CH708669A2 - assembly system using an elastic locking element plane. - Google Patents

Abstract

The invention relates to an assembly system (1) comprising a member (3) made of at least a first material comprising an axis (2) and a bearing surface (4), the axis (2) of the member ( 3) being received in the opening of a workpiece (5) in a second material having no or little plastic field. According to the invention, the assembly system (1) comprises a locking element (9) made of a third material arranged for elastically attaching the piece (5) between the bearing surface (4) of said member and the locking element (9). ) and in that the locking element (9) is a washer whose inner wall radially clamps the axis (2) of said member and whose peripheral portion exerts an axial and resilient force in line with the bearing surface (4). ) of said member to make integral the assembly member (3) - piece (5) - locking element (9). The invention relates to the field of fragile parts, especially in watchmaking.

Description

Description

Field of the invention

The invention relates to an assembly system using a substantially flat elastic locking element for assembling a workpiece whose material does not have a usable plastic field, that is to say with a plastic field very restricted, with a member comprising another type of material.

Background of the invention

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

Summary of the invention

The object of the present invention is to overcome all or part of the disadvantages mentioned above by proposing an assembly without adhesive capable of securing a part whose material does not have a plastic field with a member comprising a ductile material such as, for example , a metal or a metal alloy

For this purpose, the invention relates to an assembly system comprising a member in at least a first material having an axis and a bearing, the axis of the member being received in the opening of a part in a second material characterized in that the assembly system comprises a locking element in a third material arranged to elastically attach the part between the bearing surface of said member and the locking element and in that the locking element is a washer whose inner wall radially clamps the axis of said member and whose peripheral portion exerts an axial force and resilient to the plumb with the bearing of said member to make integral the member-piece locking member assembly.

This configuration advantageously allows to secure the whole body - piece - blocking element without bonding with a usual member to the controlled precision while ensuring that the part does not undergo destructive efforts even if it is formed, for example , from a silicon-based material. Indeed, the Applicant was surprised to be able to secure the whole body - piece - blocking element, in particular in relative rotation, with such great structural simplicity because the prejudices of mechanical strength of the parts in particular from silicon-based materials so far, it was necessary not to provide axial force on a piece made of material having no or little plastic area.

According to other advantageous features of the invention:

the third material comprises a metal or a metal alloy whose resistance to relaxation, after 10,000 hours at a temperature of 70 ° C., is at least equal to 50% of the applied force representing 75% of the stress required to obtain 0.2% plastic deformation of the third material in order to maintain the fastening of the whole body

- part - locking element;

the third material comprises copper, brass, nickel silver, arcap alloy, pfinodal alloy, spinodal alloy, durnico alloy, durimphy alloy, carbon alloy; Be and / or 20AP steel;

the section along an axial section plane of the blocking element comprises a ratio of the height with respect to the width of between 0.1 and 5;

- The locking element is chamfered to prevent breakage of the second material;

the second material is based on silicon such as silicon, quartz, silicon oxide, silicon nitride or silicon carbide;

said at least one first material comprises a metal or a metal alloy;

- the axis and the reach came form.

In addition, the invention relates to a timepiece characterized in that it comprises at least one assembly system according to one of the preceding variants, the part having no plastic field can be a wheel, anchor or hairspring.

Finally, the invention relates to a method of manufacturing an assembly system comprising the following steps: a) forming a member in at least a first material having an axis and a bearing, a second material part with an aperture and a washer-shaped locking member based on a third material and whose hole is smaller than the axis of said member; b) pass without stress the axis of said member in the opening of the room; c) locating the pin against the hole of the locking member and forcibly sliding the locking member against the pin with a tool to deform the locking member so that the peripheral portion of the locking member the blocking element is closest to the part; d) stopping and removing said tool when a predetermined force and less than the yield stress of the third material is reached between the tool and the bearing of said member.

This method advantageously makes it possible to simply make, elastically and without possible relative displacement, the whole body - piece - blocking element. Indeed, advantageously according to the invention, only one

2 blocking element is attached and deformed to induce a solely elastic peripheral nip. It is also understood that such a method makes it possible to secure the assembly member - piece - blocking element by adapting to the manufacturing dispersions of the various constituents.

Finally, surprisingly, the axial force exerted by the peripheral portion of the locking element during the process does not cause breakage of the second material based on having no or little plastic field. This technical advantage makes it possible to simplify considerably the assembly of parts having no or little plastic domain on a pivoting axis. It is understood in particular that it is not necessary to provide glue, additional locking cap or additional overlapping shapes to secure the pieces together and, in particular, as to the relative displacements about the axis of rotation of the pivoting axis.

