CH700528A2 - Clock movement for timepiece, has bridge mounted on mainplate using fixation devices and formed from silicon based micro-machinable material plate, where bridge and bearings are formed as single piece to support part of movement - Google Patents

Abstract

The movement has a bridge (1) mounted on a mainplate using fixation devices (2, 4, 6), where the bridge is formed from a silicon based micro-machinable material plate. The bridge and bearings (8, 10) are formed as a single piece for supporting a part of the movement. Each bearing comprises a cushion forming hole formed by etching. The bridge has a hole comprising two sections forming a shoulder. The shoulder serves as a stop for a screw head that maintains the bridge against the mainplate. An independent claim is also included for a method for fabricating a bearing in a micro-machinable element.

Description

Field of the invention

The invention relates to a bridge or a platen of micro-machinable material comprising a one-piece bearing for the manufacture of a watch movement.

Background of the invention

It is known to make metal bridges such as brass to support rotations of at least one pivot of a watch movement mobile, the other pivot of said mobile being supported by the plate. The pivots are generally supported in bearings reported in the bridges and the plate. The bearings usually used include at least one ruby pad, also called stone, which is used for its very good tribological characteristics.

In some watch movements, the fineness of the case makes it necessary to make bridges and / or a plate of very small thicknesses. The board of bridges and / or platinum, that is to say the thinnest part, becomes very difficult to machine and work. In fact, during the application of the machining tool or the tool for driving the stone, a phenomenon of voilage can appear and cause flatness losses of precision positioning of said elements.

Summary of the invention

The object of the present invention is to overcome all or part of the disadvantages mentioned above by providing a bridge or a plate having a one-piece bearing for a watch movement whose flatness and accuracy are improved despite its small thickness.

For this purpose, the invention relates to a watch movement comprising at least one bridge mounted on a plate with the aid of at least one fastening device characterized in that said at least one bridge or plate is made from a plate of a micro-machinable material and that said at least one bridge or plate comprises at least one bearing formed in one piece with said at least one bridge to support at least one member of said movement . This advantageously makes it possible to obtain a monobloc member of high precision and the disadvantages of which are induced by mounting steps are avoided.

According to other advantageous features of the invention: said at least one bearing comprises a hole forming a pad made by etching to dispense with a dedicated staking; the wall of said bearing hole comprises a coating for improving the tribological qualities with respect to said micro-machinable material; said bearing hole comprises at least one olivage or at least one oiler for reducing friction; the micro-machinable material is based on silicon.

The invention also relates to a timepiece characterized in that it comprises a watch movement according to one of the preceding variants.

Finally, the invention relates to a method of manufacturing a bearing in a micro-machinable element characterized in that it comprises step a): perform an etching to form the bearing hole of said bearing .

According to other advantageous features of the invention: the etching is performed by a deep reactive ion etching of the anisotropic type; the method further comprises, after step a), step b): performing a second etching to form an olivage coaxially with said hole; the method further comprises, after step a), step b '): performing a second etching to form an oiler coaxially with said hole; the second etching is performed by deep reactive ion etching of the isotropic type; the second etching is carried out by a succession of reactive ion etching of the anisotropic type, the leading section of which is successively reduced; the second etching is performed by electroerosion; the method further comprises the final step c): forming a coating on the wall of said bearing hole with a better coefficient of friction than said micro-machinable element; step c) comprises phase d): performing a physical vapor deposition of a material of better tribological quality with respect to said micro-machinable material; the micro-machinable material is based on silicon; step c) comprises the step e): oxidizing said silicon-based material to form said coating of better tribological quality.

Brief description of the drawings

Other features and advantages will clearly be described in the following description, by way of indication and in no way limiting, with reference to the accompanying drawings, in which: <tb> fig. 1 <sep> is a perspective view from above of a bridge according to the invention; <tb> fig. 2 <sep> is a perspective view from below of a bridge according to the invention; <tb> fig. 3 <sep> is a top view of a bridge according to the invention; <tb> fig. 4 <sep> is a representation according to section A-A of FIG. 3; <tb> fig. <Sep> is a block diagram of the process of the invention.

