EP2102717A2

EP2102717A2 - Mechanical oscillator for timepiece

Info

Publication number: EP2102717A2
Application number: EP07857010A
Authority: EP
Inventors: Franck Orny; Stephen Forsey; Johnny Girardin
Original assignee: Complitime SA
Current assignee: Complitime SA
Priority date: 2006-12-21
Filing date: 2007-12-20
Publication date: 2009-09-23
Anticipated expiration: 2027-12-20
Also published as: JP2010513886A; EP2102717B1; US20100054090A1; WO2008080570A2; US8240910B2; WO2008080570A3

Abstract

Mechanical oscillator for timepiece having a balance (10) and a hairspring (12). The balance (10) and the hairspring (12) are made of the same material. This material is non-magnetic and possesses a very low thermal expansion coefficient.

Description

MECHANICAL OSCILLATOR FOR A HORLOGERIE PIECE

The present invention relates to a mechanical oscillator for a timepiece, and more particularly to a mechanical oscillator for a wristwatch which has a high degree of isochronism.

Various mechanical oscillators have already been proposed for wristwatches. In general, such oscillators are designed in the form of a balance spring which generates oscillations defining the natural frequency of the oscillator. This natural frequency divides the time into strictly identical units in order to order the escapement of a wristwatch to regulate the speed of its cog. Thus the precision of a wristwatch depends on the frequency stability of its sprung balance.

Several parameters such as temperature variations, magnetic fields and amplitude variations of pendulum oscillations affect the frequency stability of a balance spring. The temperature variations are likely to cause thermal expansion of the balance and spiral which essentially cause a variation in the moment of inertia of the balance and a variation of the return torque of the balance spring. Magnetic fields act essentially on the hairspring and are likely to disturb or cancel its action on the balance. The amplitude variations of the oscillations of the pendulum are related to the weight and the inertia of the pendulum and are likely to cause a defect of isochronism of the sprung balance. Thus, all these parameters are capable of modifying the natural frequency of the sprung balance. To compensate for variations in temperature, the materials used to produce the balance and the hairspring in the most frequently used mechanical oscillators are chosen so that the variation of the moment of inertia of the balance and the variation of the return torque of the respective hairspring compensate each other. Among the proposed solutions, we note in particular the use of a cupro-beryllium alloy balance associated with a spiral made of specially designed alloys such as invar and élinvar, which is an alloy of iron-nickel having a coefficient very weak dilatation. This type of balance spring is however always sensitive to magnetic fields. Thus, the search for new alloys that can be used for producing the hairspring is still relevant, as evidenced, for example, by the development of silinvar ^{™ 1} . The self-compensating result of these alloys is mainly the result of two contrary influences, notably that of the temperature and that of the magnetostriction on the modulus of elasticity of the metal.

To compensate for the effects of magnetic fields other than by the use of new alloys specially designed for this purpose, it has also been proposed to produce the spiral in a non-magnetic material, such as quartz for example, while producing the balance in cupro- beryllium as described above. This type of sprung balance is however sensitive to temperature variations.

To compensate for oscillator amplitude variations in order to minimize its isochronism defect, some factors must be taken into account including asymmetry of spiral expansion and contraction, changes in spring balance elasticity in response to changes in temperature, magnetic fields, attachment points of the hairspring, centrifugal forces and gravity, balance of the balance, friction and geometries. Minimizing the isochronism defect is crucial for optimizing the accuracy of mechanical watches. This consists in producing a spiral balance having a high degree of isochronism allowing it to generate oscillations equal and independent of their amplitude. Thus, a beam as light as possible is frequently used, with as much inertia as possible.

An example of a sprung balance designed to overcome the problems described above is illustrated in the document WO 2004/008529 A1. This sprung balance is provided with a balance composed of a non-magnetic ceramic for which the coefficient of expansion The spiral is positive and less than + l * 10 ^{~ 6} K ^"1. The hairspring is made from a composite of continuous carbon fibers of twisted or parallel texture with respect to the axial directions of the fiber. a thermosetting polymer matrix, thermoplastic or ceramic.The coefficient of thermal expansion of this composite is negative and greater than -l * 10 ^{~ 6} K ^"1 . More particularly, the materials used for producing the balance and the hairspring are selected so that the values of their coefficients of thermal expansion are similar, very small and of opposite signs. Thus, this sprung balance makes it possible to obtain a high precision and a more stable operation of the oscillator thanks to a self-compensating effect of the spiral.

The present invention aims to at least significantly reduce the self-compensating effect of the spiral. Thus, the present invention proposes a spiral balance which is in wide temperature ranges insensitive to variations in temperature. temperature to avoid dilation and variation of the moment of inertia of the pendulum. More generally, the object of the present invention is to propose a spiral balance having an improved stability of its frequency, both with regard to its sensitivity to variations in temperature and amplitude, as well as to magnetic fields.

This object is achieved by a mechanical oscillator comprising a balance and a spiral having the features of independent claims. Preferential variations of execution are the subject of the dependent claims.

More particularly, this object is achieved by a mechanical oscillator according to the invention, characterized by the production of the balance and the spiral in the same material. This embodiment of the balance and the hairspring from the same material avoids the compensating effect of the hairspring relative to the balance, which thus has an almost constant inertia. As a result, self-compensation between the balance and the balance spring becomes negligible.

