CH704686B1 - spring watchmaker wristwatch. - Google Patents

Abstract

The invention relates to a clock spring for a wristwatch comprising a casing (20), which spring is hollow or said spring comprises a core (10) made of a material lighter than that of the casing (20). In one embodiment of the invention, the watch spring is a barrel spring or a spiral spring for wristwatch lighter than the known springs. The barrel spring and / or the spiral spring may have a section that limits the contact area between the turns of the spring.

Description

Technical area

The present invention relates to a watch spring for a wristwatch, including a barrel spring or a spiral spring.

State of the art

The barrel of a wristwatch is an energy accumulator. It comprises a barrel drum, that is to say a cylindrical box closed by a barrel cover and a mainspring, housed in this box.

The known barrel spring is a blade with a generally rectangular section. Before being housed in the drum, it usually has an inverted S shape. When mounted in the drum, the barrel spring is deformed since it is wrapped around the shaft of the barrel which is in the center of the drum. This process is called strapping. The unfolding of the leaf of the mainspring which seeks to resume its initial form restores the energy necessary for the operation of a wristwatch. Once disarmed, the barrel spring is relaxed against the walls of the drum.

The barrel spring is moving during its course, which generates a loss of energy proportional to its mass. In other words, some of the stored energy is used by the barrel spring to move itself.

In addition, when the barrel spring is reassembled by the user, for example through the winding crown of the wristwatch, or automatically by the oscillating mass, the rectangular section turns, which are pressed against each other, touch each other along a surface that, by definition, includes an unlimited number of nips. When the barrel spring begins to unwind to try to return to its original form, the friction between the turns generates a loss of energy which is of the order of magnitude of about one third of the energy stored in the spring barrel. This reduces the power reserve of the watch accordingly.

Known solutions have been provided to limit this waste, for example by acting on the winding crown so that it does not completely coil the barrel spring. However, these solutions do not prevent the windings of the mainspring spring come into contact, for example during unwinding of the mainspring, which generates as discussed a loss of energy as mentioned above.

Other known solutions provide for the use of lubricants, for example conventional or synthetic oils or greases, between the turns of the mainspring. However, these solutions have disadvantages, since the oils have a strong tendency to oxidize in contact with the air and therefore have a limited duration of effectiveness and degrade over time, which generates a revision and maintenance constraint. . Fats for their part are of delicate use, having to be perfectly homogeneous and not having to produce microdroplets in case of shocks.

In addition, the closure of the drum box with the barrel cover is necessary to contain the lubricant and prevent it from coming out of the drum and move inside a wristwatch. This box normally has significant dimensions compared to those of other elements of a wristwatch, it prevents the user from seeing the barrel spring and, since its appearance generally affects the aesthetics of the movement, especially in the case of a skeleton or transparent watch, its placement in these types of watches poses problems.

The mechanical wristwatches further comprise a regulator member often constituted by a rocker on the axis of which is fixed a spiral spring called spiral spring. This spiral spring is normally constituted by a rectangular section blade wound on itself in the form of spiral Archimedes. The greater its oscillation frequency, and the better the measurement resolution of the watch or chronograph. Known solutions make it possible to increase this frequency of oscillation by reducing the dimensions of the spiral spring, which is detrimental to the aesthetics of the watch and prevents the user of the watch from fully understanding its operation.

Document DE 10 2005 054 314 describes a spiral spring of dimensions much larger than the dimensions of a spiral spring of the field of wristwatches, and intended to be used in the field of industrial mechanics, particularly in the field of car manufacturing. This spiral spring is made of a fiber-plastic composite material. It can be hollow. However, the use of a fiber-plastic composite material has disadvantages, mainly related to its high cost and low surface resistance to wear. The Young's modulus of some composite materials is very low compared to that of metal springs, which makes their use unsuitable for the manufacture of barrel springs or miniaturized spiral springs. In addition, the known composite materials tend to expand and deform with temperature, making them totally unsuitable for the manufacture of spirals for an isochronous regulating organ.

US 2007 133 355, US 3,528,237 and FR 1,533,876 disclose spiral springs of circular section, and US 2,647,743 a spiral of elliptical section.

There is therefore a need for a watch spring for a wristwatch, for example a mainspring and / or a spiral spring, which avoids at least one of the limitations of the state of the art mentioned.

Brief summary of the invention

An object of the present invention is to provide a watch spring free from the limitations of known clock springs.

Another object of the present invention is to provide a watch spring, for example a mainspring, which reduces the energy wastage related to its movement.

Another object of a variant of the present invention is to provide a watch spring, for example a mainspring, which reduces energy losses due to friction between turns during its unwinding.

Another object of the present invention is to provide a watch spring, for example a barrel spring, which can be visible from the outside of the movement or by the user of a skeleton or transparent wristwatch.

