Classifications

• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/06—Dials
  • G04B19/12—Selection of materials for dials or graduations markings
• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/06—Dials
  • G04B19/14—Fastening the dials to the clock or watch plates

Definitions

• the present invention relates to a timepiece dial foot, said one foot being fixed on said dial and used to fix said dial to the timepiece.
• the technical field of the invention is the technical field of fine mechanics.
• timepieces comprise a movement on which is fixed a dial.
• This dial includes feet which are used, on the one hand, as a geometrical reference in the cycle of manufacture of the dial and, on the other hand, to fix said dial to the movement.
• feet are made of crystalline metal such as steel, brass or gold. These feet are assembled by spot welding. They very often have a smaller diameter in the area in contact with the base of the dial, this for three main reasons. First, it prevents a weld overflow from properly squeezing the dial against movement. Second, it ensures, in case of impact on the foot, the plastic deformation is located in this narrowed area. The foot can then be straightened while maintaining good accuracy on the large diameter area that will adjust to the movement. Finally, this diameter of the smaller foot in the area in contact with the base of the dial serves to prevent deformation of the base of the dial in case of impact on a foot by a deliberate and controlled weakening of said foot.
• each material is characterized by its Young's modulus E also called modulus of elasticity (generally expressed in GPa), characterizing its resistance to deformation.
• Each material is also characterized by its elastic limit ⁇ ⁇ (generally expressed in GPa) which represents the stress beyond which the material deforms plastically. It is then possible, for given dimensions, to compare the materials by establishing for each the ratio of their elastic limit on their Young's modulus a JE, said ratio being representative of the elastic deformation of each material. Thus, the higher the ratio, the greater the elastic deformation of the material.
• the Young's modulus E is equal to 130 GPa and the elasticity limit ⁇ ⁇ is equal to 1 GPa, which gives an oJE ratio of the order of 0.007 cm. that is to say, weak.
• the object of the invention is to overcome the drawbacks of the prior art by proposing to provide a metal dial foot which is more resistant to shocks.
• the invention relates to a timepiece dial comprising at least one foot. Said at least one foot is attached to said dial and is used to fix said dial to said timepiece, said at least one foot and the dial are made of an at least partially amorphous metal alloy.
• a first advantage of the present invention is to allow the dial feet to better withstand shocks. Indeed, amorphous metals have more interesting elastic characteristics.
• the elastic limit ⁇ ⁇ is increased, which makes it possible to increase the ratio ⁇ ⁇ / ⁇ so that the material sees the stress beyond which it does not return to its initial shape to increase. If the foot deforms plastically more difficult, it is no longer necessary to unfold the foot to return it to its original position. If the foot is more resistant, it is also less weakened by successive folds and unfoldings and thus the foot has a longer life.
• Another advantage of the present invention is to make it possible to produce feet of smaller dimensions. Indeed, as the amorphous metal is able to withstand higher stresses before deforming plastically, it is possible to make dial feet of smaller dimensions without losing resistance.
• the present invention also relates to a timepiece dial comprising at least one foot, said dial is fixed on a support on which said at least one foot is fixed to fix said dial to said timepiece.
• Said at least one foot and the support are made of an at least partially amorphous metal alloy.
• said at least one foot and the dial are one and the same piece.
• said at least one foot and the support are one and the same piece.
• said at least one foot is attached to the dial.
• said at least one foot is attached to the support.
• said material is totally amorphous
• the dial comprises at least one recess in which said at least one foot is fixed.
• the support, on which the dial is fixed comprises at least one recess in which said at least one foot is fixed.
• flanks of said at least one recess comprise reliefs in order to improve the fixing of said at least one foot in said at least one recess.
• the reliefs arranged on the sides of said at least one recess form a tapping.
• said at least one recess has a constant section.
• the bottom of said at least one recess has the largest section.
• the section increases linearly approaching the bottom of said at least one recess.
• said foot comprises, in its area of contact with the dial or the support, a smaller diameter.
• said foot comprises, in its zone of contact with the dial or the support, a larger diameter low and in the area contiguous to this contact area, an even smaller diameter.
• said at least one metallic element is a precious material or an alloy based on such a precious material, said precious material being chosen from the group formed by gold, platinum, palladium, rhenium, ruthenium, rhodium, silver, iridium or osmium.
