized surface of the wall of the workpiece around the opening.

Finally, according to the invention, the piece comprises perforations forming elastic deformation means which are distributed around and away from its opening and which are intended to absorb said radial forces to restore them once the stress of the tools released in order to, in the end, fasten the assembly non-destructively for said part.

The assembly according to the invention will be better understood in relation to the Figures 1 to 8 presenting examples of applications in the field of watchmaking. We can see at the figure 1 , a watch exhaust system comprising an anchor 1 and an escape wheel 3 and at the figure 2 , a spiral 61.

In the case of figure 1 , the anchor 1 as an example comprises two assemblies 2, 12 according to the invention intended respectively to secure the stinger 7 and the member, here a pivot axis 17, with its rod 5. As visible in FIG. figure 1 each assembly 2, 12 comprises a radially flaring portion 4, 14, substantially discoidal shaped with the stinger 7 or the member 17 and cooperating with the rod 5 of the anchor 1. In addition, each assembly 2, 12 comprises perforations 6, 16 made in the rod 5 around an opening 8, 18 and which are intended to form elastic deformation means. It is therefore understood that the assembly 2, 12 is sufficiently strong not to generate relative movements between its components.

The escape wheel 3, and more generally the mobile 3, comprises, by way of example, an assembly 22 intended to secure the member, here a pivot axis 27, with the body 25 of the wheel 3. As visible to the figure 1 , the assembly 22 comprises a radially flaring portion 24, substantially discoidal in shape with the member 27 and cooperating with the body 25 of the wheel 3. In addition, the assembly 22 comprises cut-outs 26 made in the hub around an opening 28 of the wheel 3 and which are intended to form elastic deformation means.

It is therefore immediately understood that the example of the assembly 22 can be applied to any type of mobile. In addition, the member 27 may comprise, in addition to the flared portion 24, in one piece a pinion to form the finished mobile.

As illustrated in figure 2 it is possible to fix a hairspring 61 on a member, here a balance shaft 67, with the aid of an assembly 62 according to the invention. Cut-outs 66 are formed in ferrule 63 of hairspring 61 and a disc-shaped portion 64 formed integrally with member 67 is mounted in aperture 68 of ferrule 63, similarly to the explanations above.

Examples of openwork are presented to Figures 3 to 8 . According to a first embodiment illustrated in Figures 3 to 6 , the perforations are formed at a distance and around the opening by two series of diamond-shaped holes distributed in a staggered manner to form beams divided into V secants.

The figure 3 is a representation of the perforations 6, 16, 26, 66 of figures 1 and 2 . For simplicity only the references of the wheel 3 are included in the figure 3 . The latter shows cutouts 26 which, preferably, completely cross the thickness of the body 25 of fragile material. The perforations 26 are distributed at a distance and around the opening 28 formed, preferably, also completely through in the thickness of the body 25 of fragile material.

As visible at figure 3 , the perforations 26 form a first series of holes 31, furthest from the opening 28, and a second series of holes 33 which are diamond-shaped and distributed in staggered rows. We notice at the figure 3 that the perforations 31, 33 thus form V-shaped beams 32 which are intersecting with each other.

In a first variant of the first embodiment illustrated in FIG. figure 4 , the perforations 26 'take up the first and second series of holes 31, 33 with, in addition, a third series which, formed of holes 35 in the form of a triangle, is located between the first two series and the opening 28, c' that is to say the closest to the opening 28. As visible in the figure 4 the third set of holes 35 is staggered with one of the first two sets to form beams 34 distributed in intersecting X's.

In a second variant of the first embodiment illustrated in FIG. figure 5 , the cut-outs 26 "repeat the cut-outs 26 'of the figure 4 with, in addition, slots 36 for communicating the third set of holes 35 with the opening 28.

