The present invention relates to a timepiece part, for example and nonlimitingly a dial or an oscillating weight. The present invention also relates to a method for manufacturing such a part.
Watches, especially luxury watches, made of metal, are often set with precious, semiprecious or synthetic stones.
Examples of precious stones for example and nonlimitingly include diamond, sapphire, emerald and ruby. Examples of semiprecious stones for example and nonlimitingly include spinal, amethyst, tourmaline, citrine and quartz.
Precious or semiprecious stones are often transparent.
Their table, i.e. the top portion of the stone, may have various shapes, it may for example be round, oval, square, heart-shaped, etc. These stones are cut in general so as to optimize their brilliance.
The ratio between the total width of the stone and its height is very important: for example a stone that is too flat or too thick will lead to a substantial loss of brilliance. The ratio chosen also depends on the type of stone and especially on the refractive index of the material. However, conventional stones made of the aforementioned materials have a height to width ratio of 65% to 80%. The height is therefore 65% to 80% of the width of the stone.
In this context, a stone is defined as flat if the ratio between its height and its width is lower than 50%.
Over the last few decades the use in the watch and clock making industry of flat stones, for example stones cut with what is referred to as a Russian cut, has gradually ceased. This is because flat stones exhibit brilliance defects, which manifest themselves in various ways and that as a general rule involve a loss of brilliance in an exterior or interior portion of the stone. One such defect is referred to as “fish eye”.
Therefore, to maximize the brilliance of set watches and jewelry, the dimensions of the stone as seen from in front (i.e. the dimensions of the table) are maximized. Thus, as a result of the proportion constraint (65% to 80%), the stone, and therefore its mount, is thicker. For this reason, in densely set commercially available timepieces, stones are in general wider in timepiece parts such as the bracelet or bezel, where the thickness constraints are less stringent than on the dial.
Other watches, which are also commercially available, comprise flat precious stones, for example having a height-to-width ratio of 40% to 45%. However, these stones have a brilliance that is clearly worse than that of non-flat stones.
Transparent stones that are said to be “colorful” or colored—which may be precious, semiprecious, natural or synthetic—have the particularity of not reflecting the entire spectrum of light, but only some of the spectrum in the visible field. Each colorful stone thus possesses a characteristic response spectrum to luminous stimulation.
In contrast to stones that are not colorful (or “colorless” stones), for which it is important to maximize the intensity and distribution of the reflected light, and therefore brilliance, for colored stones it is also important to maximize the coloring of the stone. As a general rule, the more intense the color of the stone, the greater its desirability.
In order to obtain a stone the color of which is as intense as possible, it is also important to maximize its height relative to its width. Colored stones therefore almost always have a conventional cut.
Precious or semiprecious stones are historically set into supports made of precious metals such as gold, platinum or silver. It is at the present time also common to use steel or brass, and sometimes titanium or aluminum.
Frequently, the titanium or aluminum is plated after the stone has been set, so as to obtain protection from corrosion and to maximize brilliance.
Mounts made of titanium or aluminum are in particular used to set parts having conventional dimensions (i.e. stones that are not flat); the contrast in the brilliance of the stones and the appearance of the titanium or aluminum sets off the stones. Such mounts made of titanium or aluminum therefore have a large thickness in order to accentuate the brilliance of the stones.
US2009229307 describes a timepiece part, for example a watch case, comprising a titanium or aluminum mount with apertures for receiving stones.
FR2855947 relates to a method for setting a stone into an element made of metal, for example of titanium. A tool is applied to the surface of the metal part in order to form a lip on the girdle of a stone. This lip allows the stone to be immobilized in its hole. With the tool, it is also possible to form imprints on the surface of the metal part, which may contain facets. The imprints located adjacent the stones allow the latter to be retained, the other imprints have the function of reflecting light.
EP2327323 relates to a decorative part, for example a timepiece part, comprising stones and a device for fastening the stones relative to one another, this fastening device comprising a single support allowing the stones to be attached relative to one another. The single support comprises at least two layers, the first of which may comprise titanium and/or aluminum.
FR2889423 relates to a removable piece of jewelry that may be used to create or modify a customized final piece of jewelry, without the need for a jeweler. This piece of jewelry comprises a movable device, consisting of a sleeve into which one or more stones or pearls are set, and having an aperture into which a cap, that is equipped with a spring, may be inserted. The sleeve and the cap may be made of titanium or anodized aluminum.
