This application claims priority from European Patent Application No. 17200360.0 filed on Nov. 7, 2017; the entire disclosure of which is incorporated herein by reference.
The invention relates to a method for assembling a stone on a setting support, said stone being cut to exhibit a table, a crown, a girdle and a pavilion. The invention also relates to a method for crimping, on an element of a timekeeping or jewellery part, a stone and its setting support obtained according to said assembly method.
It is known that precious, semi-precious or synthetic stones can be crimped using claws, grains or rails. Conventional crimping by assembling a natural stone, such as diamond or emerald, in a setting by means of claws generally requires dimensional control of close to 5/100 of the size of the stones. For this reason, this type of crimping is not compatible with that of mass produced, low-cost crimped stones, for their part using stones with greater precision, of close to 1/100, such as synthetic diamond, zircon and ruby.
The aim of the present invention is to overcome this disadvantage by proposing a method for crimping stones allowing the inevitable dimensional variations to be overcome that are encountered when natural stones, such as diamonds or emeralds, are used.
To this end, the invention first and foremost relates to a method for assembling a stone on a setting support, said stone being cut to exhibit a table, a crown, a girdle and a pavilion, said method comprising the following steps:
In a particularly advantageous manner, the substrate and its recess can be produced according to the following steps:
The method according to the invention allows the dimensions of the recess and, more specifically, the dimensions of the through-hole to be selected, so as to adapt to the dimensional variations of the stones.
The invention also relates to a method for crimping a stone on an element of a timekeeping or jewellery part comprising the assembly, on a setting subsequently added to the element of a timekeeping or jewellery part or directly on the element of a timekeeping or jewellery part, of the stone and of its setting support obtained according to the method as defined above.
The invention also relates to an element of a timekeeping or jewellery part comprising at least one stone assembled on its setting support obtained according to the assembly method as defined above.
Further features and advantages will become clearly apparent from the description, which is provided hereafter by way of a non-limiting example, with reference to the accompanying drawings, in which:
With reference to
The first step a) of the method for assembling the stone 1 on a setting support 2 according to the invention involves providing a substrate 8 comprising at least one recess 10, in which said stone 1 is positioned, said recess 10 being arranged to form, between the substrate 8 and said stone 1, a peripheral free space 12 at least around the girdle 5 of the stone 1, the bottom 14 of said peripheral free space 12 having a conductive surface 16. “Around the girdle” means that the peripheral free space 12 is positioned at least in the vicinity of the girdle 5 and of zones 4a and 6a of the crown 4 and of the pavilion 6 respectively contiguous to the girdle 5.
More specifically, the substrate 8 and its recess 10 advantageously can be produced according to the following steps, d) and e):
Step d) involves providing a substrate 8 having a conductive surface layer 16 and producing at least one through-hole 18 in said substrate 8. One through-hole 18 is formed per stone 1 to be assembled. Advantageously, the substrate 8 is, for example, based on silicon, glass, ceramic or quartz. Silicon wafers for microelectronics can be used, for example. The conductive layer 16 can be obtained by PVD (Physical Vapour Deposition) of chrome, titanium, gold and the combinations thereof, for example. Any other suitable conductive layer can be used. The through-holes 18 can be formed on the substrate 8 by laser ablation, for example. Advantageously, the distribution of the through-holes 18 on the surface of the substrate is particularly optimised as a function of the dimensions of the recesses, the shape of the setting supports, etc., so as to have a maximum number of through-holes on the surface of the substrate 8.
Step e) involves covering the substrate 8 with a photosensitive resin layer 20, as shown in
The dimensions of the through-hole 18, in the plane of the substrate 8, are less than the dimensions (generally called “diameter”) of the girdle 5 of the stone 1, and the dimensions of the cavity 22, in the plane of the substrate 8, are greater than the diameter of the girdle 5 of the stone 1. Consequently, the dimensions of the cavity 22, in the plane of the substrate 8, are greater than the dimensions of the through-hole 18, the cavity 22 then comprising a central opening 24 corresponding to the through-hole 18, and a peripheral zone comprising resin side walls 26 and a bottom, i.e. the bottom 14 occupied by the conductive layer 16 of the substrate 8 around the through-hole 18. The recess 10 therefore has a T-shaped section in the plane perpendicular to the substrate 8, as shown in
In a particularly advantageous manner, step e) comprises the use of a negative photosensitive resin 20, for example, an SU8 resin, with the UV irradiation of the photosensitive resin layer 20 through a mask corresponding to the profile of the desired setting support, and the removal of the non-irradiated part of the photosensitive resin layer 20, so as to obtain the cavity 22, the profile of which corresponds to the profile of said desired setting support. Such a photolithography method is per se known to a person skilled in the art and does not require a more detailed description.
Once the substrate 8 and its recesses 10 are produced, step a) of the assembly method according to the invention progresses to the installation of a stone 1 in each of the formed recesses 10.
The dimensions of the cavity 22 and of the through-hole 18 forming the recess 10 are selected so that the pavilion 6 of the stone 1 is partially housed in the through-hole 18, in order to rest on the periphery of the central opening 24 of the cavity 22, with the remainder of the pavilion 6 above the through-hole 18 defining the zone 6a of the pavilion 6 contiguous to the girdle 5, and so that the remainder of the stone 1 between said zone 6a of the pavilion 6 contiguous to the girdle 5 and at least up to the level of the zone 4a of the crown 4 contiguous to the girdle 5 is housed in the cavity 22, so as to form, between the stone 1 and the walls of the cavity 22, i.e. the side walls 26 and the bottom 14, said peripheral free space 12.
