The present invention relates to a watch case comprising a middle at least one opening of which is closed by a bezel and/or a crystal, or by a back, and in which at least one of the elements for closing the opening is linked to the middle by a resilient metal member in the form of a ring or an endless frame and having a recessed cross section defined by the contour of a non-rectilinear wall of controlled thickness whose ends are attached to the periphery of said closing element, respectively of the middle.
It may be advantageous to make the crystal or the back of a watch mobile relative to the middle, and do so without compromising the seal-tightness of the case, for example to improve the impact resistance, or to provide new functions. The solutions proposed in the state of the art are not satisfactory in this respect.
The documents CH630220 and CH686600 describe means for making a crystal move at variable frequencies by means of an electromagnet or a piezoresistive element. Mention is made of a thin annular ring which provides elastic suspension for the crystal. The mobility of the crystal relative to the middle is very limited both in the plane of the crystal and in the plane perpendicular to the crystal, and the seal-tightness is not guaranteed by construction.
CH 632387 and CH 698742 propose forming a resilient link piece between a sound generator and a watch crystal. This link piece is formed by a number of annular segments each having, seen in cross section, a rectilinear form, which has the effect of limiting the amplitude of the mobile piece associated with this link piece.
The document WO 2008027140 describes a mobile (tilting) bezel for activating different functions. The mobility of this bezel is due to a piece made of rubber or of polyurethane, which does not, however, ensure the seal-tightness and whose reliability can be doubted in the long term.
The aim of the present invention is to give a freedom of movement that is controlled in direction and in amplitude to the closing element fitted on the middle, bezel and/or crystal or even back, according to the role that is to be conferred on this closing element.
To this end, the subject of the present invention is a watch case as claimed in claim 1.
Advantageously, the profile of said wall includes a plurality of alternate annular folds, the number of which is between 1 and 10.
Preferably, the thickness e of said wall is constant and between 10 μm and 200 μm, the width a of the annular fold is between 0.2 mm and 4 mm, the pitch p of the annular fold being between >40 μm and 2.5 mm, to give said closing element a freedom of movement, with controlled stiffness and orientation relative to the plane of the opening.
Even more advantageously, the ends of the profile of said wall are linked in a seal-tight manner to the periphery of said closing element, respectively of the middle.
According to a preferred embodiment of the invention, seals are fitted between the respective cylindrical ends of said wall adjacent to cylindrical seats of said closing element, respectively of said middle and compression rings or frames in order to ensure the seal-tightness of said case.
Other particular features and characteristics of the present invention will become apparent from the following description and the appended drawings which illustrate, schematically and by way of examples, different embodiments and variants of the present invention.
a is an exploded perspective view of
The resilient metal member, in the form of a ring or endless frame and having a recessed cross section defined by the profile of a non-rectilinear wall, advantageously with a substantially constant thickness, whose ends are respectively attached to the periphery of a closing element and an opening of the middle of a watch case according to the present invention, forms a bellows comprising at least one annular fold formed by a curvature, the arc of which describes an angle of between >90° and 180°, to give said closing element a freedom of movement relative to the plane of the opening of the middle.
The metal bellows are elements formed from a thin metal wall, with a profile that is carefully chosen to confer a given flexibility, stiffness and resistance to the whole. There are several types of metal bellows: rolled, hydro-formed, chemically deposited, electroformed, this list being non-exhaustive.
The electro-formed bellows are of particular interest. Their manufacturing technique is more than 150 years old, but it is only over recent years that components with complex geometries and small (of the order of ten or so microns) and well controlled thicknesses have been able to be obtained. The challenge in controlling the thickness consists in acting on the deposition parameters (for example, distances between electrodes, nature of the electrodes, stirring and chemical composition of the bath, etc.) so as to minimize the thickness variations associated with the current density variations along a geometry with strong changes of curvature. Precise control of the geometry and of the thickness makes it possible to develop bellows with a suitable stiffness and that are capable of giving the element for closing the opening of the middle a freedom of movement relative to the plane of this opening. The companies Servometer and Nicoform are examples of miniature electro-formed bellows suppliers. These bellows are described, for example, in U.S. Pat. No. 3,187,639 and U.S. Pat. No. 5,932,360. The websites www.servometer.com and www.nicoform.com also give a lot of information on the technique and the materials used.
Such bellows can be joined to other rigid pieces to facilitate their integration. Care must be taken to ensure that the chosen assembly methods and the materials used are suited to the stresses that the assembly will undergo without the associated function being compromised.
The assemblies can be produced by gluing, by brazing or by welding by an electronic bombardment or by laser, or by a combination of at least two of these methods. If, for example, seal-tightness is to be guaranteed, gluing or tinning may prove insufficient. Furthermore, depending on the materials used, an excessively high temperature in the process may degrade their properties. If the constraints demand a good corrosion resistance, care must also be taken to use suitable materials or material pairings.
