CH710544A2 - Process for producing a decorated element of a timepiece or jewelery, and element produced by the method. - Google Patents

Abstract

The method according to the invention makes it possible to produce a decorated element (1) of a timepiece or a jewelery piece. This decorated element may be for example a watch face. The method comprises the steps of providing a base substrate, and performing on said base substrate a micro-machining of a mold or decorative partitions (6) in a programmed pattern, and filling the mold or the decorative partitions of at least one filler material (7) to obtain the decorated element. The filler material may be an epoxy resin and the mold or partitions are obtained by melting and solidifying a paste or solder powder. The invention also relates to a decorated element.

Description

The invention relates to a method of producing at least one decorated element of a timepiece or jewelery.

The invention also relates to the decorated element obtained according to the production method.

To decorate an element or component of a timepiece or jewelery, it can be carried out enameling on a surface of the component after making in particular a set of partitions on the component. It can be a hot enameling. This traditional stovepipe technique is one of the many enamelling techniques, which include, among other things, grisaille, dry application, enamel painting, champlevé, low size, updated ply, embossed enamel, the strawberry to name the main ones.

The principle of this artisanal decoration technique is to manually create a pattern consisting of wire partitions, and then fill it with successive layers of enamels of different colors, transparent or opaque on a metal or ceramic support. The raw materials of the vitreous substance called enamel, are mainly silica in the form of very pure sand, feldspars, pegmatites, chalk, lime, and sometimes kaolins, associated with metallic components to give it its color . This substance deposited on a surface of the component is fired until it melts and adheres to the metal or ceramic component. The realization of the decor by various manual steps is long and can not be reproduced identically from one component to another, which is a drawback.

In the case of the cloisonné technique, there must be generally counted a large number of stages of realization of the decorated element. This involves making the design of the pattern directly on paper or computer before hand-making the decor patterns including a wire laid on the drawing as a base. A reproduction of the drawing on a metal or ceramic support or metal-ceramic is performed in particular by hand engraving, machine engraving or freehand. The support can then be enamelled with a layer of enamel transparent or not. The decor patterns are still placed and fixed on the support to form the partitions, which are leveled. A filling material, such as enamel, is subsequently inserted into the partitions and normally a firing of the enamelled support is still to be carried out. A polishing operation can still be provided when the enamelled component is out of the oven. As a very large number of steps is provided for this method of producing a decorated element, this constitutes a disadvantage of producing such a decorated element.

For example, patent EP 2 380 864 B1, which describes a method of manufacturing a ceramic element, which is encrusted with at least one metal decoration. First etching in the ceramic material by means of a laser beam to obtain one or more recesses. After that, a deposit is made in each recess, a metal layer by vapor deposition and chemical autocatalysis as a bonding layer. Subsequently, a decorative layer is deposited galvanically on the bonding layer to finalize the element decoration. It is complicated to fill each hollow made in the ceramic material with the metal layers to achieve the decorated element, which is a drawback. In addition, decoration only by deposition of a metal layer in the vapor phase does not allow to obtain decorative layers of sufficient thickness.

In the patent application CH 707 533 A2, there is described a method of manufacturing a watch dial decorated with an embroidery. It is first performed a decal engraving in a fabric scrim. Once the layer is pierced according to the desired pattern, a powder is spread on the layer. An impression of the pattern on the canvas is then performed to highlight the pattern for the embroidery operation, which follows this printing step. Once the embroidery is complete, the decorated canvas is glued to a support, such as a watch face. This method also comprises a very large number of steps to decorate the watch face, which is a disadvantage. In addition, a decoration of complex shape can not be realized with this method and the gluing of the decoration is generally not reliable in the long term.

The invention therefore aims to provide a method of producing a decorated element of a timepiece or jewelery by overcoming the disadvantages of the state of the art mentioned above to facilitate the manufacture of a such decorated element and its reproducible.

To this end, the invention relates to a method of producing a decorated element of a timepiece or jewelery, which includes the features mentioned in the independent claim 1.

Particular steps of the method of producing a decorated element are defined in the dependent claims 2 to 14.