WO2008102957 relates to a decoration stone comprising various layers, especially: an aluminum mounting (plating) layer formed on a back surface of the stone body, a hot melt part formed on a lower surface of the aluminum mounting layer, a coating layer which is formed on an upper surface of the stone body and consists of a printing ink absorption fixing agent, a UV coating layer, and a painting layer.
JPS57101782 relates to a method for manufacturing a dial from a titanium sheet.
However there remains a need for thinner timepiece parts, for example and nonlimitingly dials, oscillating weights, hands, etc. set with colored stones, but in which the smaller thickness of the stones does not adversely affect their coloring.
In other words, there is a need for a method for setting parts of small thickness with colored stones.
In this context the expression “small thickness” indicates a thickness smaller than 1 mm, preferably smaller than 0.8 mm, for example 0.6 mm.
One aim of the present invention is therefore to provide a timepiece part exempt from at least certain of the limitations of known parts.
Another aim of the invention is to provide a timepiece part set with colored stones and having a small thickness, in which the stones are as colored as possible.
According to the invention, these aims are achieved especially by means of a timepiece part according to claim 1 and a method for manufacturing a timepiece part according to claim 11.
The timepiece part according to the invention comprises:
The ratio between the height and width of this stone may be lower than about 50%, i.e. the colored transparent stone is a flat stone. Advantageously, the mount is made of anodized titanium or anodized aluminum: specifically, these metals have a good optical behavior because they do not reflect all the light.
Mounts made of anodized titanium or anodized aluminum are known. Their use in combination with flat stones is however unexpected, because flat stones are generally considered to be less beautiful, and therefore have been discarded in the watch and clock making industry for tens of years.
In particular, the use of colored transparent flat stones is surprising, because there is a long-held prejudice in the watch and clock making industry and in the jewelry industry that says that it is not possible to obtain good coloring effects with flat stones.
A fortiori, the use of flat colored stones in combination with a titanium or aluminum mount is completely unexpected, because even if a person skilled in the art were to have envisioned such a combination, they would a priori have expected to obtain a part in which the flat stones were not very brilliant, suffered from fish eye defects, and contrasted poorly with the mount.
Against all expectation, tests have however shown that combining colored transparent flat stones with a mount made of anodized titanium or anodized aluminum allows stones with a significant coloring to be obtained despite their small thickness because the color given to the mount by the anodization process influences the color of the flat stones, which color may thus be reinforced and therefore improved.
The invention is therefore based on the observation that the brilliance and coloring of a stone must be evaluated depending on the mount on which it is mounted. A stone considered to be very beautiful in isolation may lose its qualities on an unsuitable mount; conversely, and in the way used in the invention, a stone considered to be of little value in isolation may prove to be outstanding on a particular mount.
The choice of a mount made of anodized aluminum or anodized titanium therefore allows the color and/or reflectance of the mount to be adapted to the type of stone that it is desired to set, in order to obtain a very brilliant and/or very intensely colored assembly even when the stones employed do not, themselves, have these qualities.
Specifically, if at least some of the stones have the same color as that given to the mount by the anodization process, a portion of the light passes through the stone and reaches the metal located underneath and is then reflected. The coloring of these light rays is therefore obtained by subtraction of certain wavelengths through the colorful stone, but also during the reflection from the metal. The coloring of the stone is therefore reinforced by the mount.
Therefore one of the advantages of the invention is the obtainment of colored transparent stones of significant coloring despite the small thickness of the mount (smaller than 1 mm, preferably smaller than 0.8 mm, for example 0.6 mm).
In a preferred variant, the surfaces defining the aperture for receiving the colored transparent stone are also anodized. In another preferred variant, the setting elements, for example claws or grains, are anodized or the same color as the mount.
Specifically, if the stone is a first color, the mount is a second color chosen so as to reinforce this first color. In a preferred variant this first color is equal to the second color.
In other words, there is a synergy between the first and second colors allowing the coloring of the mount to be added to that of the colored transparent stones. If a plurality of stones are present in the mount, this synergistic effect also allows the uniformity of the coloring of the part to be improved.