The substance used for the bellows is typically nickel or different nickel-based alloys with specific properties. Other materials such as gold, bronze, silver, titanium, tin, zinc or copper are possible alternatives, in solid form or as nickel-plating finishing coat. Furthermore, there are other polymer-based finishing coats. Given the above comments, it is possible to devise different variants of assembly and association of materials for specific applications. In each case, account must be taken of the materials involved when geometrically dimensioning the system to obtain a suitable stiffness. A few known examples are:
The embodiment illustrated by
The watch crystal 1 is linked to the middle 2 by a resilient metal member 3 in the form of a ring with a recessed cross section defined by the profile of a non-rectilinear wall of constant thickness, forming a metal bellows, the ends 3a, 3b of which are attached to the periphery of the crystal 1, respectively of the middle 2. An annular seal 4 surrounds the periphery of the crystal and the end 3a of the metal bellows 3. A compression ring 5, made for example of titanium, compresses the annular seal against the periphery of the crystal 1. The end 3a of the bellows is thus captive between the annular seal 4 and the crystal 1.
The other end 3b of the bellows 3 is fixed in the same way against a cylindrical portion of the middle 2 by an annular seal 6 compressed by a titanium ring 7. A bezel 8 is fixed to the middle by a ring 9 fixed against a seat formed on the outer lateral face of the titanium ring 7.
As can be appreciated, the crystal 1 is held only by an end of the bellows 3, such that it is suspended elastically over the middle 2. This assembly can then serve as an impact damper; it may be capable of tilting to activate functions; or else serve as a loudspeaker, a pressure-sensitive system (balance, barometer, etc.), without this list being limiting.
Other variants of the assembly method described in
It should be noted that the assembly methods described hereinabove are not limited by their method of manufacture to cylindrical geometries. It is possible to produce complex geometries combining curves and straight lines with a high degree of freedom, as in the embodiment illustrated by
We will now look at how the resilient metal member 3, 23, 33 in the form of a ring with a recessed cross section defined by the profile of a non-rectilinear wall of constant thickness, forming a bellows when it includes at least two adjacent folds forming a meander (
In the interests of simplicity, the descriptions of the stiffnesses are given firstly for a single meander, corresponding to n=1. The following parameters are therefore considered separately:
Stiffness as a function of wall thickness e
Stiffness as a function of the width a of a meander
Stiffness as a function of the dimension of the pitch p
The stiffnesses are defined by k, their index gives the vertical v, horizontal h or tilt b direction.
Taking into account the dependencies expressed in the above table, it is possible to seek to maximize the ratio kh/kv to facilitate and guarantee the self-guidance while having kv fixed. This ratio is a function of e−1.5, a1.5 and p−0.2. Thus, for a vertical stiffness value fixed by the physical data of the system being studied, it is possible to determine a suitable thickness range. Knowing that a is necessarily greater than e, efforts must be made to minimize p within the limits of the machining techniques. Furthermore, it is essential to guarantee that the strength limits of the material are not exceeded. For greater clarity in these explanations, a numerical example and appropriate limits are given hereinafter in the description.
It is first of all interesting to discuss the influence of the number n of meanders that is expressed according to the following relationships:
It is therefore essential to add a dependency at n−1 (for small n) in the ratio kh/kv described above. If it is to be maximized, it is therefore implicit to have the smallest n. Knowing that n can take only integer or half-integer values, n=0.5 would correspond to an ideal solution, but in the embodiments envisaged, n=1 is preferable. Furthermore, as mentioned above, it is also essential to take account of the strength limits of the materials in such a system, which is favored by increasing the value of n between 0.5 and 5, that is, between 1 and 10 alternate annular folds.
To sum up, guaranteeing the self-guidance of the system is equivalent to minimizing n and p for values of e and a linked to a stiffness defined by the physical function of the bellows.
Here, we want to illustrate and complement the above comments with two numeric examples that will be found in the following table:
These examples make it possible to define maximum and minimum limits of these various parameters according to the possible different uses of the element for closing the opening or openings of the middle of the watch case that is the subject of the invention:
The thickness e is bounded as follows:
The width a is bounded as follows:
The height p is bounded as follows:
Finally, n is bounded as follows:
The two examples described in the table thus give two production possibilities which allow for a watch-making integration of a metal bellows with self-guidance for two possible types of applications:
Number | Date | Country | Kind |
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09405052 | Mar 2009 | EP | regional |
09405202 | Nov 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CH2010/000061 | 3/8/2010 | WO | 00 | 9/16/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/105377 | 9/23/2010 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2237860 | Bolle | Apr 1941 | A |
3187639 | Kelly et al. | Jun 1965 | A |
3855786 | Yamamoto | Dec 1974 | A |
4199931 | Yokoyama | Apr 1980 | A |
4258432 | Zafferri et al. | Mar 1981 | A |
4668101 | Wuthrich | May 1987 | A |
5932360 | Hazlitt et al. | Aug 1999 | A |
7242641 | Sato et al. | Jul 2007 | B2 |
7619948 | Takasawa | Nov 2009 | B2 |
8411533 | Mieville et al. | Apr 2013 | B2 |
Number | Date | Country |
---|---|---|
259168 | Jan 1949 | CH |
259169 | Jan 1949 | CH |
630220 | Jun 1982 | CH |
632387 | Oct 1982 | CH |
686600 | May 1996 | CH |
698742 | Oct 2009 | CH |
0028429 | May 1981 | EP |
20081027140 | Mar 2008 | WO |
Entry |
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International Search Report of PCT/CH2010/000061, mailing date May 25, 2010. |
Number | Date | Country | |
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20120002513 A1 | Jan 2012 | US |