Detailed Description of the Preferred Embodiments

As illustrated in FIGS. 1 to 4, the element chosen for the explanation of the invention is a watch movement bridge generally annotated 1 and intended for a timepiece. However, it is understood that the invention is also applicable to the platen of a watch movement or platinum of said movement comprising the bridge cited above.

The bridge 1 comprises three bases 3, 5, 7 above which extends the board 9 of said bridge. Preferably, the three bases 3, 5, 7 and the plate 9 are monoblock. In the example illustrated in FIG. 3, it can be seen that the board 9 has a general crescent shape.

Advantageously, the bridge 1 is made from a plate of a micro-machinable material to provide flatness and improved accuracy. Such a micro-machinable material may be based on silicon, crystalline silica or crystallized alumina. In fact, the micromachining of a plate whose faces are already flat, such as for example a silicon wafer, makes it possible to guarantee very good ratings.

In addition, the working precision of the micro-machinable material is obtained through a process using a dry or wet attack that avoids the application of local force for the removal of material. These processes are widely used in particular for engraving computers and processors in microelectronics and guarantee a precision of etching below a micrometer. Preferably, an attack of the deep reactive ion etching type, also known under the terms "Deep Reactive Ion Etching" (DRIE), is used.

One of the known processes consists, firstly, to coat a protective mask on the surface of the micro-machinable plate, for example, using a photolithography process of a photosensitive resin. In a second step, the mask-plate assembly is subjected to an attack of the DRE type, only the parts of the unprotected plate being etched. Finally, in a third step, the protective mask is removed. It is therefore understood that the protective mask directly determines the final shape of the elements etched on the plate. It is thus possible to carry out any form precisely.

Therefore, the blank of the bridge 1 and / or the same plate very thin, ie about 0.4 mm, allows through the use of a micro-machinable material to obtain very precise dimensions with very good mechanical strength. It is therefore understood in the example illustrated in FIGS. 1 to 4, that the blank can be obtained, at first, by the global engraving of the crescent moon shape, then, in a second step, by the selective removal of a part of the thickness so to distinguish a thickness for the bases 3, 5, 7 and a smaller thickness for the board 9.

Advantageously, it is also possible during the roughing to make recesses on the upper part of the board 9 to improve the aesthetic effect of said movement. Indeed, for example, a numbering, a mark and / or decorations can also be engraved in all or part of the thickness of the element with precision.

Preferably, in the example illustrated in FIGS. 1 to 4, the manufactured element is a bridge 1 which comprises three fasteners 2, 4, 6 for securing the bridge 1 to a plate (not shown) by screwing. Thus, each fixing device 2, 4, 6 has a hole 11 in the bridge 1 and, in a known manner, a screw (not shown) intended to cooperate in rotation with a threaded recess (not shown) in the plate. Obtained by means of a photolithography and DRE attack process, the hole 11 in the bridge 1 comprises two distinct sections forming a shoulder 13 intended to serve as a stop for the screw head allowing, after screwing, the holding of the bridge 1 against the platinum.

Preferably, the shoulder 13 comprises a coating 15 for receiving the clamping force of the head of said screw. Indeed, for example, silicon has almost no plastic deformation domain. Thus, the silicon breaks rapidly if an induced stress exceeds its yield strength. Preferably, therefore, the coating 15 which comprises a ductile material for each fixing device 2, 4, 6 so as not to damage the bridge 1 is used.

Preferably, the coating 15 may include but not limited to gold, copper, nickel or alloys NiP, TiW, AuCr. It may be formed on the shoulder 13, for example, by vapor deposition such as a cathode sputtering in a thickness, for example, at least equal to 5 microns.

Each fixing device 2, 4, 6 may also comprise a foot assembly - recess between said at least one bridge and said plate in order to properly position the two latter before fixing them. In the example illustrated in FIG. 2, it can be seen that the fixing device 4 comprises a blind recess 12 intended to cooperate with a foot of the plate.

