This application claims priority from European patent application No. 17200365.9 filed on Nov. 7, 2017, the entire disclosure of which is hereby incorporated herein by reference.
The invention relates to a method for assembling a stone on to a mounting, said stone being cut so that it has a table, a crown, a girdle and a pavilion. The invention also relates to a method for setting a stone and its mounting, produced by said assembly method, on an element of a timepiece or a of a piece of jewelry.
There are known methods of setting precious, semi-precious or synthetic stones using claws, beads or rails. Conventional setting by mounting a natural stone in a bezel using claws usually requires a dimensional accuracy of about 5/100 in the stone cutting. This type of setting is therefore incompatible with serially produced, low cost stone setting, where stones such as synthetic diamond, zircon and ruby, cut with a higher precision of about 1/100, are used.
The object of the present invention is to overcome this drawback by proposing a method of setting stones which makes it possible to disregard the inevitable dimensional variations found when natural stones such as diamonds are used.
For this purpose, the invention relates, in the first place, to a method for assembling a stone on to a mounting, said stone being cut so that it has a table, a crown, a girdle and a pavilion, said method comprising the following steps:
The positioning of the stones using the hot-melt adhesive layer according to the method of the invention makes it unnecessary to create housings of adequate size in advance to receive the stones. The method according to the invention therefore allows the dimensional variations of the stones to be disregarded.
The invention also relates to a method for setting a stone on an element of a timepiece or a of a piece of jewelry, comprising fitting the stone and its mounting, produced according to the method defined above, on to a bezel which is then affixed to the element of the timepiece or piece of jewelry, or directly on to the element of the timepiece or piece of jewelry.
The invention also relates to an element of a timepiece or a of a piece of jewelry, comprising at least one stone assembled on to its mounting, produced according to the assembly method as defined above.
Other characteristics and advantages will be clearly apparent from the description given below, for illustrative purposes and in an entirely non-limiting way, with reference to the attached drawings, of which:
With reference to
The first step a) of the method for assembling the stone 1 on to a mounting 2 according to the invention consists in providing a substrate 8 comprising a hot-melt adhesive layer 10.
Preferably, the substrate 8 takes the form of a plate, and is based on glass, ceramic, polymer, metal, silicon, quartz or any other appropriate support with a flat surface. Advantageously, the substrate 8 is a glass plate.
The hot-melt adhesive layer 10 is preferably a layer of adhesive soluble in hot water or a solvent, of the hot-melt type, such as Crystalbond™ or Wafer-Mount™ adhesive or any other similar appropriate mounting product.
The second step b) of the method for assembling the stone 1 on to a mounting 2 according to the invention consists in positioning the stone 1 on the hot-melt adhesive layer 10 of the substrate 8. In an advantageous and particularly preferable way, the stone 1 is positioned so that its table 3 is in contact with the adhesive layer 10, as shown in
The third step c) of the assembly method of the invention consists in heating the hot-melt adhesive layer 10 so that it is at least sufficiently softened to enable the stones 1 to be sunk into it.
The fourth step d) of the assembly method of the invention consists in exerting a pressure on the stone 1 so that, according to the variant shown here, only a part of the crown 4 of the stone 1 can be sunk into the sufficiently softened hot-melt adhesive layer 10, so that the rest of the crown 4, the girdle 5 and the pavilion 6 remain exposed, as shown in
Evidently, the order of steps b) and c) may be reversed. Step b) may advantageously be executed after step c), notably if the stone 1 is positioned so that it is its pavilion 6 that is partially sunk into the sufficiently softened hot-melt adhesive layer, leaving the rest of the stone exposed, so that the rest of the pavilion 6, the girdle 5 and the crown 4 remain exposed.
The depth of the hot-melt adhesive layer 10 is chosen so that the crown 4 (or the pavilion 6, depending on the variant used) is practically entirely sunk into the hot-melt adhesive layer 10, and comes into contact with the substrate 8, only a part of the crown 4 (or of the pavilion 6) having a small thickness e (see
The resulting assembly is left to cool so that the adhesive layer 10 solidifies and holds the stone 1 on the substrate 8 without the need to form suitable housings in said substrate.
The use of the method of the invention then continues according to step e), with the positioning of a setting sheet 12 above the adhesive layer 10 (which is cooled and solidified), the sheet being cut around the stone 1 so as to form a peripheral free space 16 between the portion 14 of the setting sheet 12 and said stone 1, at least at the level of the girdle 5 and of an area 4a of the crown 4 and an area 6b of the pavilion 6, said areas 4a and 6a being adjacent to the girdle 5.