Another object of the present invention is to provide a watch spring, for example a spiral spring, which has dimensions that make visible its oscillations, but which also allows a temporal indication more accurate than the known solutions.

According to the invention, these objects are achieved by means of a clock spring for a wristwatch according to claim 1 and by means of manufacturing methods of a watch spring according to claims 13 and 14.

The watch spring for a wristwatch according to the invention comprises an envelope, it is hollow or comprises a core made of a material lighter than the envelope, that is to say in a material having a density. lower than the density of the envelope material.

In this context the word "envelope" with reference to a watch spring indicates its outer part, that is to say the part that is visible from the outside. The word "soul", on the contrary, indicates the inner part of the clock spring, that is to say the part that is not visible from the sides of the spring.

In the context of this invention it has been discovered that the part of a watch spring that deforms the most in case of stress is the envelope, the soul is only slightly affected by this deformation. It is therefore possible either to remove the core and thus obtain a hollow watch spring, or to make the core in a lighter material than the envelope. In both cases the watch spring has a mass which is less than the mass of a solid spring and mono-material, without substantially changing its ability to store and accumulate energy.

The advantages of this mass reduction are numerous: since in the case of a solid barrel spring and mono-material part of the stored energy is used by the barrel spring to move, if the spring barrel is hollow or has a lightened soul, almost all stored energy is returned to the wristwatch instead of being used for moving the mass of the spring itself.

In the case of a spiral spring, the mass is related to the oscillation frequency by a relationship of inverse proportion, that is to say that smaller is its mass and greater is its frequency. oscillation. In addition, the greater this oscillation frequency and the better the time resolution of the wristwatch. For example, a rapidly oscillating hairspring can count the time or times with a resolution of the order of 10 <e> or 100 <e> second, instead of the second or 1/5 <e> usual seconds. A hollow spiral spring or having a lighter core than the casing thus makes it possible to have an oscillation frequency and therefore a greater resolution than a solid spiral spring and monomaterial having the same dimensions and the same Young's modulus. or modulus of elasticity. In other words, it is possible to make a spiral spring which has the same high oscillation frequency as a known spiral spring of smaller size, which makes it possible to observe its oscillations and to understand its operation.

In a preferred embodiment, the envelope of the watch spring is made of amorphous material, for example amorphous metal. Several advantages are related to the use of an amorphous material: in fact, this material has a Young's modulus which is substantially larger than the Young's moduli of crystalline or non-amorphous materials, which allows a watch spring, for example example a barrel spring, store more energy. In addition, the elongation at break of an amorphous material, that is to say the characteristic that defines the ability of a material to elongate before breaking when subjected to traction, is substantially greater than the elongation of materials other than amorphous materials, which allows, for example, to tighten the barrel springs more and thus to store more energy. Finally, the amorphous materials can be polished so as to obtain more slippery surfaces than the materials used in the field of watchmaking, which makes it possible to reduce the friction between the turns of a mainspring during its unwinding.

In another variant the envelope of the watch spring is made of crystalline material, for example steel, invar steel or silicon.

The envelope may also be made of a material with a large elastic limit, or in any case greater than the elastic limit of the core if the spring is not hollow.

The envelope can also be made in a material with a weak Young's modulus, or in any case lower than the Young's modulus of the core if the spring is not hollow.

Either the spring is hollow or the core is made of a lighter material than the material of the envelope, for example polymeric resin or plastic.

As discussed, in a variant the watch spring according to the invention may be a mainspring. In another variant it may be a spiral spring.

Advantageously, the watch spring according to the invention can be manufactured with manufacturing processes such as photolithographic etching of an amorphous or crystalline substrate.

In another variant, the watch spring according to the invention may be manufactured by PVD (Physical Vapor Deposition) deposition, which makes it possible to produce a coating whose thickness may range up to about ten times. micrometers, or by thick PVD deposition, that is to say a PVD deposition which allows to obtain thicknesses up to a few millimeters or even centimeters.

According to a variant, the watch spring has a section such that the contact surfaces between adjacent turns are reduced to a limited finite number of lines, in order to reduce the friction between the turns and therefore the energy wasted by these rubs. In other words, the turns are no longer in contact along a surface, which by definition includes an unlimited number of lines, but along a line of contact or a limited number of contact lines.

In a variant the section of the watch spring has one or more ribs and / or projections. In another variant, this section is triangular. The triangular shape indeed makes it possible to optimize the reduction of the energy wasted by the friction between the turns; however, it does not allow optimum storage of energy in a mainspring during its reassembly, because of the empty space between the turns due to this triangular shape.

In another variant, the section of a watch spring according to the invention is circular or elliptical or ovoidal or polygonal or clover-shaped or clover-shaped with four or more sheets or any other form that ensures that the contacts between the Clockwise wind turns comprise a finite number of lines.