Preferably, in the example illustrated in FIGS. 1 to 4, the bridge 1 which also comprises two bearings 8, 10 for supporting two distinct pivots of at least one member of said watch movement. It is understood that these bearings 8, 10 are also applicable to the plate of a watch movement or to the plate of said movement comprising the bridge 1 cited above.

Advantageously according to the invention, each bearing 8, 10 is made in one piece with the bridge 1, that is to say without the use of stones. Each bearing 8, 10 thus comprises a hole 17 forming a pad, that is to say that its wall 19 is used as a sliding surface for the rotation of said organ pivots.

Preferably, if the tribological qualities of the material used are not very good, the wall 19 of the hole 17 comprises a coating intended to reduce the coefficient of friction and thus reduce friction with its associated pivot. As explained below, such a coating may comprise silicon dioxide, a nickel-phosphorus-based alloy or a diamond-like carbon (DLC which is an abbreviation of the English term "diamond like carbon").

In addition, preferably, the hole 17 comprises an olivage and / or an oiler 21, at least at its upper part, which is intended to reduce the friction surface with said organ pivot while facilitating its lubrication. Indeed, as visible in figs. 1, 3 and 4, the oiler 21 of substantially conical shape increases progressively section from that of the hole 17. It is therefore understood that the pivot of the member rotates against a smaller surface area which allows the reduction of friction. It is also understood that the oiler 21 allows easy lubrication of said pivot capable of further reducing said friction.

The manufacturing method 31 of an element such as a bridge 1 and / or platinum will now be explained in relation to FIG. 5. The method 31 mainly comprises a hole forming step 33, a step of forming the olives and / or oil and a forming step 37 of the coatings.

The first step 33 is intended to form the holes 11 of each fastener 2, 4, 6 and / or the holes 17 of each bearing 8, 10. In a first phase 32, it is equipped with a blank as explained above of the bridge 1. Then during the phase 34, the holes 11 and / or 17 are etched using a process comprising photolithography and anisotropic DRIE etching methods.

Preferably, in the case of the holes 11, a double mask protection process is used to form the shoulders 13. Thus, two masks are structured, one in recovery of the other, the unprotected section of the second mask being smaller than that of the first mask. This makes it possible to start phase 34 by engraving only according to the smallest section. From a predetermined depth of etching, phase 34 is interrupted to remove the second mask. The etching phase 34 is then resumed in order to continue etching the small section and to start the large one at the same time to the desired depth, that is to say to make the small section of the hole 11 open.

Step 35 is intended to form the olives and / or oilers 21 at at least one end of each bearing hole 17, 8, 10. As shown in FIG. 5, the invention comprises three embodiments represented respectively by double, single and triple lines.

In a first embodiment visible in double line in FIG. 5, step 35 comprises a phase 36 in which the oilers 21 are etched using a process comprising photolithography and isotropic DRIE etching methods. Indeed, an isotropic etching makes it possible to etch substantially in the form of a half-sphere, which allows the taper to be made of said oiler.

In a second embodiment visible in single line in FIG. 5, step 35 comprises a phase 38, in which the oilers 21 are etched using a process comprising photolithography and anisotropic DRIE attacking methods whose attacking section is successively reduced by modifying the sections unprotected protective masks. This embodiment forms a substantially stair-shaped oiler 21 and is, for this reason, preferably followed by oxidation in order to smooth said steps.

In a third embodiment visible in triple line in FIG. 5, step 35 comprises a phase 40 in which the oilers 21 are etched using an electroerosion process. Preferably, the electroerosion is carried out with a conical electrode to form said conical impression of the oiler 21. Preferably, in order to improve the quality of the phase 40, the element comprises a highly doped silicon-based material to increase its electrical conductivity.

Following step 35 or following step 33 as shown in broken lines in FIG. 5, the method 31 may further comprise the step 37 for forming the coatings with a low coefficient of friction on the wall 19 of the bearing holes 17, 10.

A first variant in single line of step 37 may include a phase 42 for producing a physical or chemical vapor or liquid deposition of a material of better tribological quality with respect to said micro-machinable material. This material may be, for example, an alloy based on nickel and phosphorus or a diamond-like carbon (DLC).