Specifically, in the case where colored transparent stones, which are preferably round and of various diameters, are “snow set”, i.e. placed as closely as possible to each other and with different cuts, it is very difficult to make the color of the stones uniform, certain stones being lighter or darker or having different colorings. The anodization of the mount allows a coloring to be added to the colored transparent stones and thus the uniformity of the color of the part to be improved.
In another variant, it is also possible to produce a shift between or even an intentional relative opposition of the colors of the mount and that of the colored transparent stone.
In another variant it is also possible to have a plurality of transparent stones of various colors and/or for the mount of the stones to have various colorings.
Another advantage of the invention is that it makes it possible to use large stones in a surround of small thickness, that would not be usable with a stone that was not flat. This advantage is moreover independent of the shape of the stone, which may be round or any other even complex shape (baguette cuts, marquise cuts, etc.).
In one preferred variant the aperture is a through-aperture, i.e. it passes right through the mount.
Placing through-apertures under each stone also allows a degree of transparency to be given to the part. This is all the more the case since the colored through-stones being flat, some of the light originating from the end opposite the table passes through the aperture and therefore illuminates the stones from behind.
Placing through-apertures under each stone also allows a “stained-glass window” effect to be achieved with the part, thereby allowing a coloring to be kept both when the light originates from in front and behind the set part.
Lastly, through-apertures under each stone allow a good uniformity for the anodization-produced coloring of the mount and cleaning out the treatment products after the mount has been colored.
In a preferred variant the timepiece part according to the invention consists of a dial. In another variant it consists of an oscillating weight.
The invention also relates to a method for manufacturing a timepiece part comprising the following steps:
Examples of implementation of the invention are indicated in the description illustrated by the appended figures, in which:
In the following description, which is given by way of example, reference will be made, for the sake of simplicity, to a dial. However, the invention is not limited to such a part. The invention is also not limited to the watch and clock making industry but also includes, for example, jewelry components.
The timepiece part 1 according to the invention comprises:
Advantageously, the ratio between the height h and the width L of the stone 10, as illustrated in
Advantageously, the mount 20 is made of anodized titanium or anodized aluminum. The anodization is as a general rule carried out after the part 1 has been set and polished.
Combining flat colored transparent stones 10 with a mount made of anodized titanium or anodized aluminum 20 allows stones 10 with a significant coloring to be obtained despite the mount 20 having a small thickness e (as may be seen in
Specifically, if at least some of the stones 10 have the same color as that given to the mount 20 by the anodization process, some of the light passes through the stone and reaches the metal located underneath and is then reflected. The coloring of these light rays is therefore obtained by subtraction of certain wavelengths through the colorful stone 10, but also during the reflection from the metal of the mount 20. The coloring of the stone 10 is therefore reinforced by the mount 20.
Therefore one of the advantages of the invention is the obtainment of colored transparent stones 10 of significant coloring despite the small thickness e of the mount 20 (smaller than 1 mm, preferably smaller than 0.8 mm, for example 0.6 mm), or in any case despite the small depth of the apertures into which the stones are set.
The colored transparent stone 10, shown in
In a preferred variant, illustrated in
Specifically, if the stone 10 is a first color, the mount 20 is a second color chosen so as to reinforce this first color. In a preferred variant, this first color is equal to the second color. If a plurality of stones are present in the mount, this synergistic effect also allows the uniformity of the coloring of the part 1 to be improved.
In the example in
The anodization of the mount 20 allows a coloring to be added to the colored transparent stones 10 and thus the uniformity of the coloring of the part 1 to be improved.
In the variant in
Through-apertures 200 under each stone allow the coloring process to reach the surfaces 26, 27, 28 of the mount 20 under the stones 10. Thy also allow a degree of transparency to be given to the part 1. Through-apertures 200 under each stone 10 also allow a “stained-glass window” effect to be achieved with the part 1, thereby allowing a coloring to be kept both when the light originates from in front and behind the set part.
Lastly, through-apertures 200 allow a good uniformity to be obtained for the anodization-produced coloring of the mount and for cleaning out treatment products after the mount has been colored.
Stones set into blind apertures may however also be used.
Number | Date | Country | Kind |
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0419/13 | Feb 2013 | CH | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/052497 | 2/7/2014 | WO | 00 |
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WO2014/122296 | 8/14/2014 | WO | A |
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