The setting sheet 12 is made of a conductive material, for example a metallic material chosen from the group comprising nickel, gold, silver, platinum, palladium, copper, brass, and their alloys. Thus the peripheral free space 16 is delimited by the conductive surface of the portion 14 of the setting sheet 12.
Step e) also comprises the placing of a lower insulating layer 18 between the adhesive layer 10 and the setting sheet 12 and the placing of an upper insulating layer 20 on the free surface of the setting sheet 12, as shown in
Next, step f) of the method of the invention consists in depositing a metallic layer 22 by galvanic growth in said peripheral free space 16 from the portion 14 of the setting sheet 12, at least at the level of the girdle 5 and of the areas 4a and 6a of the crown 4 and the pavilion 6 respectively adjacent to the girdle 5, so as to trap said girdle 5 in said metallic layer 22, as shown in
Preferably, the area 6a of the pavilion 6 adjacent to the girdle 5 and the area 4a of the crown 4 adjacent to the girdle 5 extend immediately on either side of the girdle 5 only, over a thickness smaller than the thickness e of the part of the crown left exposed, so as to form said metallic layer 22 between the stone 1 and the setting sheet, substantially around the girdle only, that is to say at the level of the girdle 5 and immediately on either side of said girdle 5 only.
The metallic layer 22 is preferably made of a material chosen from the group comprising nickel, gold, silver, platinum, rhodium, palladium, copper, and their alloys.
The electroforming conditions, notably the bath composition, the geometry of the system, the voltages and current densities, are chosen for each metal or alloy to be electrodeposited according to techniques which are well-known in the art of electroforming (see, for example, Di Bari G. A., “Electroforming”, Electroplating Engineering Handbook 4th Edition, edited by L. J. Durney, published by Van Nostrand Reinhold Compagny Inc., N.Y. USA 1984).
The next step g) consists in releasing the stone 1, assembled on to its mounting 2, from the substrate 8. This step g) is carried out, for example, by dissolving the hot-melt adhesive layer 10 in an organic solvent. The insulating layers are removed by mechanical peeling, dissolving in organic solvents, or erosion (etching) by chemical agents.
The result is a stone 1, assembled on to its mounting 2, as shown in
When a plurality of stones 1 have been positioned on the hot-melt adhesive layer 10 in step b), the result is a mounting in the form of a plate comprising a plurality of stones 1 assembled on to said plate, the stones possibly forming a pattern.
Evidently, the dimensions of the mounting 2 are defined by the dimensions of the setting sheet 12. Notably, the thickness of the setting sheet 12 is preferably chosen so that the metallic layer 22 is deposited only substantially at the level of the girdle 5 and of the areas 4a, 6a respectively of the crown 4 and the pavilion 6 which extend only immediately on either side of the girdle 5 as described above, so that the mounting 2 is positioned substantially around the girdle 5 only, as shown in
The assembly method according to the invention allows adaptation to the dimensional variations of the stones 1 by allowing the stones to be assembled on to their mounting without the need to form different housings in advance with appropriate dimensions for receiving the stones.
When released in this way, the stone 1 assembled on its mounting 2 may be used in the setting method according to the invention.
Said method for setting said stone on an element of a timepiece or a of a piece of jewelry comprises fitting the stone 1 and its mounting 2, produced according to the assembly method defined above, on to a bezel. The bezel is then attached to the element of the timepiece or of the piece of jewelry.
In another variant, the stone 1 and its mounting 2, produced according to the assembly method as described above, are fitted directly on the element of a timepiece or of a piece of jewelry.
The mounting 2, bearing the stone 1 on the bezel 38 or directly on the element of a timepiece or of a piece of jewelry, may be fitted by clipping, pressing, setting, or other methods.
The element of a timepiece or of a piece of jewelry may be, for example, a dial, a bezel, a rotating bezel, a case middle, a horn of the case, a crown, a hand, a pointer, a link or other bracelet element, an element of a pendant, of a ring, of a necklace, or the like, any internal or external lining element, or any decorative element of a timepiece or of a piece of jewelry that can be set.
Number | Date | Country | Kind |
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17200365.9 | Nov 2017 | EP | regional |