In a particularly preferred manner, the dimensions of the cavity 22 and of the through-hole 18 are selected so that the pavilion 6 of the stone 1 is practically fully housed in the through-hole 18, so that the zone 6a of the pavilion 6 contiguous to the girdle 5 only extends directly below the girdle 5, and the zone 4a of the crown 4 contiguous to the girdle 5 only extends directly above the girdle 5, so as to form, between the stone 1 and the walls of the cavity 22, i.e. the side walls 26 and the bottom 14, said peripheral free space 12 only substantially around the girdle 5, i.e. in the vicinity of the girdle 5 and only directly on either side of said girdle 5, as shown in
Since the only precise dimension of the stone that can be provided is the “diameter” of the girdle 5 and its height, it is possible that the stone 1 is not installed correctly and does not ensure that sufficient flatness is provided for the table 3 of the stone 1.
In this case, the assembly method according to the invention can comprise, between steps a) and b), a step f) of correcting the orientation of the stone. Advantageously, and with reference to
Before removing the repositioning device 28, it may be necessary to provide, between steps f) and b), a step g) of setting the pavilion 6 of the stone 1 in the through-hole 18. This step g) allows the correct positioning of the stones 1 to be maintained in their recesses 10, even after the repositioning device 28 has been removed.
Step g) involves, for example, introducing, through the open inlet of the through-hole 18, a retention adhesive 34 around the pavilion 6 of the stone 1, allowing the stone 1 to be set in the recess 10. In order to prevent the retention adhesive 34 from entering the cavity 22 if there is a clearance between the stone 1 and the central opening 24, a sufficiently viscous retention adhesive can be used that will not fill the narrowest gaps. It is also possible to plug, on the side of the cavity 22, any gaps existing between the stone 1 and the central opening 24, prior to depositing the retention adhesive 34. To this end, a resin can be sprayed into said gaps, on the side of the cavity 22, which resin can be easily removed (by dissolution, for example). Provision also can be made to deposit an indium layer of approximately 50 μm on the silicon substrate 8 before installing the stones 1. The indium layer has the advantage of deforming during the step f) of correcting the orientation of the stones by levelling the tables 3 and subsequently being able to provide the seal in the vicinity of the central opening 24 of the cavity 22.
Step g) is followed by a step h) of removing the repositioning device 28 in order to be able to continue the implementation of the assembly method of the invention.
Once the stone 1 is positioned in its recess 10 on the substrate 8 by forming, between said substrate 8 and said stone 1, a peripheral free space 12 at least in the vicinity of the girdle 5 and of the zones 4a and 6a, respectively of the crown 4 and of the pavilion 6 contiguous to the girdle 5 according to step a) described above, the assembly method according to the invention progresses with the implementation of step b). This step b) involves depositing, by electroplating in said peripheral free space 12, from the bottom 14 of said peripheral free space 12 occupied by the conductive layer 16, a metal layer 36 in the vicinity of the girdle 5 and of the zones 4a, 6a, respectively of the crown 4 and of the pavilion 6 contiguous to the girdle 5, so as to confine said girdle 5 in said metal layer 36 in order to form, at least substantially around the girdle 5 of the stone 1, said setting support 2, as shown in
The metal layer 36 deposited in step b) preferably is made of a material selected from the group comprising nickel, gold, silver, platinum, rhodium, palladium, copper and the alloys thereof.
The electroforming conditions, particularly the composition of the baths, the geometry of the system, the voltages and current densities, are selected for each metal or alloy to be electro-deposited according to the techniques that are well known in the art of electro-forming (cf., for example, Di Bari G. A., “Electroforming” Electroplating Engineering Handbook, 4th Edition, compiled by L. J. Durney, published by Van Nostrand Reinhold Company Inc., N.Y. USA 1984).
The sizes of the setting support 2 are defined by the dimensions, in the plane of the substrate 8, of the through-hole 18 and of the cavity 22, and by the height of the metal layer 36 deposited according to the electroplating parameters.
Preferably, these parameters are selected so that the metal layer 36 is deposited only substantially in the vicinity of the girdle 5 and of the zones 4a, 6a, respectively of the crown 4 and of the pavilion 6 that only extend directly on either side of the girdle 5, so that the setting support 2 is positioned substantially around the girdle 5 only, as shown in
The following step c) involves releasing the stone 1 assembled on its setting support 2 from the substrate 8. To this end, the silicon substrate 8 and the retention adhesive 34 are removed by dissolution. For example, 20% potassium hydroxide KOH can be used that is heated to 85° C. to dissolve the silicon and commercial solvents can be used to dissolve the adhesive.
The assembly method according to the invention enables adaptation to the dimensional variations of the stones 1 by providing, in the substrate 8, through-holes 18 with various diameters, adapted to the dimensions of said stones 1.
The stone 1, assembled on its setting support 2, that is thus released can be used in the crimping method according to the invention.
Said method for crimping said stone on an element of a timekeeping or jewellery part comprises assembling the stone 1 and its setting support 2, obtained according to the assembly method as described above, on a setting 38, as shown in
In another variation, the stone 1 and its setting support 2, obtained according to the assembly method as described above, are directly mounted on the element of a timekeeping or jewellery part.
The assembly of the setting support 2 bearing the stone 1 on the setting 38 or directly on the element of a timekeeping or jewellery part can be carried out by clipping, pressing, crimping, gluing, etc.
The element of a timekeeping or jewellery part can be, for example, a dial, a bevel, a rotary bevel, a middle, a horn of the case, a crown, a hand, an index, a link or other bracelet element, a pendant element, a ring, a collar, etc., or any timekeeping/jewellery decorative element that can be crimped.
Number | Date | Country | Kind |
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17200360.0 | Nov 2017 | EP | regional |