An advantage of the method of producing a decorated element lies in the fact that it is possible to easily make two-dimensional or three-dimensional decorations with complex shapes with a small number of steps of implementation. The decorations can be made directly on a metal object, ceramic or metal-ceramic, such as cermet, and industrially. To improve adhesion with the decor, the base substrate can be treated with a metal or ceramic layer or cermet of the same family as the decor materials. Previously, the sets are drawn or programmed on a computer, which allows for very fine and reproducible decorations.

An advantage of the method of producing the decorated element lies in the fact that it can be obtained the partitions or mold on a base substrate by depositing a paste or powder solder in resin portions open on the substrate and according to the pattern of the drawn decoration. The paste or solder powder may be deposited either directly on the surface of the base substrate, which may be metallic or ceramic, or on a conductive layer made on the surface of the base substrate. The paste or solder powder, inserted into the open portions of the resin, is subsequently heated and melted before solidification of the solder. Any metal composition for brazing can be used taking into account the color of the metal components of the watch, on which the decorated element can be placed. Finally the resin can be easily removed by chemical etching, and the partitions, obtained by a low-melting point solder, are filled with a filler material for the decoration.

Advantageously, the filling material may be a cold enamel, defined as false enamel. For this cold enameling technique, an epoxy resin is used, which is a thermosetting polymer provided with color pigments. Once inserted into the partitions, the epoxy resin is dried. For the filling material, it may also be ceramic or metal-ceramic powders, whose melting point must be lower than that of the material used to make the partitions.

For this purpose, the invention also relates to a decorated element obtained according to the method of producing the decorated element, which comprises the characteristics mentioned in the independent claim 15.

Particular shapes of the decorated element are defined in the dependent claims 16 to 18.

The objects, advantages and characteristics of the method of producing a decorated element of a timepiece or jewelery, as well as the decorated element obtained will appear better in the following description with reference to the drawings in which: <tb> Figs. 1a to 1g <SEP> represent the different steps of producing a decorated element of a watch or jewelery piece according to the invention, <tb> fig. 2 <SEP> represents an element of a watch or jeweler's part with partitions or walls made according to the invention, and <tb> fig. 3 <SEP> represents a piece of a watch or jewelry piece after the steps of filling and solidification of the filling material according to the invention.

In the following description all the techniques for producing the decorative patterns of a watch element or jewelry, which are well known in the state of the art, will be reported in a simplified manner. The decorative motifs relate to partitions or molds deposited on a base substrate by techniques defined as micromachining techniques.

Preferably, the invention particularly relates to the industrialization of certain stages of cloisonné techniques and plique up to date in volume. With these two techniques, it is possible for example to enamel a volume pattern by previously creating partitions son or metal strips. These partitions are preferably placed on a base substrate, which may be metallic or ceramic or metal-ceramic, such as cermet, or another material indicated below.

The method of producing a decorated element for a watch or a jewel comprises an essential first step of making partitions or walls or molds on the base substrate by a micro-machining technique. The base substrate may be a crystalline or amorphous metallic material, a ceramic, a semiconductor, a cermet, or any other material. Regarding ceramics, this concerns alumina, zirconia, magnesia, boron nitride, silicon nitride, silicon carbide, aluminum titanate and aluminum nitride, or other types of ceramics . It can even be expected to have a base substrate of quartz, glass, sapphire, corundum or other type of gemstone. The mold or partition material may be the same as that of the base substrate.

The decoration patterns defined by the partitions are drawn or previously programmed on computer, and the stored data of the drawing or pattern are transmitted to the micro-machining machine for the realization of said partitions. Subsequently, an operation is further carried out to fill the partitions with a filling material, which may preferably be a cold enamel, which is a thermosetting polymer provided with color pigments, a metal alloy, or even a ceramic or a cermet. The enamel can be deposited or cold fixed in the partitions and is defined as a false enamel.

In figs. 1a to 1g, it is schematically described all the steps necessary for the realization of the decoration on a base substrate 2 to obtain a decorated element for a timepiece or jewelery. To do this, it is first provided with a base substrate 2, which may be metallic, ceramic or metal-ceramic. It may also be envisaged to have a semiconductor base substrate, such as silicon or even gallium arsenide.

