This application claims priority from EP No. 16170379.8 filed on May 19, 2016, the entire disclosure of which is hereby incorporated herein by reference.
The invention relates to a process for the production of a part such as a timepiece or item of jewellery, e.g. a watch dial, bezel, band or bracelet etc. More specifically, the process enables an external element such as an hour indicator, a decorative element etc. to be made on said part.
In the field of clock-making or jewellery making it is classic practice to make raised external elements that are held non-detachably on their support. In particular, patent application EP 2192454A1 is known from the prior art, which describes a process for the production of an external element forming a relief on a dial. According to the third embodiment described in this application a watch dial having T-shaped through openings is made. A mask is then attached to the dial. The mask has openings arranged so as to connect with the openings of the dial. The openings are then filled by means of electroplating, by pressing an amorphous material or by metal injection in order to form external elements. Finally, the excess thickness of filling material of the mask is removed and the mask is taken off.
A disadvantage of this process is the restriction in the shape and depth of the openings causing a restriction in the shape and length of the external elements. For example, the process does not allow the formation of external elements that extend over only a portion of the dial. The external elements are possibly made from precious materials, e.g. gold, and it is therefore advantageous to restrict their depth in the dial that is not noticeable from the outside. Another disadvantage is that the process does not allow the production of external elements with heads that are textured, e.g. engraving. Another disadvantage is that the process does not allow the production of external elements that are formed from a non-metallic material. Another disadvantage is that the process does not allow the production of external elements that are not raised but are hollow, forming recesses of a desired shape, and in particular recesses with a coloured base.
The aim of the present invention is to fully or partly overcome the disadvantages discussed above.
For this purpose, according to a first embodiment the invention relates to a process for the production of a part provided with an external element, wherein the process comprises the following steps:
The process according to the first embodiment enables the production of a part provided with an external element forming a recess in the part. The geometry of the recess is determined by the geometry of the raised pattern present on the substrate: it is thus understood that the recess can have any desired shape. Moreover, the recess has a base with the colour of the metal layer, e.g. a golden base if the metal layer is made from gold. This metal layer forms an insert, from which the mass of base material cannot be separated without destroying the part. In fact, the invention benefits from a characteristic of the galvanic growth of a metal often considered as a fault, whereby the metal grows not only vertically from a surface arranged horizontally in a land reference point, but also laterally. This feature enables the metal layer to partially rest on the insulating layer at the end of the step of deposition by galvanic growth. The parts of the metal layer resting on the insulating layer, referred to as lateral ends in the following text, thus form hooks that are left sealed in the mass of base material of the part at the end of the covering step.
According to a second embodiment the invention relates to a process for the production of a part provided with an external element comprising the following steps:
The process according to the second embodiment allows a part provided with an external element forming an outgrowth to be produced. The outgrowth is formed by the part of the metal layer that projects from the mass of base material, the outgrowth thus being the colour of the metal layer. The geometry of the outgrowth is determined by the geometry of the hollow pattern machined onto the substrate. It is thus understood that the outgrowth can have any desired shape within the limit of machining possibilities of the substrate. Moreover, the metal layer forms an insert, which is impossible to separate from the mass of base material for the same reasons as those explained in relation to the first embodiment.
In addition, the production process according to the first or the second embodiment can comprise one or more of the following features in all technically possible combinations.
In a non-restrictive embodiment the process according to the first embodiment includes the following step:
In a non-restrictive embodiment the process according to the first or second embodiment includes the following step:
In a non-restrictive embodiment the process according to the first or second embodiment includes the following step following the step of dissolving the metal layer:
In a non-restrictive embodiment the process according to the first or second embodiment the base material of the mass is not metallic, wherein the compound is metallic, and the process includes the following step between the step of dissolving the metal layer and the step of filling the cavity with the compound:
In a non-restrictive embodiment the process according to the first or second embodiment includes the following step:
In a non-restrictive embodiment the process according to the first or second embodiment includes the following step performed before the step of depositing the insulating layer:
In a non-restrictive embodiment the process according to the first or second embodiment includes the following step performed after the step of depositing the metal layer:
In a non-restrictive embodiment the process according to the first or second embodiment the base material is a metal or an amorphous or partly amorphous metal alloy or a polymer, and the covering step is performed by pressing a block of base material onto the assembly comprising the substrate and the metal layer.
In a non-restrictive embodiment of the process according to the first or second embodiment the base material is metallic, and the covering step is performed by galvanic growth of the base material on the assembly comprising the substrate and the metal layer.
In a non-restrictive embodiment of the process according to the first or second embodiment the metal layer is formed from gold, silver, nickel or an alloy of the aforementioned metals.
In a non-restrictive embodiment of the process according to the first or second embodiment the insulating layer is formed from resin.