• the amorphous metal is very easy to shape and allows the manufacture of complicated shapes with greater precision. This is due to the particular characteristics of the amorphous metal which can soften while remaining amorphous for a certain time in a given temperature range [T g - T x ] specific to each alloy. It is thus possible to shape it under a relatively low stress and at a low temperature then allowing the use of a simplified process such as hot forming, while reproducing very precisely fine geometries because the viscosity of the alloy decreases significantly as a function of temperature in said temperature range [T g - T x ]. Therefore, it becomes possible to realize the dial and feet in one piece and accurately.
• FIGS. 5 to 7 schematically represent alternatives to the second embodiment of the invention.
• FIG. 8 schematically shows a third embodiment of the invention.
• FIG. 9 schematically shows a particular variant of the first embodiment of the invention.
• FIG. 1 shows a timepiece 1 comprising a housing 2.
• This dial 7 is fixed to movement 5 by means of feet 9 fixed to said dial 7 and engaged in orifices 1 1 of the movement 5.
• the fixing of the dial 7 to the movement 5 is ensured by fastening means 13.
• These fastening means 13 consist, for example, of a screw 15 engaged in a threaded hole transverse to the orifice 1 1 and opening therein. This screw then clamps said foot 9 so as to hold it fixed in the orifice 1 January.
• the dial 7 is attached to a support 17 on which the feet 9 are fixed as is the case for a dial 7 enamel glued to a support 17 Brass.
• the feet 9 are made of an amorphous material or at least partially amorphous.
• a material comprising at least one metal element is used.
• the material will be an amorphous metal alloy. It will be understood by at least partially amorphous material that the material is capable of solidifying at least partially in the amorphous phase, that is to say that it is capable of losing at least locally all of its crystalline structure.
• the advantage of these amorphous metal alloys comes from the fact that, during their manufacture, the atoms of these amorphous materials do not arrange according to a particular structure as is the case for crystalline materials.
• the elastic limit ⁇ ⁇ is different.
• An amorphous metal is thus distinguished by an elastic limit ⁇ ⁇ higher than that of the crystalline metal by a factor of approximately two to three. This allows the amorphous metals to be able to undergo a greater stress before reaching the elastic limit ⁇ ⁇ .
• Amorphous metals plastically deform more difficultly and break brittle when the applied stress exceeds the elastic limit.
• the metal element of said material may then comprise gold, platinum, palladium, rhenium, ruthenium, rhodium, silver, iridium or osmium.
• Such feet 9 have the advantage of having higher strength and longevity compared to their crystalline metal counterparts.
• a foot 9 made of amorphous metal has a better resistance to the stresses applied to it during an impact because it will deform elastically over a wider stress interval and return to its initial position once the shock is complete.
• this interval of constraints in which the foot 9 is elastically deformed, is wider for a foot 9 of amorphous metal than for its crystalline metal equivalent, it allows said foot 9 amorphous metal to withstand stresses that plastically deform said foot 9 crystalline metal .
• these feet 9 are no longer unfolded to return them to their original position and therefore they become weaker, which improves their longevity.
• the elastic limit of an amorphous metal is greater than that of a crystalline metal by a factor of approximately two to three, making it possible to withstand higher stresses, it is conceivable to reduce the dimensions of said foot. 9. Indeed, as a foot 9 of dial 7 of amorphous metal can withstand a higher stress without deforming plastically, it is then possible, at equivalent stress, to reduce the dimensions of the foot 9 relative to a crystalline metal. As the feet 9 are inserted into the openings 1 1 of the movement 5, the fact of decreasing the dimensions of the feet 9 makes it possible to reduce the dimensions of the orifices 1 1.
• the fact of decreasing the size of the feet 9 increases the risk of deformation of the dial 7, especially if the foot 9 has a smaller diameter in the area in contact 10, 12 with the base of the dial 7 or the support 17.
• the foot 9 has an even smaller diameter in the contiguous zone 14 to the contact zone 10, 12 as visible in Figure 9. This allows to separate the functions.
• the contact zone 10, 12 is used to prevent the overflow of the weld prevents the dial 7 from being correctly pressed onto the movement 5.
• the zone 14 is used to weaken the foot 9 so that it deforms, elastically or plastically, at this zone 14.
• the feet 9 may be made by machining, but it is possible to achieve them using the properties of amorphous metals. Indeed, the amorphous metal has a great ease in shaping allowing the manufacture of parts with complicated shapes with greater precision. This is due to the particular characteristics of the amorphous metal which can soften while remaining amorphous for a certain time in a given temperature range [T g - T x ] specific to each alloy (for example for a Zr 41 .2 _4 alloy. Ti 13.77 Cu 12.
• the shaping is done around 300 ° C for a viscosity up to 10 3 Pa.s for a stress of 1 MPa, instead of a viscosity of 10 12 Pa. s at the temperature Tg.
• One method used is the hot forming of an amorphous preform.