In the first step shown in FIG. 1a, at least one conductive layer 3 is deposited on the surface of the base substrate 2. This conductive layer 3 may be a thin metal layer deposited by a PVD or CVD technique or by sputtering. It may even be expected to deposit several successive conductive layers 3 of the same material or a different material from one layer to another. However, this first step can be avoided, if the base substrate 2 is metal, typically copper, or if used as explained below an active solder.

In the second step shown in FIG. 1b, a photosensitive resin 4 is deposited on the surface of the base substrate 2 or on the conductive layer 3. This photosensitive resin 4 may be a polyimide-based resin PMMA (poly-methyl methacrylate) or a resin based on octofunctional epoxy available from Shell Chemical under the reference SU-8 and a photoinitiator selected from triarylsulfonium salts. This photosensitive resin 4 can be photopolymerized by means of ultraviolet (UV) radiation.

In the third step shown in FIG. 1c, a mask 5 at the contour of the pattern to be made on the base substrate 2 of the element is placed on the resin 4. The mask 5 may be a glass plate on which is made a masking layer with opaque portions and transparent according to the pattern to be made. A light radiation, for example of the ultraviolet UV type, is directed onto the mask 5 to irradiate unmasked portions of the resin 4. With this type of resin 4 used, which is a negative photosensitive resin, the non-irradiated portions can be removed at the fourth step shown in FIG. 1d, by physical or chemical means. This makes it possible to define the shapes of the partitions or mold in the removed parts 4a of the resin 4.

It should be noted that a positive photoresist 4 can also be used with a masking mask 5 having opaque and transparent portions according to the pattern to be produced. This mask 5 is the inverse of the mask used with the negative resin 4. In this case, it is the irradiated parts of the resin, which are removed in the fourth step.

In the fifth step shown in FIG. 1e, the open portions 4a of the resin 4 on the base substrate 2 or on the conductive layer 3, are filled with a paste or powder solder 6. The paste or solder powder 6 is generally composed of a metal or a metal alloy, which preferably has a lower melting point than that of the photoresist, ie below 380 ° C. The solder paste 6 is generally composed of a powder with an additive or organic binder. The metal powder used may be for example a mixture of gold and tin (Au-Sn) or there may be a mixture of two powders, which are gold and tin of the first powder and gold for the second powder. The low melting point paste or solder powder may also consist of Au-Si eutectic compositions with melting point at about 363 ° C., Au-Ge at melting point at about 361 ° C., Au-Sb having a melting point to about 360 ° C or Au-Ga alloys melting at about 340 ° C and Au-Ga-ln melting at about 325 ° C. In addition, other types of soft solder compositions without precious elements may be used which are based on Sn, Sn-Pb or In with a melting point below 380 ° C.

It can also be envisaged to have a paste or powder solder 6, which is composed of a mixture of metal powder and ceramic particles. The metal powder is the part of the mixture, which can easily melt and bind the ceramic particles as well. This type of mixture has the advantage of increasing the hardness of the partitions made while giving a composite appearance.

In the sixth step also shown in FIG. 1e, the assembly, which is composed in particular of the base substrate 2, the resin 4 and the paste or powder solder 6 inserted into the open portions 4a of the resin 4, is heated so as to melt the dough or solder powder 6 in the partitions. After that, a solidification of the paste or powder solder occurs. Due to the capillary action of the liquid solder in the partitions, there is a good grip of said low temperature solder to completely complete all the spaces in the partitions. In the case of metal solder paste, the organic additive (s) are burnt or evaporated.

In the seventh step shown in FIG. 1f, all the photoresist 4 is removed. After this step of removing the resin, an element is obtained with the metal partitions 6 made. This element is represented for example in the form of a watch face in three-dimensional view with its pattern in FIG. 2.

In the eighth step shown in FIG. 1g, the spaces between the partitions 6 are filled by a filling material 7, which may preferably be a cold enamel or false enamel, such as an epoxy resin with color pigments. Different colors of the filling material 7 may be chosen for filling the partitions 6, in order to produce a decorated element. This false enamel is dried to be solidified and thus form a decorated element 1 at the end of the production process.

Another type of filling material 7, such as a metal or metal alloy, can be inserted in pasty or liquid form in the spaces between the partitions before being solidified. It may be envisaged to use ceramic or cermet filling material which is disposed between the bulkheads in the form of powder or liquid before a solidification operation. Once finished, the decorated element 1 can be in the form of a watch face as shown from above in FIG. 3.