Advantageously according to the invention, the series of holes 31, 33 and 35 and the slots 36 are used to form elastic deformation means capable of absorbing radial stresses, that is to say forces exerted from the center of the opening 28 to the wall of the body 25 surrounding said circular opening.

Of course, the two or three series may be more or less close to each other and / or different shapes and / or different dimensions depending on the desired maximum displacement and the desired stress to deform the beams 32, 34.

For example, an alternative of the figure 5 is presented to the figure 6 . It can be seen that the cut-outs 26 '"are similar to those 26" of the figure 5 however, the three sets of holes are spaced apart from each other. In addition, it is visible that the shapes and dimensions of both holes and slots are different. So we understand that the alternative of figure 6 modifies the rigidity of the elastic deformation means in the brittle material.

Preferably, the cut-outs 26, 26 ', 26 ", 26"' extend over a width of between 100 μm and 500 μm from the wall of the body 25 surrounding the opening 28. In addition, the slots 36 are between 15 microns and 40 microns. Finally, preferably, the section of the opening 28 is between 0.5 and 2 mm.

According to a second embodiment illustrated in Figures 7 and 8 , the perforations are formed at a distance and around the opening by a first series of oblong holes distributed in staggered rows with a second series of triangular shaped holes, the second series being the closest to the circular opening, each form hole triangular communicating with the opening by a notch to form radially movable beams according to the thickness of the oblong holes.

So, the figure 7 shows cutouts 46 which, preferably, completely cross the thickness of the body 25 of fragile material. The perforations 46 are distributed at a distance and around the opening 28 formed, preferably, also completely through in the thickness of the body 25 of fragile material.

As visible at figure 7 , the perforations 46 form a first series of oblong holes 51 and a second series of holes 53 of triangular shape. According to the second embodiment, the two sets of holes 51, 53 are distributed in staggered rows.

In addition, each hole 53 of triangular shape communicates with the opening 28 by a notch 57. It can be seen at figure 7 that the perforations 46 thus form substantially trapezoidal beams 52 which are separated from each other by the notches 57. It is also noted that each beam 52 is centered on an oblong hole 51 which makes each beam 52 mobile radially according to the thickness an oblong hole 51.

In a variant of the second embodiment illustrated in FIG. figure 8 , the openwork 46 'reproduce the cut-outs 46 of the figure 7 with, in addition, a third series of holes 55 in the form of a triangle. In addition, each hole 55 of the third series is distributed between two holes 53 of triangular shape of the second series and communicates with the opening 28 by a slot 56. The perforations 46 'thus form beams 54 with two independent arms symmetrical and substantially L-shaped which are movable radially according to the thickness of the holes 51 oblong and tangentially according to the thickness of slots 56 and notches 57.

Of course, as for the first embodiment, the two or three series may be more or less close to each other and / or different shapes and / or different dimensions depending on the desired maximum travel and the desired stress for deform the beams 52, 54.

Preferably, the openings 46, 46 'extend over a width of between 100 μm and 500 μm from the wall of the body 25 surrounding the opening 28. In addition, the slots 56 and the notches 57 are between 15 μm. and 40 μm. Finally, preferably, the section of the opening 28 is between 0.5 and 2 mm.

The assembly process will now be explained in relation to the schematic figures 9 to 11. For simplicity, only the references of the wheel 3 are included in the drawings. Figures 9 to 11 . According to the invention, a first step consists in forming the part 3 in a material having no plastic domain with an opening 28 and perforations 26 distributed around the opening 28 intended to form elastic deformation means according to, for example, for example, the embodiments explained above. As visible at figure 9 , the opening 28 has a section e ₁ and the perforations 26 include in particular holes of section e ₂ .

Such a step can be carried out by etching in dry or wet form, such as, for example, a deep reactive ion etching (also known as the English abbreviation "DRIE").