A second variant in double line of step 37 may include a phase 44 for oxidizing said silicon-based material to form a coating of silicon dioxide of better tribological quality.

In an alternative to step 37, following step 33 as shown in broken lines in FIG. 5, the method 31 may further comprise the step 37 for forming the ductile coatings 15 of the shoulders 13 of the fixing devices 2, 4, 6. The step 37 may then comprise a phase 42 intended to produce a physical deposit or chemical vapor or liquid phase of a ductile material. This material may be, for example, gold, copper, nickel or alloys NiP, TiW, AuCr.

Of course, the present invention is not limited to the example shown but is susceptible to various variations and modifications that will occur to those skilled in the art. In particular, a final oxidation step may be performed to form a silicon dioxide layer for mechanically reinforcing the bridge 1 and / or the platinum of silicon-based material. In addition, the attachment devices 2, 4, 6 presented use screwing means, however, they can not be limited thereto. They can be replaced by means of driving, gluing or clamping.

Claims (19)

1. Watch movement comprising at least one bridge (1) mounted on a plate by means of at least one fixing device (2, 4, 6), characterized in that said at least one bridge is made from a plate of a micro-machinable material and that said at least one bridge comprises at least one bearing (8, 10) formed in one piece with said at least one bridge to support at least one member of said movement. 2. Watch movement comprising at least one bridge (1) mounted on a plate with at least one fixing device (2, 4, 6), characterized in that the plate is made from a plate of a micro-machinable material and said platen comprises at least one bearing (8, 10) formed in one piece with the platen to support at least one member of said movement. 3. Movement according to claim 1 or 2, characterized in that said at least one bearing comprises a hole (17) forming a pad made by etching to dispense with a dedicated staking. 4. Movement according to claim 3, characterized in that the wall (19) of said bearing hole comprises a coating for improving the tribological qualities with respect to said micro-machinable material. 5. Movement according to claim 3 or 4, characterized in that said bearing hole comprises at least one olivage to reduce friction. 6. Movement according to one of claims 3 to 5, characterized in that said bearing hole comprises at least one oiler (21) to reduce friction while facilitating lubrication. 7. Movement according to one of the preceding claims, characterized in that the micro-machinable material is based on silicon. 8. Timepiece characterized in that it comprises a watch movement according to one of the preceding claims. 9. A method of manufacturing (31) a bearing (8, 10) in a micro-machinable element (1), characterized in that it comprises the following step: a) performing (33) etching to form the hole (17) of the pad of said bearing. 10. Process (31) according to claim 9, characterized in that the etching is performed by a deep reactive ion etching of the anisotropic type. 11. Method (31) according to claim 9 or 10, characterized in that it comprises, further after step a), the following step: b) performing (35) a second etching to form an olivage coaxially with said hole. 12. Method (31) according to one of claims 9 to 11, characterized in that it comprises, further after the step a), the next step: b) performing (35) a second etching to form an oiler (21) coaxially with said hole. 13. Method (31) according to claim 11 or 12, characterized in that the second etching is performed by deep-reactive ion etching of the isotropic type (36). 14. Method (31) according to claim 11 or 12, characterized in that the second etching is performed by a succession (38) of reactive ion etching of the anisotropic type whose driving section is successively decreased. 15. Method (31) according to claim 11 or 12, characterized in that the second etching is performed by electroerosion (40). 16. Method (31) according to one of claims 9 to 15, characterized in that it comprises, in addition, the final step: c) forming (37) a coating on the wall (19) of said bearing hole with a better coefficient of friction than said micro-machinable element. 17. Method (31) according to claim 16, characterized in that step c) comprises the following phase: d) performing (42) a physical vapor deposition of a material of better tribological quality with respect to said micro-machinable material. 18. Process (31) according to one of claims 9 to 17, characterized in that the micro-machinable material is silicon-based. 19. Method (31) according to claim 16, characterized in that the micro-machinable material is based on silicon and in that step c) comprises the following phase: e) oxidizing (44) said silicon-based material to form said coating of better tribological quality.