Other special features and advantages will become clear from the following non-restrictive description provided as an example with reference to the attached drawings, wherein:
According to a first embodiment illustrated in
According to a step Md_Sub shown in
In the example of
According to a step Md_Cis shown in
According to a step Md_Cga shown in
According to an optional step the metal layer CM is machined to reduce its thickness P and/or structure or polish its surface.
According to a step Md_Dis shown in
According to an optional step, a surface treatment of this assembly ES is conducted. This treatment is the application of a parting agent or a passivation treatment, for example. The significance of this step will be seen in the following text.
In a step Md_Enr shown in
According to a step Md_Dem shown in
At the end of step Md_Dem the mass VL of base material has a recess EV that corresponds in shape to the imprint of the pattern MT of the substrate SB, the base FD of which is the colour of the metal layer CM. It is noted that the transition between the mass VL of base material and the metal layer CM is clean. Moreover, as a result of imprints the mass VL has a textured appearance: the base FD of the recess EV has a mirror appearance similar to that of the crest ST of the substrate SB, and the surface SF of the mass VL that was previously facing the upper surface SP of the substrate SB has a mirror appearance similar to that of said upper surface SP.
It is noted that
The first embodiment thus allows production of a part PC provided with an enclosed external element. This external element is formed from a recess EV having a base FD with the colour of the metal layer CM, e.g. golden or silver. Moreover, the interface between the mass VL and the metal layer CM is clean without burrs. In addition, the metal layer CM is inseparable from the rest of the part. Finally, the surface SF of the part PC and the base FD of the recess EV are textured.
According to a second embodiment illustrated in
According to one step a conductive substrate SB′ is provided. The substrate SB′ is advantageously made from brass, but can be made from another material, e.g. stainless steel, aluminium, nickel etc. The upper surface SP′ of the substrate SB′ may possibly have been subjected to a surface machining operation to create a particular texture that is desired for the part, e.g. an engraving, as is evident from
According to a step Md′_Cis shown in
According to a step Md′_Uge shown in
According to a step Md′_Cga shown in
According to an optional step the metal layer CM′ is machined to reduce the thickness P′ of the lateral ends EL′ and/or structure or polish the surface of the metal layer CM′.
According to a step Md′_Dis shown in
According to an optional step a surface treatment of this assembly ES′ is conducted. This treatment is the application of an oil or a passivation, for example. The significance of this step will be seen in the following text.
In a step Md′_Enr shown in
According to a step Md′_Dem shown in
At the end of step Md′_Dem the metal layer CM′ forms an outgrowth EV′ on the mass VL′ that corresponds in shape to the imprint of the pattern MT′ in the substrate SB′. It is noted that the transition between mass VL′ of base material and the metal layer CM′ is clean. Moreover, as a result of imprints the mass VL′ has a textured appearance: the surface SF′ of the mass VL′ that was previously facing the upper surface SP′ of the substrate SB′ has a mirror appearance similar to that of said upper surface SP′.
Thus, the second embodiment enables a part PC′ provided with a raised external element to be produced. This external element consists of an outgrowth EV′ formed by the metal layer CM′. Moreover, the interface between the mass VL′ and the metal layer CM′ is clean without burrs. In addition, the metal layer CM′ is inseparable from the rest of the part. Finally, the surface SF′ of the part PC can be textured.
Moreover, the process according to the first or the second embodiment possibly includes the following additional steps that enable the appearance of the external element to be modified.
According to an optional step Md_Ddr shown in
The anchoring arms BA are advantageously used to hold an element such as a coloured resin, a fluorescent lacquer, a metal, a mineral etc. in place.
Hence, in an embodiment the process includes a step Md_Rsl, shown in
In an alternative embodiment the process includes a step of inserting a metal, a metal alloy or a composite into the cavity CV. The metal is inserted in liquid form, for example, then cooled to be solidified. Because of the anchoring arms it is then impossible to separate the metal from the mass VL, VL′. Alternatively, the metal can be deposited by galvanic growth. In this case, if the base material forming the mass VL, VL′ is not metallic, it is necessary to perform a step of depositing at least one thin metal film into the cavity CV by physical vapour deposition beforehand.
In an alternative embodiment the process includes a step Md_Min, shown in
Of course, the present invention is not limited to the illustrated example, but is open to various variants and modifications that will occur to the person skilled in the art.
Number | Date | Country | Kind |
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16170379 | May 2016 | EP | regional |
Number | Name | Date | Kind |
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20050126917 | Morimoto | Jun 2005 | A1 |
20100054089 | Maier | Mar 2010 | A1 |
20140177401 | Grossenbacher | Jun 2014 | A1 |
Number | Date | Country |
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2 543 625 | Jan 2013 | EP |
2 950 732 | Apr 2011 | FR |
Entry |
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European Search Report dated Nov. 11, 2016 in European application 16170379.8 filed on May 19, 2016 (with English Translation of Categories Cited Documents ). |
Number | Date | Country | |
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20170336762 A1 | Nov 2017 | US |