According to other advantageous features of the invention:

step d) is stopped when the force applied by said tool is between 20% and 90% of the elastic limit stress of the third material;

the third material comprises a metal or metal alloy whose resistance to relaxation, after 10,000 hours at a temperature of 70 ° C., is at least equal to 50% of the force applied during step d) representing 75 % of the stress necessary to obtain 0.2% of plastic deformation of the third material in order to maintain the fastening of the member - piece - locking element assembly;

the third material comprises copper, brass, nickel silver, arcap alloy, pfinodal alloy, spinodal alloy, durnico alloy, durimphy alloy, carbon alloy; Be and / or 20AP steel;

the section along an axial section plane of the blocking element comprises a ratio of the height with respect to the width of between 0.1 and 5;

- The locking element is chamfered to prevent breakage of the second material;

the second material is based on silicon such as silicon, quartz, silicon oxide, silicon nitride or silicon carbide;

said at least first material comprises a metal or a metal alloy;

- The piece is a watchmobile, a watch anchor or a clockwork hairspring.

Brief description of the drawings

Other features and advantages will become apparent from the description which is given below, for information only and in no way limitative, with reference to the accompanying drawings, in which: FIG. 1 fig. 2 fig. 3 figs. 4 to 8 figs. 9 and 10 is a perspective view of a locking element according to the invention; is a sectional view along an axial plane of a locking element of FIG. 1; is a graphical representation of the force applied during the process as a function of the axial position of the tool exerting said force; are schematic sectional views of successive steps of the method according to the invention; are partial schematic views of a watch movement comprising assembly systems according to the invention.

Detailed Description of the Preferred Embodiments

As explained above, the invention relates to a system for assembling a workpiece whose material does not comprise a usable plastic field, that is to say with a very restricted plastic field, with an organ comprising another type of material.

This assembly system has been devised for applications in the watchmaking field. However, other areas can perfectly be imagined as including aeronautics, jewelry, automotive or the arts of the table.

In the field of watchmaking, this assembly is made necessary by the growing share of fragile materials such as those based on silicon such as monocrystalline silicon (or polycrystalline) doped or not, silicon oxide as quartz or silica, monocrystalline or polycrystalline corundum or more generally alumina, silicon nitride and silicon carbide. By way of example, it is possible to envisage forming the hairspring, the balance, the anchor, the bridges or even the mobiles such as the escape wheels wholly or partly 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 not having 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 usable 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.

For this reason, the invention relates to an assembly system 1, 101, 121, 201 comprising a member 3, 103, 123, 203 in at least one first material having an axis 2, 102, 1 12, 202 and a scope 4, the axis 2 of the member being received in the opening 6 of a part 5, 105, 205 in a second material having no or little plastic field.

It is therefore understood that the axis 2, 102, 122, 202 and the scope 4 may have come form with the aid of a single first material or that the axis 2, 102, 122, 202 and the scope 4 of the member 3, 103, 123, 203 may be formed from several materials and / or parts.

Advantageously according to the invention, the assembly system 1, 101, 121, 201 comprises a locking element 9, 109, 129, 209 in a third material arranged to elastically attach the part 5, 105, 205 between the scope 4 of the member 3, 103, 123, 203 and the locking element 9, 109, 129, 209. As best seen in FIG. 8, advantageously according to the invention, the part 5 is pinched against the bearing surface 4 of the member 3 by the elastic force of the locking element 9. It is immediately understood the simplicity of the assembly system 1, 101, 121, 201 according to the invention which does not require glue, additional locking cap or complementary forms overlap or plastic deformation as creep.

Preferably according to the invention, the locking element 9, 109, 129, 209 is a washer whose inner wall

10 radially clamps the axis 2, 102, 122, 202 of the member 3, 103, 123, 203 and whose peripheral portion 13 exerts an axial and elastic force in line with the bearing surface 4 of the member 3, 103, 123, 203 to make integral the entire member 3, 103, 113, 203 - part 5, 105, 205 - blocking element 9, 109, 129, 209.

In figs. 1 and 2, it can also be seen that the locking element 9, 109, 129, 209 has a top surface

1 1 intended to come into contact with a preferably flat tool 15 and a lower surface 12 intended to come into contact with the upper surface of the part 5, 105, 205.