The realization of a spring with a core made of a lighter material than that of the envelope also allows better control of the deformation of the spring mode. For example, it is possible to provide a core which does not participate in energy storage during spring deformations according to the main mode of deformation of the spring, but which nevertheless makes it possible to stiffen it in order to avoid undesirable deformations according to other modes.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> Fig. 1 <SEP> illustrates a view of a turn of a watch spring according to an example of an embodiment of the invention. <tb> Fig. 2 <SEP> illustrates a section of an example of an embodiment of the watch spring according to the invention. <tb> Fig. [SEP] illustrates a section of an example of another embodiment of the watch spring according to the invention. <tb> Fig. <SEP> illustrates a section of an example of an embodiment of the watch spring according to an independent aspect of the invention. <tb> Fig. <SEP> illustrates a sectional view of three turns of an example of an embodiment of the watch spring according to the invention. <tb> Fig. [SEP] illustrates a sectional view of three turns of another example of an embodiment of the watch spring according to the invention. <tb> Fig. 7 <SEP> illustrates a sectional view of three turns of another example of an embodiment of the watch spring according to the invention.

Example (s) of embodiment of the invention

FIG. 1 illustrates a view of a turn 1 of a watch spring for a wristwatch according to an example of an embodiment of the invention. This clock spring comprises a core 10 and a casing 20. According to the invention the spring is hollow or the core 10 is made of a lighter material than the casing 20.

In the context of this invention it has been found that the part of a watch spring that deforms the most when a force or a torque is applied is the envelope 20, the core 10 not being that little affected by this deformation. It is therefore possible either to remove the core 10 and thus obtain a hollow watch spring, or to make the core 10 in a lighter material than the envelope 20. In both cases the watch spring is lightened and thus has a mass lower than that of a solid spring and mono-material.

As discussed, the advantages associated with this mass reduction are numerous: in the case where the watch spring according to the invention is a mainspring, almost all the stored energy is returned to the wristwatch and the energy loss. due to the displacement of the barrel spring is less than that produced by the displacement of a solid and mono-material barrel spring.

In the case of a spiral spring, the mass reduction makes it possible to increase the frequency of oscillation. It is therefore possible to produce a hairspring with the same high oscillation frequency as a smaller conventional hairspring: it is thus possible to observe its oscillations well and to understand its operation.

In a preferred embodiment, the envelope 20 of the watch spring is made of amorphous material, for example amorphous metal. Several advantages are related to the use of an amorphous material: in fact this material has a Young's modulus, or modulus of elasticity, which is substantially larger than the Young's moduli of materials other than the amorphous material, which allows a watch spring, for example a mainspring, to store more energy. Furthermore, the elongation at break of an amorphous material, i.e., the characteristic that defines the ability of a material to elongate before breaking when stressed in tension, is substantially greater. large than the elongation of materials other than amorphous, which allows for example a barrel spring to be more efficient. Finally, the amorphous materials have more slippery surfaces than the materials used in the field of watchmaking, which makes it possible to reduce the friction between the turns of a mainspring during its unwinding.

In another variant the envelope of the watch spring is made of crystalline material.

Either the spring is hollow, or the core 10 is made of a lighter material than the material of the envelope, for example polymer plastic resin or a metal or semiconductor less dense than the envelope .

Advantageously the watch spring according to the invention can be manufactured with manufacturing processes such as photolithographic etching of a substrate, which can be amorphous or crystalline. The etching process is the same as that used in the manufacture of microelectronic components, for example MEMS (MicroElectroMechanical Systems), in which silicon wafers are generally used as substrate. A "U" shaped portion of the envelope 20, visible in FIG. 2, is produced by a succession of epitaxial steps, resins, photolithography and dry or wet attack. In an alternative, these steps are performed around a sacrificial core, that is to say a core that will be removed in whole or in part at the end of the manufacturing process, giving rise to a hollow watch spring. In another variant this soul will be kept: in this case it will be made of a lighter material than the envelope 20. A lid or cap 22 is then bonded, for example glued, welded or packed, to the shaped part of " U "of the envelope 20. The cover 22 may be made of the same material as the envelope 20, for example made of silicon, or in any other material, using the same manufacturing techniques, for example by photolithography and / or different methods.

In another variant the watch spring according to the invention can be manufactured with the PVD deposition process, which allows to place around a core 10 visible in FIG. 3 a layer of material which constitutes the envelope 20, the thickness of which may be up to ten micrometers. In a variant, the core 10 may be sacrificial: it may be made of plastic and etched chemically after the deposition of the casing 20, in order to obtain a hollow spring. In another variant it will be preserved: in this case it will be made of a lighter material than the envelope 20.