Of course, it is still possible after the eighth step to eliminate the base substrate 2, for example metal or ceramic or metal-ceramic, or even semiconductor material by a machining operation or selective dissolution. In this case, the decorated element 1 obtained therefore comprises epoxy resin enamel portions 7 surrounded by the pattern structure 6.

It should also be noted that the base substrate 2 can still be hollowed in particular by laser beam to improve the mechanical grip of the filling material 7 between the partitions. It can also be provided to perform micro-drilling or recesses in the partitions made to ensure proper maintenance of the filling material 7. These operations are performed before inserting the paste or solder powder in the open portions of the resin. Different thicknesses of the filling material 7 can be envisaged to obtain a two-dimensional or three-dimensional decor pattern.

In an alternative embodiment, it can be envisaged in the fifth step of the method of depositing one or more PVD or galvanic metal layers in the open portions 4a of the resin 4. This resin can subsequently be removed and a paste or solder powder 6 is deposited on the conductive or PVD or galvanic layers deposited on the base substrate 2. A melting of the paste or powder solder 6 is performed above the conductive layers made according to the pattern of decor. As the liquid solder wets only the metallized areas and not the base substrate 2, which is in this case ceramic, the partitions are made after solidification of the paste or powder solder in the desired pattern and with a suitable thickness. Subsequently, the filling material 7 is inserted into the partitions and the same operations are performed as mentioned above to produce the decorated element 1.

It should be noted that in the aforementioned embodiment, the paste or powder solder no longer needs to be low melting point since the resin has been removed. On the other hand, the melting point of the dough or solder powder must be lower than the melting point of the base substrate on which it is placed before heating.

Of course for this embodiment, it may also be envisaged to have a metal base substrate, but in this case, it is necessary to deposit at least one non-metallic layer by PVD or CVD, such as an oxide or nitride around the decoration pattern, where the paste or metal powder to be soldered must be deposited. It is also not deposited other conductive layers by PVD or CVD, as the base substrate is metallic. To do this following the deposition of the photosensitive resin on the base substrate, this resin is irradiated with a UV beam through a mask of the pattern to be produced. The non-irradiated parts of the resin for example are removed in order to deposit the non-metallic layer or layers to define a complementary pattern for producing the partitions or mold. Once the non-metallic layer (s) are deposited, all the resin can be removed. From this moment the paste or solder powder is deposited in portions removed from the non-conductive layer or layers. The solder is melted and solidified to make the partitions or the mold. Finally, the filling material can fill the spaces between the partitions to obtain the decorated element.

From the description that has just been given, several variants of the method of producing a decorated element of a timepiece or jewelery can be designed by those skilled in the art without departing from the scope of the present invention. the invention defined by the claims. The decorated element may also be a watch hand, or a date disc, another component of the watch, such as a seconds wheel, an oscillating weight, a watch case back.

Claims (18)