In addition, in a second step, the method consists in forming the axially extending member, a pivot axis 27 in the example of the Figures 9 to 11 , in a second material with a main section e ₃ and a radially flared portion 24 intended to be deformed with a maximum section e ₄ . The portion 24 may have a thickness between 100 and 300 microns. As explained above, the second step can be performed according to the usual processes for producing axes. The member 27 is preferably metallic and may, for example, be formed of steel.

Of course, the first two steps have no consecutivity to respect and can even be performed at the same time.

In a third step, the flared portion 24 is introduced without contact into the opening 28. This means as visible at the figure 10 that the section e ₁ of the opening 28 is greater than or equal to the outer section e ₄ of the flared portion 24 of the member 27.

Preferably, the difference between the section e ₁ of the opening 28 and the outer section e ₄ of the flared portion 24 is about 10 μm, that is to say a gap of about 5 μm which separates the body 25 of the piece 3 with respect to the flared portion 24 of the member 27.

In addition, preferably according to the invention, the flared portion 24 and, incidentally, the member 27, is held in the opening 28 with a 21 of the tools 20, 21 used for the deformation step. Finally, preferably, the tool 21 comprises a recess 29 intended to receive a part of the member 27.

Finally, the method comprises a fourth step of elastically and plastically deforming the flared portion 24 of the member 27 by bringing the tools 20, 21 in the axial direction A in order to exert a uniform radial stress B against the wall of the part 3 surrounding the opening 28 by biasing the means of elastic deformation of the part 3, that is to say the cut-outs 26.

So, as visible at the figure 11 pressing the deformed flared portion 24 at its upper and lower portions, respectively by the tool 20 and 21 in the axial direction A will induce an elastic and plastic deformation of the flared portion 24 in an exclusively radial manner in the direction B, that is to say towards the body 25.

In a preferred manner according to the invention, the deformation is parameterized so that the tightening is greater than the gap between the undeformed flared portion 24 and the wall of the body 25 surrounding the opening 28. Preferably, the tightening is between 8 and 20 μm.

Therefore, it is desired that the elastic and plastic deformation of the flared portion 24 exerts the elastic deformation of the body 25 around the opening 28 in order to secure together the member 27 and therefore its flared portion 24 deformed, with the body 25 of the wheel 3 as visible to the figure 11 . It should be noted that this embodiment allows in particular an automatic centering of the entire body 27 - body 25. As such, at the figure 11 it is noted that the perforations 26 comprise a section referenced e ₅ and no longer e ₂ .

Advantageously according to the invention, it is possible to secure the member 27 of any side of the body 25 of the wheel 3. In addition, no axial force (by definition likely to be destructive) is applied to the body 25 of the wheel 3 during the process. Only a radial elastic deformation is applied to the body 25. It should also be noted that, preferably, the use of the radially flared portion 24 allows, during the radial deformation B of the flared portion 24, to exert a uniform stress on a maximized surface of the wall of the body 25 around the opening 28 to prevent any breakage of the wheel 3 of fragile material and adapt to the manufacturing dispersions of the various elements.

Of course, the present invention is not limited to the illustrated example but is susceptible of various variations and modifications that will occur to those skilled in the art. In particular, the perforations of the piece of fragile material may comprise more or fewer series of holes than the modes of realization presented above. In addition, the presented embodiments are capable of being combined with one another according to the intended applications.

The radially flared portion 24 may also comprise a different geometry in order to optimize or "program" the deformation towards the body 25. It may be, for example, considered to minimize or locally increase the thickness of the flared portion 24 in order to favor one direction of deformation with respect to the other in the direction B. For example, it is thus possible to make a conical recess and coaxial with the member 27 to facilitate the radial orientation B but also to make the progressive induced stress.

The figures 1 and 2 have applications for an exhaust system such as the anchor 1 and the escape wheel 3 or a hairspring 61 of a watch movement. Of course, the present assembly 2, 12, 22, 62 can be applied to other elements. One can, in a non-exhaustive way, consider forming a pendulum, a bridge or more generally a mobile with an assembly 2, 12, 22, 62 as explained above.