In another variant the watch spring according to the invention can be manufactured with the thick PVD deposition process, that is to say a PVD deposition which allows to obtain thicknesses up to a few millimeters or even centimeters.

According to an independent aspect of the invention, the watch spring can be manufactured with the PVD deposition method, thick or not, by depositing around a core 10 two parallel layers 24, 26, visible in FIG. 4. The soul 10 in this case is not sacrificial. Indeed, the laid layers correspond to the parts of the watch spring which are the most stressed during a deformation of the spring. According to this aspect, the watch spring is therefore more efficient and more economical, since a lower number of layers is deposited (two instead of four).

According to another variant, the watch spring has a section such that the contacts between the turns of this spring are reduced to a limited number of lines, to reduce the friction between the turns and therefore the energy wasted by these friction . In other words, the turns are no longer in contact along a surface 30, visible in FIG. 5, which comprises by definition an unlimited number of lines, but along a single line of contact or a limited number of contact lines 40, visible in FIG. 6.

In a variant the section of the watch spring has one or more ribs and / or projections. In another variant this section is triangular, as shown in FIG. 7. The triangular shape indeed makes it possible to optimize the reduction of the energy wasted by the friction between the turns; however, it does not allow optimum storage of energy in a mainspring during its reassembly, because of the empty space 50 between the turns of the triangular shape.

In another variant, the section of a watch spring according to the invention is circular or elliptical or ovoidal or polygonal or in the form of clover or clover with four or more sheets or any other form that ensures that the contacts between the Watchmaker spring turns include a limited number of lines. In a variant, the core 10 may be constituted by several materials, for example by different layers of different superimposed materials.

The invention relates to a method for manufacturing a watch spring by photo-lithographic etching of a substrate, comprising a step of producing a "U" shaped portion of the envelope 20 by photo-etching. lithographic method of a substrate, the production step comprising the following steps: application of a photoresist in the form of a thin film on the surface of the substrate exposing the surface of the substrate to a luminous radiation removal of some parts of the photo-resin film.

The invention relates to a method of manufacturing a watch spring by PVD deposition, comprising a step of depositing a layer of a material around the core 10 to form the envelope, the step of filing comprising the following steps: Evaporation of the material under vacuum condensation of this evaporated material on a surface of the core in the form of a layer having a thickness of less than 50 micrometers.

Reference signs used in figures

[0053] <tb> 1 <SEP> Spire of the watchmaking spring <tb> 10 <SEP> Soul of watchmaking <tb> 20 <SEP> Clockwork Watch Envelope <tb> 22 <SEP> Cover or cap <tb> 24 <SEP> First parallel layer <tb> 26 <SEP> Second parallel layer <tb> 30 <SEP> Contact surface between two turns of the watchmaking spring <tb> 40 <SEP> Line of contact between two turns of the watchmaking spring <tb> 50 <SEP> Empty space between turns of the watchmaking spring

Claims (14)

A clock spring for a wristwatch comprising an envelope (20), characterized in that - Said spring is hollow or said spring comprises a core (10) made of a material having a lower density than the density of the material of said casing (20). 2. watch spring according to claim 1, said envelope (20) being made of amorphous material. 3. watch spring according to claim 1, said envelope (20) being made of crystalline material. 4. Watch spring according to one of claims 1 to 3, said watch spring being produced by photo-lithographic etching of a substrate. 5. Watch spring according to one of claims 1 to 3, said spring being made by PVD deposition. 6. watch spring according to one of claims 1 to 3, said spring being made by thick PVD deposition. 7. Watch spring according to one of claims 1 to 6, said watch spring being a mainspring. 8. watch spring according to one of claims 1 to 6, said watch spring being a spiral spring. 9. Watch spring according to one of claims 7 to 8, said watch spring having a section such that the contact surfaces between adjacent turns (1) of said watch spring are reduced to a finite number of lines (40). 10. Watch spring according to claim 9, said section having one or more ribs and / or projections. 11. Watch spring according to claim 9, said section being triangular. 12. Watch spring according to claim 9, said section being circular or elliptical or ovoid or polygonal or clover-shaped or four-leaf clover. 13. A method of manufacturing a watch spring according to one of claims 1 to 12, comprising a step of producing a U-shaped portion of the envelope (20) by photo-lithographic etching of a substrate, said production step comprising the following steps: Applying a photo-resin in the form of a film to the surface of said substrate; Exposing said surface of said substrate to a light radiation; Eliminating certain parts of said photoresist resin film. 14. A method of manufacturing a watch spring according to one of claims 1 to 12 by PVD deposition, comprising a step of depositing a layer of a material around the core (10) to form the envelope (20); said depositing step comprising the steps of: Evaporation of the material under vacuum; Condensing said evaporated material on a surface of said core in the form of a layer having a thickness of less than 50 micrometers.