Indeed, as explained below, surprisingly, the axial force exerted by the peripheral portion 13 of the locking element 9, 109, 129, 209 during the process does not cause breakage of the second. material not having a plastic field. This technical advantage makes it possible to considerably simplify the assembly of parts 5, 105, 205 on an axis 2, 102, 122, 202, for example, pivoting. This advantage is obtained in particular because the peripheral portion 13 of the locking element 9, 109, 129, 209 presses the bearing surface 4 and not cantilevered the span 4. It is therefore important that the surface of the blocking element 9, 109, 129, 209 does not exceed that of the span 4.

In the example illustrated in FIGS. 1 and 2, the locking element 9 is symmetrical, that is to say that the surfaces 1 1 and

12 can be indifferently the one above or below. However, this symmetry is only optional and applied preferentially to avoid handling errors during manufacture.

The elastic mounting of the locking element 9, 109, 129, 209 is advantageously obtained by using a third material which comprises a metal or a metal alloy whose resistance to relaxation is at least equal to 50% of the applied force. The tests making it possible to determine this percentage were carried out after 10Ό00 hours at a temperature of 70 ° C. and under a force of 75% of the stress necessary to obtain 0.2% of plastic deformation, that is to say substantially 75%. % of the elastic limit of the third material.

This resistance greater than 50% was observed when the third material comprises copper, brass, nickel silver, arcap alloy and even greater than 85% when the third material comprises the pfinodal alloy, the spinodal alloy, durnico alloy, durimphy alloy, Cu-Be alloy and 20AP steel.

For considerations specific to watchmaking, the locking element 9, 109, 129, 209 is, even more preferably, selected from the above materials which do not have ferromagnetic properties to be not very sensitive to magnetic fields, that is to say copper, brass, nickel silver, arcap alloy, pfinodal alloy, spinodal alloy, Cu-Be alloy and durimphy alloy.

As best seen in FIGS. 1 and 2, preferably according to the invention, the section along an axial section plane of the locking element 9, 109, 129, 209 comprises a ratio (H / L) of the height H with respect to the width L between 0 , 1 and 5. Thus, it is important to choose the length L to have a peripheral portion 13 sufficiently far from the center of the axis D to obtain a sufficiently high lever arm to provide sufficient clamping to the joining. At the same time, a height H must also be well chosen to have a minimum height to sufficiently protect the second material having no or little plastic field and a maximum height to always obtain the intermediate deformation explained below. It is therefore understood that the H / L ratio must be adapted according to the intended applications.

According to another preference, the locking element 9, 109, 129, 209 is chamfered to prevent breakage of the second material having no or little plastic field. Indeed, as explained below according to the geometry of the intermediate deformation, a chamfer can prevent the blocking element 9, 109, 129, 209 coming into contact on the upper surface of the part 5, 105, 205 by a sharp edge clean to generate too much stress and / or pressure on a minimum surface.

Thus, advantageously according to the invention, said at least first material formed for the member 3, 103, 123, 203 may comprise a large variety of material such as, for example, a metal or a metal alloy.

The method of manufacturing a first embodiment of assembly system 1 according to the invention illustrated in FIG. 9 is explained below with reference to FIGS. 3 to 8.

The method comprises a first step a) of forming each part of the assembly system 1. Thus, step a) comprises a phase intended to form a member 3 in at least a first material having an axis 2 and a bearing 4 having shape or not, a second phase intended to form a piece of second material having no or little plastic field such as, for example, based on silicon with an opening 6 and a third phase intended to form a blocking element 9 in the form of a washer based on a third material and whose hole 8 is smaller than the axis 2 of the member 3. It is understood that, during step a), the order of execution of the phases is of no importance.

The method continues with a second step b) consisting of passing without stress the axis 2 of the member 3 in the opening 6 of the part 5. This step b) is viewable in FIG. 4.

Step c) continues the process and comprises a first phase intended to place the axis 2 against the hole 8 of the locking element 9. This first phase of step c) can also be seen in FIG. . 4. In this fig. 4, there is also a tool 15. This tool 15 is preferably flat, that is to say has a substantially flat surface 14 intended to come into contact with the upper face 1 1 of the locking element 9. Note as well as if the locking element 9 is symmetrical as illustrated in FIGS. 1 and 2, the mounting errors between the upper face 1 1 and the lower face 12 are eliminated.

Step c) continues with a second phase for sliding the blocking element 9 against the axis 2 with the aid of the tool 15 in order to deform the locking element 9 so that the peripheral portion 13 of the locking element 9 is closest to the part 5 as illustrated in FIG. 5. We understand that this second phase could be likened to hunting.