A method of producing a decorated element (1) of a timepiece or jewelery, characterized in that the method comprises the steps of: - providing a base substrate (2), and performing on said base substrate a micro-machining of a mold or decorative partitions (6) in a programmed pattern, and - filling the mold or the decorative partitions (6) with at least one filling material (7) to obtain the decorated element (1). 2. A method of producing a decorated element (1) according to claim 1, characterized in that it comprises the steps after having provided the base substrate (2) of: Depositing on the base substrate (2) a layer of photoresist (4) of the positive or negative type, Placing on the photosensitive resin (4) a mask (5) at the contour of the pattern to be produced, Illuminate the resin (4) through the mask (5), - remove the illuminated parts of the resin (4), if the photoresist is of the positive type, or remove the non-illuminated parts of the resin (4), if the photoresist is of the negative type, - filling the removed portions (4a) of the resin (4) with at least one paste or solder powder (6) to make the partitions or the mold, - heating the assembly composed of the base substrate (2), the resin (4) and the paste or powder solder (6) to melt the paste or solder powder (6) before solidification of the solder, - remove all the resin (4), and - filling the mold or the decorative partitions (6) with at least one filling material (7) to obtain the decorated element (1). 3. A method of producing a decorated element (1) according to claim 2, characterized in that at least one conductive layer, such as a metal layer is deposited by a physical or chemical vapor deposition or sputtering at the surface of the base substrate (2) before depositing the resin layer (4). 4. A method of producing a decorated element (1) according to claim 2, characterized in that the pulp or powder solder (6) used is metal paste or powder solder. 5. A method of producing a decorated element (1) according to claim 4, characterized in that the pulp or powder solder (6) used is low melting point below 380 ° C. 6. A method of producing a decorated element (1) according to claim 5, characterized in that the metal powder or powders (6) are composed of a mixture of gold and tin, or a mixture of gold and tin for a first powder and gold for a second powder. 7. A method of producing a decorated element (1) according to claim 2, characterized in that the paste or solder powder (6) consists of Au-Si or Au-Ge or Au-Sb eutectic compositions or Au-Ga or Au-Ga-ln alloys. 8. A method of producing a decorated element (1) according to claim 2, characterized in that the paste or solder powder (6) used comprises a mixture of metal powder and ceramic particles. 9. A method of producing a decorated element (1) according to claim 2, characterized in that the solder paste (6) is composed of at least one metal powder with at least one additive or organic binder. 10. A method of producing a decorated element (1) according to claim 1, characterized in that it comprises the steps after having provided the base substrate (2) of: Depositing on the base substrate (2) a layer of photoresist (4) of the positive or negative type, Placing on the photosensitive resin (4) a mask (5) at the contour of the pattern to be produced, Illuminate the resin (4) through the mask (5), - remove the illuminated parts of the resin (4), if the photoresist is of the positive type, or remove the non-illuminated parts of the resin (4), if the photoresist is of the negative type, depositing in the withdrawn portions (4a) of the resin (4) one or more metal layers by physical or chemical vapor deposition, - remove all the resin (4), Depositing at least one paste or solder powder (6) on the metal layer or layers, Melting and solidifying the paste or solder powder (6) to make the partitions or the mold, and - filling the mold or the decorative partitions (6) with at least one filling material (7) to obtain the decorated element (1). 11. A method of producing a decorated element (1) according to claim 1, characterized in that it comprises the steps after having provided the metal base substrate (2) of: Depositing on the base substrate (2) a layer of photoresist (4) of the positive or negative type, Placing on the photosensitive resin (4) a mask (5) at the contour of the pattern to be produced, Illuminate the resin (4) through the mask (5), - remove the illuminated parts of the resin (4), if the photoresist is of the positive type, or remove the non-illuminated parts of the resin (4), if the photoresist is of the negative type, Depositing in the removed portions (4a) of the resin (4), one or more non-conductive layers by physical or chemical vapor deposition to define a complementary pattern for producing the partitions or mold, - remove all the resin (4), Depositing at least one paste or solder powder (6) on the base substrate in portions removed from the non-conductive layer or layers, Melting and solidifying the paste or solder powder (6) to make the partitions or the mold, and - filling the mold or the decorative partitions (6) with at least one filling material (7) to obtain the decorated element (1). 12. A method of producing a decorated element (1) according to claim 1, characterized in that once the mold or the decorative partitions (6) are filled by the filling material (7) solidified and maintained at walls of said mold or said partitions, a selective machining or dissolution operation is performed to remove the base substrate (2), which is made of metal or ceramic or metal-ceramic or semiconductor material. 13. A method of producing a decorated element (1) according to claim 1, characterized in that the base substrate (2) is hollowed on the surface to improve the mechanical grip of the filling material (7) between the partitions ( 6). 14. A method of producing a decorated element (1) according to claim 1, characterized in that micro-bores or recesses are made in the partitions or the mold (6) to improve the mechanical maintenance of the filling material (7). ). Decorated element (1) obtained according to the production method according to one of the preceding claims, characterized in that the element comprises a filling material (7) held on the walls of a mold or decorative partitions (6). ) micro-machined according to a programmed pattern. Decorated element (1) according to claim 15, characterized in that the mold or the decorative partitions (7) are made of a metal or metal and ceramic braze, and that the filling material (7) is cold enamel, such as epoxy resin. 17. decorated element (1) according to claim 16, characterized in that the filler material (7) is a thermosetting polymer provided with color pigments, and of different color from a partition to another partition. 18. Decorated element (1) according to claim 15, characterized in that the element is a watch face.