• This preform is obtained by melting in a furnace the metallic elements constituting the amorphous alloy. This fusion is made under a controlled atmosphere with the aim of obtaining as low a contamination of the oxygen alloy as possible. Once these elements are melted, they are cast as a semi-finished product, such as for example a cylinder of dimensions close to those of the dial feet 9, and then rapidly cooled in order to maintain the at least partially amorphous state or phase. .
• the hot forming is performed in order to obtain a final piece.
• This hot forming is carried out by pressing in a range of temperatures between glass transition temperature T g of the amorphous material and the crystallization temperature T x of said amorphous material for a predetermined time to maintain a totally or partially amorphous structure.
• the goal is then to retain the characteristic elastic properties of amorphous metals.
• the different stages of final shaping of the foot 9 of dial 7 are then:
• a casting process is used. This process involves casting the alloy obtained by melting the metal elements in a mold having the shape of the final piece. Once the mold filled, it is cooled rapidly to a temperature below T g to prevent crystallization of the alloy and thus obtain a foot 9 of amorphous or partially amorphous metal.
• T g temperature below T g
• the advantage of casting an amorphous metal with respect to the casting of a crystalline metal is to be more precise.
• the solidification shrinkage is very low for an amorphous metal, less than 1% relative to that of the crystalline metals which is 5 to 7%. After completion of said feet 9, they are fixed to said dial 7 by welding.
• said feet 9 are arranged as the feet 9 according to the prior art, that is to say having a smaller diameter in the area in contact 12 with the base of the dial 7 to prevent the Overflow of the weld prevents the dial 7 from being pressed correctly on the movement 5.
• the plastic deformation is localized in this narrowed zone in order to preserve the dial 7.
• the feet 9 will be welded to the support or chased in recesses 19 made on the support 17.
• holding means 23 are arranged. These holding means 23 can take various forms. In a first alternative visible in Figure 5, these holding means 23 may be the flanks 25 of the recesses 19 which are arranged to have a non-constant section. Preferably, the bottom section 21 of the recess 19 is larger than that at the surface of the dial 7. It can also be expected that the section expands steadily when approaching the bottom 21 of the 19. This arrangement of the section of the recesses 19 in which are fixed the feet 9 allows a natural retention of said feet 9 in said recesses 19 without requiring welding or gluing.
• the flanks 25 of the recesses 19 comprise reliefs 27.
• These reliefs 27 may be in the form of recesses and / or projections arranged on the flanks 25 of each recess 19.
• These recesses and / or protrusions can be arranged to form a tapping allowing the screwing and unscrewing of the feet 9.
• These reliefs 27 exploit the characteristics of the amorphous metal to be able to soften while remaining amorphous in a temperature range [T g - T x ] given specific to each alloy thus marrying all the details of the negative.
• the amorphous metal then inserts into the recesses of the flanks 25 thus ensuring a better hold of the foot 9 in the recess 19. It will be understood that, in the case where the dial 7 is attached to a support 17, the recesses 19, in which are made the feet 9 and whose flanks 25 comprise reliefs 27, are formed on the support 17 as shown in Figure 7.
• a third embodiment, visible in FIG. 8, consists in producing the dial 7 and the feet 9 in one and the same piece, that is to say that the dial 7 and the feet 9 are made of amorphous metal simultaneously.
• the dies constituting the mold form the complementary impression of the part composed of the dial 7 and the feet 9. It will be understood that, in the case of a dial 7 attached to a support 17, the support 17 and the feet 9 are one and the same room. This part is then cast or hot-formed amorphous metal.
• the advantage is to have in the first place a perfect reproducibility of the process since the dials 7 associated with their feet 9 are all made in the same mold.
• this method has the advantage of being simple and not having a step of fixing the feet 9 with the risk of bending the feet 9 or deforming the dial 7.
• the dial 7 and the feet 9 are made of amorphous metal or metal alloy at least partially amorphous but separately. It is understood that the feet 9 and the dial 7 are separate pieces and that the feet 9 are then reported on the dial 7. This is also valid in the case where the dial 7 is fixed on a support 17 and that the support 17 is amorphous metal. The feet 9 and the support 17 are different pieces of amorphous metal. The feet 9 are attached to said support 17.
• the feet 9 are, in the case where they are reported to the dial 7 or the support 17, glued or welded or fixed with any possible method.

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• 2010
  • 2010-06-22 EP EP10166916A patent/EP2400354A1/de not_active Withdrawn
• 2011
  • 2011-06-21 EP EP11726429.1A patent/EP2585880A1/de not_active Ceased
  • 2011-06-21 JP JP2013515849A patent/JP5457608B2/ja not_active Expired - Fee Related
  • 2011-06-21 CN CN2011800310394A patent/CN103038713A/zh active Pending
  • 2011-06-21 WO PCT/EP2011/060285 patent/WO2011161080A1/fr active Application Filing
  • 2011-06-21 US US13/704,075 patent/US20130148484A1/en not_active Abandoned

Non-Patent Citations (2)

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