This elastic intermediate deformation, which may cause occasional plastic deformations at the inner wall 10, gives the impression that the locking element 9 is a Belleville washer. However, this geometry is not stable, that is to say not a plastic deformation such as creep, and only induced by the force of the tool 15. This elastic intermediate deformation is made maximum by the use of the hole 8 of the locking element 9 smaller than the axis 2 of the member 3 and the use of the tool 15 whose surface 14 is substantially flat.

This elastic intermediate deformation is of great importance for the future assembly system 1 in that it applies the future axial stress to the part 5 as shown in FIG. 6, not closer to the axis 2 but, via the bottom lever width L of the locking element 9, at the peripheral portion 13 of the locking element 9. It is therefore clear that the section of the scope 4 of the member 3 must also preferably be substantially equal to or greater than that of the locking element 9 to allow the peripheral portion 13 to exert an axial and elastic force beyond the scope 4 of the body 3.

In a simple manner, the process ends with step d) of stopping and removing the tool 15 when a predetermined force lower than the yield stress of the third material is reached between the tool 15. and the bearing surface 4 of the member 3. Indeed, once the elastic nip is operated between the peripheral portion 13 of the locking element 9 in line with the bearing surface 4 of the member 3, the tool 15 is used to bring the inner wall 10 closer to the workpiece 5 without exceeding, at the peripheral portion 13, the elastic limit stress of the third material used for the locking element 9.

It is therefore understood that once the tool 15 removed, it is not desired that the entire width L of the lower face 12 of the locking element 9 exerts a constraint against the part 5 but only or mainly the peripheral portion 13. The fastening of the assembly member 3 - part 5 - blocking element 9 is therefore exerted solely or mainly by an axial and elastic force of the peripheral portion 13 of the blocking element 9 to the plumb the bearing 4 of the member 3 conjugated to the radial clamping of the inner wall 10 of the locking element 9 against the axis 2 of the member 3.

FIG. 3 is a graphical representation of the force applied by the tool 15 during the above process as a function of the axial position of the tool 15. From arrow A, the second phase of step c) starts as illustrated in fig. 5. From the arrow B, the peripheral portion 13 of the locking element 9 starts to pinch the part 5 as illustrated in FIG. 6. From the arrow C, the inner wall 10 of the locking element 9 is brought to the maximum of the part 5 as shown in FIG. 7 and any additional force of the tool 15 exerts an internal stress of the locking element 9 without impact on the geometry of the locking element 9.

It is therefore understood that the steps of the manufacturing process and the elements of the assembly system are very simple and easy to implement. Thus, according to a first embodiment illustrated in FIG. 9, it is possible to fix a hairspring 5 on a balance shaft 2, using an assembly system 1 according to the invention. To do this, the ferrule 7 of the spiral 5 is secured between the pivot 3 and the locking element 9.

In order to minimize the risk of plastic deformation of the locking element 9, 109, 129, 209, step d) is stopped when the force applied by the tool 15 is between 20% and 90% of the elastic limit stress of the third material. Of course, the percentage must be adapted according to the intended application. During the tests, it appeared that the stopping of step d) was entirely satisfactory when the force applied by the tool 15 is substantially equal to 75% of the elastic limit stress of the third material.

As explained above, the elastic mounting of the locking element 9, 109, 129, 209 is advantageously obtained by using a third material which comprises a metal or a metal alloy whose resistance to relaxation is at a minimum. less than 50% of the applied force. The tests to determine this percentage were carried out after 10,000 hours at a temperature of 70 ° C. and under a force of 75% of the stress necessary to obtain 0.2% of plastic deformation.

The resistance greater than 50% was observed when the third material comprises copper, brass, nickel silver, arcap alloy, and even greater than 85%, when the third material comprises pfinodal alloy, spinodal alloy, durnico alloy, durimphy alloy, Cu-Be alloy and 20AP steel.

For considerations specific to watchmaking, the locking element 9, 109, 129, 209 is, even more preferably, selected from the above materials which do not have ferromagnetic material to be not very sensitive to magnetic fields, that is to say copper, brass, nickel silver, arcap alloy, pfinodal alloy, spinodal alloy, Cu-Be alloy and durimphy alloy.

As best seen in FIGS. 1 and 2, preferably according to the invention, the section along an axial section plane of the locking element 9, 109, 129, 209 comprises a ratio (H / L) of the height H with respect to the width L included between 0, 1 and 5. Thus, it is important to choose the length L to have a peripheral portion 13 sufficiently far from the center of the axis D to obtain a sufficiently high lever arm to provide sufficient stress to the bonding. At the same time, a height must also be well chosen to have a minimum height to sufficiently protect the second material having no or little plastic field and a maximum height to always obtain the intermediate deformation explained below. It is therefore understood that the H / L ratio must be adapted according to the intended applications.