It is also possible to use the assembly 2, 12, 22, 62 instead of the elastic deformation means 48 or the cylinders 63, 66 of the document WO 2009/115463 in order to fix a resonator type balancer - spiral monobloc on a pivot axis.

Of course, two parts as described above can also be secured on the same axis with two separate assemblies 2, 12, 22, 62 to secure their respective movement. It is then understood that the same axis will be formed with two radially flared portions 4, 14, 24, 64 intended to be deformed.

Finally, the assembly 2, 12, 22, 62 according to the invention can also allow the joining of any type of watchmaking member or not whose body is formed of a material having no plastic field (silicon, quartz, etc.) with an axis such as, for example, a resonator of the type tuning fork or more generally a MEMS (acronym from the English term "Micro-Electro-Mechanical System").

Claims (14)

1. Method of assembling an axially extending member (7, 17, 27, 67) made of a first material in a part (1, 3, 61) made of a second material having no plastic domain, including the following steps:

   a) forming the part (1, 3, 61) with an aperture (8, 18, 28, 68) and pierced holes (6, 16, 26, 26', 26", 26"', 46, 46', 66) distributed around the aperture (8, 18, 28, 68) intended to form elastic deformation means;

   b) inserting a radially flared portion (4, 14, 24, 64) of said member into the aperture (8, 18, 28, 68) without any stress;

   c) elastically and plastically deforming the flared portion (4, 14, 24, 64) of said member in the aperture by moving two tools (20, 21) towards each other axially, respectively on the top and bottom parts of said flared portion, so as to exert a radial stress (B) against the wall of the part (1, 3, 61) surrounding the aperture (8, 18, 28, 68), by stressing said elastic deformation means of the part (1, 3, 61), in order to secure the assembly (2, 12, 22, 62) in a manner that is not destructive for said part.
2. Method according to the preceding claim, characterized in that the shape of the external wall of the flared portion (4, 14, 24, 64) of said member substantially matches the aperture (8, 18, 28, 68) of the part (1, 3, 61), so as to exert a substantially uniform radial stress (B) on the wall of the part (1, 3, 61) surrounding the aperture (4, 14, 24, 64).
3. Method according to claim 1 or 2, characterized in that the aperture (8, 18, 28, 68) of the part (1, 3, 61) is circular.
4. Method according to claim 1 or 2, characterized in that the aperture (8, 18, 28, 68) of the part (1, 3, 61) is asymmetrical to prevent any relative movement between the elements of said assembly.
5. Assembly method according to any of the preceding claims, characterized in that, in step b), the difference between the section (e₁) of the circular aperture (8, 18, 28, 68) and the external section (e₄) of the flared portion (4, 14, 24, 64) of said member in the aperture is approximately 10 µm.
6. Assembly method according to any of the preceding claims, characterized in that, in step c), the deformation exerts a clamping force which generates a displacement comprised between 8 and 20 µm.
7. Assembly method according to any of the preceding claims, characterized in that, in steps b) and c), the flared portion (4, 14, 24, 64) of the member (7, 17, 27, 67) in the aperture is held in the aperture (8, 18, 28, 68) via one of the two tools (20, 21).
8. Assembly method according to any of the preceding claims, characterized in that the second material is silicon-based.
9. Assembly method according to any of the preceding claims, characterized in that the first material is formed from a metal or metal alloy base.
10. Assembly method according to any of the preceding claims, characterized in that the part is a timepiece wheel set (3).
11. Assembly method according to any of claims 1 to 9, characterized in that the part is timepiece pallets (1).
12. Assembly method according to any of claims 1 to 9, characterized in that the part is a timepiece balance spring (61).
13. Assembly method according to any of claims 1 to 9, characterized in that the part is a resonator.
14. Assembly method according to any of claims 1 to 9, characterized in that the part is a MEMS.

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