According to another preference, the locking element 9, 109, 129, 209 is chamfered to prevent breakage of the second material. Indeed, as explained above according to the geometry of the intermediate deformation, a chamfer can prevent the blocking element 9, 109, 129, 209 coming into contact on the upper surface of the part 5, 105, 205 by a sharp edge clean to generate too much stress on a minimal surface.

Thus, advantageously according to the invention, said at least one first material formed for the member 3, 103, 123, 203 may comprise a large variety of material such as, for example, a metal or a metal alloy. It is therefore understood that the axis 2, 102, 122, 202 and the bearing surface 4 can be integrally formed using a single first material or that the axis 2, 102, 122, 202 and the bearing surface 4 of the member 3, 103, 123, 203 may be formed from several materials and / or parts.

It is also understood that, thanks to the method according to the invention, the second material having no or little plastic domain may include, in particular, silicon, quartz, corundum, silicon oxide, nitride silicon or silicon carbide without risk of breakage.

FIG. 10 shows other embodiments of assembly systems 101, 121, 201 according to the invention in the field of watchmaking. An anchor 105, for example, may comprise two assembly systems 101, 121 according to the invention intended respectively to secure the stinger 103 and the rod 123, with the rod 107.

As shown in FIG. 10, each assembly system 101, 121 comprises the rod 107 which is secured between the axis 102 of the rod 103 or the axis 122 of the rod 123 and the locking element 109, 129. It is thus clear that each system assembly 101, 121 is sufficiently resistant not to generate relative movements between its components.

In the same figure, an escape wheel, and more generally the wheel 205, comprises, for example, an assembly system 201 for securing a pivot 203, with the wheel 205. As visible at fig. 10, the assembly system 201 comprises a hub 207 which is secured between the axis 202 of the pivot 203 and the locking element 209.

It is therefore clear immediately that the assembly system example 201 can be applied to any type of mobile. In addition, the axis 203 may comprise in one piece a pinion to form a finished mobile.

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 locking element 9, 109, 129, 209 may comprise a different geometry without departing from the scope of the invention.

The tool 15 could also include a substantially conical surface 14 to substantially follow the shape of Belleville washer obtained during the intermediate elastic deformation.

In addition, the opening 6 of the part 5, 105, 205 can not be limited to a circular shape and / or the part 5, 105, 205 may be partially perforated below the blocking element 9, 109, 129, 209. Thus, by way of example, the hairspring 5 of FIG. 9 could be replaced by the hairspring 10 comprising a ferrule 41 whose opening is substantially trefoil of EP 2365 762, incorporated by reference in the present patent application, without removing the advantages mentioned above.

6

Claims (23)

Finally, other "fragile" materials than those based on silicon or alumina are possible such as, for example, ceramics based on zirconium or titanium, or glasses. The locking element 9, 109, 129, 209 may also be formed based on amorphous metals also called metallic glasses. claims Assembly system (1, 101, 121, 201) comprising a member (3, 103, 123, 203) in at least one first material having an axis (2, 102, 122, 202) and a bearing surface (4), the axis (2, 102, 122, 202) of the member (3, 103, 123, 203) being received in the opening (6) of a workpiece (5, 105, 205) in a second material characterized in that the assembly system (1, 101, 121, 201) comprises a blocking element (9, 109, 129, 209) of a third material arranged for elastically attaching the part (5, 105, 205) between the bearing surface ( 4) of said member and the blocking member (9, 109, 129, 209) and in that the blocking element (9, 109, 129, 209) is a washer whose inner wall (10) radially seals axis (2, 102, 122, 202) of said member and whose peripheral portion (13) exerts an axial and elastic force in line with the bearing surface (4) of said member in order to make the entire member (3, 103, 123, 203) - part (5, 105, 205) - element blocking means (9, 109, 129, 209). 2. Assembly system (1, 101, 121, 201) according to the preceding claim, characterized in that the third material comprises a metal or a metal alloy whose resistance to relaxation, after 10,000 hours at a temperature of 70 ° C, is at least equal to 50% of the applied force representing 75% of the stress necessary to obtain 0.2% of plastic deformation of the third material in order to maintain the joining of the whole body (3, 103, 123, 203) - part (5, 105, 205) - locking element (9, 109, 129, 209). 3. Assembly system (1, 101, 121, 201) according to the preceding claim, characterized in that the third material comprises copper, brass, nickel silver, arcap alloy, pfinodal alloy, the spinodal alloy, durnico alloy, durimphy alloy, Cu-Be alloy and / or 20AP steel. 4. Fitting system according to one of the preceding claims, characterized in that the section along an axial section plane of the locking element (9, 109, 129, 209) comprises a ratio (H / L) of the height (H) with respect to the width (L) of between 0.1 and 5. 5. Assembly system (1, 101, 121, 201) according to one of the preceding claims, characterized in that the locking element (9, 109, 129, 209) is chamfered to prevent breakage of the second material . 6. Assembly system (1, 101, 121, 201) according to one of the preceding claims, characterized in that the second material is based on silicon. 7. Assembly system (1, 101, 121, 201) according to the preceding claim, characterized in that the second material comprises silicon, quartz, silicon oxide, silicon nitride or silicon carbide. 8. Assembly system (1, 101, 121, 201) according to one of the preceding claims, characterized in that said at least one first material comprises a metal or a metal alloy. 9. Assembly system (1, 101, 121, 201) according to one of the preceding claims, characterized in that the axis (2, 102, 122, 202) and the bearing (4) have come form. 10. Timepiece characterized in that it comprises at least one assembly system (1, 101, 121, 201) according to one of the preceding claims. 11. Timepiece according to the preceding claim, characterized in that the piece of a second material is a mobile (205), an anchor (105) or a spiral (5). 12. A method of manufacturing an assembly system (1, 101, 121, 201) comprising the following steps: a) forming a member (3, 103, 123, 203) in at least one first material comprising an axis ( 2,102, 122, 202) and a bearing surface (4), a second material part (5, 105, 205) with an opening (6) and a locking element (9, 109, 129, 209) base of a third material and whose hole (8) is smaller than the axis (2, 102, 122, 202) of said member; b) pass without stress the axis (2, 102, 122, 202) of said member in the opening (6) of the part (5, 105, 205); c) placing the shaft (2, 102, 122, 202) against the hole (8) of the locking element (9, 109, 129, 209) and forcibly sliding the locking element (9, 109, 129, 209) against the axis (2, 102, 122, 202) by means of a tool (15) for deforming the locking element (9, 109, 129, 209) so that the peripheral portion (13) the locking element (9,109,129,209) is closest to the workpiece (5,105,205); d) stopping and removing said tool when a predetermined force and less than the yield stress of the third material is reached between the tool (15) and the bearing (4) of said member. 13. The manufacturing method according to the preceding claim, characterized in that step d) is stopped when the force applied by said tool is between 20% and 90% of the yield stress of the third material. 14. The manufacturing method according to claim 12 or 13, characterized in that the third material comprises a metal or a metal alloy whose resistance to relaxation, after 10,000 hours at a temperature of 70 ° C, is at least equal to 50% of the force applied in step d) representing 75% of the stress required to 7 to obtain 0.2% of plastic deformation of the third material in order to maintain the fastening of the whole member (3, 103, 123, 203) - piece (5, 105, 205) - locking element (9, 109, 129) , 209). 15. Manufacturing method according to the preceding claim, characterized in that the third material comprises copper, brass, nickel silver, arcap alloy, pfinodal alloy, spinodal alloy, Durnico alloy. , durimphy alloy, Cu-Be alloy and / or 20AP steel. 16. The manufacturing method according to one of claims 12 to 15, characterized in that the section along an axial section plane of the locking element (9, 109, 129, 209) comprises a ratio (H / L). the height (H) relative to the width (L) between 0, 1 and 5. 17. Manufacturing process according to one of claims 12 to 16, characterized in that the locking element (9, 109, 129, 209) is chamfered to prevent breakage of the second material. 18. Manufacturing process according to one of claims 12 to 17, characterized in that the second material is based on silicon. 19. The manufacturing method according to the preceding claim, characterized in that the second material comprises silicon, quartz, silicon oxide, silicon nitride or silicon carbide. 20. The manufacturing method according to one of claims 12 to 19, characterized in that said at least first material comprises a metal or a metal alloy. 21. The manufacturing method according to one of claims 12 to 20, characterized in that the piece is a watch mobile (205). 22. Manufacturing process according to one of claims 12 to 20, characterized in that the piece is a clock anchor (105). 23. Manufacturing process according to one of claims 12 to 20, characterized in that the piece is a clockwork spiral (5). 8