The details of realization as well as the advantages of the sprung balance according to the invention will emerge from the following detailed description of an embodiment, given by way of example and illustrated by the appended drawings which show schematically:

Fig. 1 an enlarged view of the top of a mechanical oscillator according to the invention,

Fig. 2 an enlarged view of the mechanical oscillator of FIG. 1 in section, and Fig. 3 a diagram showing diurnal step variations of two different mechanical oscillators.

In the following detailed description of the accompanying drawings, identical elements are designated by identical identification references. In general, these elements and their functionalities are described once for reasons of brevity in order to avoid repetitions.

Figs. 1 and 2 illustrate, by way of example, a mechanical oscillator of the spiral-balance type comprising a balance 10 and a balance spring 12. The balance 10 comprises a shaft 14, a board 16 mounted rigidly on the shaft 14 and flyweights 18, d a first type, and 19 of a second type, a ferrule 20 and a plate 22. The spiral 12 is made of a material that may or may not be the same as that used to make the plate 16 of the balance 10.

According to a preferred embodiment of the present invention, the spiral 12 is made from the same material as the rocker 10. More specifically, the spiral 12 and the plate 16 of the balance 10 are made of the same material. This embodiment of the balance 10 and / or its plate 16, and the spring 12 from the same material avoids the compensating effect of the spiral 12 relative to the balance 10, which thus has an almost constant inertia. As a result, the self-compensation between the balance 10 and the balance spring 12 is almost negligible.

The material chosen to produce the rocker 10, and / or its board 16, and the spiral 12, is preferably non-magnetic and has the advantage of having a coefficient of thermal expansion of 20 to 2 * 10 ^{~ 10} ppm / ° C maximum. The thermal expansion coefficient is preferably 5-10 ^"6 ppm / ° C, and still more preferably 2-10 ⁶ ppm / ° C maximum. The density of the material is preferably in a range of 2.0 to 5.0 g / cm ³ , preferably 2.5 to 4.5 g / cm ³ , and still more preferably 3 to 4.0 g / cm ³ .

According to a preferred embodiment of the present invention, this material is diamond or synthetic diamond and, more generally, a diamond-based material. Nevertheless, other materials may be used, as described in more detail below, such as, for example, quartz, silicon, carbon, titanium or ceramic.

As shown in FIG. 1, the shaft 14 of the balance 10 has an axis of symmetry, designated as the axis AA, which is also its axis of pivoting. The shaft 14 is conventionally made of hardened steel and comprises a plate 14a, cylindrical portions 14b, 14c and 14d disposed on either side of the plate 14a and intended to receive respectively the shell 20, the plate 16 and the plateau 22. Its ends form pivots 14e and 14f intended to be engaged in bearings constituted in the frame of the timepiece, not shown in the drawing.

The board 16 has a central hole 16a and eight radially oriented openings defining eight arms 16b. The outer ends of the arms 16b are interconnected to form a serge 16c. The latter is pierced, in the extension of the arms 16b, holes 16d oriented parallel to the axis AA and in which the weights 18 and 19 are fixed. The base of the serge 16c may be made of a material other than the board 16. In this case, when the board 16 is for example made of diamond, a diamond coating may be applied to the serge 16c in order to obtain the same physical characteristics for serge 16c as for board 16.

More particularly, according to a preferred embodiment of the present invention, the rocker 10 and / or the spiral 12 are coated with nanoparticles of a material which is preferably non-magnetic and has the advantage of having a coefficient of thermal expansion of 20 to 2 * 10 ^{~ 10} ppm / ° C maximum. This coefficient of thermal expansion is preferably 5-10 ^"6 ppm / ° C, and still more preferably 2-10 ^{" 6} ppm / ° C maximum. The density of said material is preferably in a range of 2.0 to 5.0 g / cm ³ , preferably 2.5 to 4.5 g / cm ³ , and still more preferably 3 to 4.0 g / cm ³ . Preferably, the balance 10 and the balance spring 12 have a nano-diamond coating. This coating is also advantageously applicable to a sprung balance known to those skilled in the art, such as, for example, a sprung balance comprising a balance made of cupro-beryllium alloy associated with a spiral made of alloys specially studied as per example the invar.

As can be seen more particularly in FIG. 2, the board 16 is in abutment against the plate 14a and positioned by the cylindrical portion 14c. It is fixed to the shaft 14 by glue points 24 arranged in housings formed in the periphery of the hole 16a. The shell 20 is driven onto the shaft 14 in its cylindrical portion 14d, bearing against the board 16. It carries, mounted by gluing, the spring 12.

The board 16 is formed of a plate of a low density material with a low coefficient of thermal expansion, such as for example diamond, corundum, quartz or silicon, and whose thickness is of the order of a few tenths of millimeters. More particularly, this thickness is preferably in a range of 0.05 mm to 0.3 mm, and is typically 0.2 mm. As mentioned above, the hairspring 12 is made of a material that may or may not be the same as that used to make the balance 10 and / or its board 16. Thus, the material used to make the hairspring 12 may also be used. be selected from the above exemplified materials, ie diamond, quartz, silicon or corundum. The elasticity and length of these materials vary very little with temperature.

The weights 18 are each formed of a cylindrical nail 18a having an axis of symmetry, designated in FIG. 1 as the BB axis, of heavy material whose density is greater than 15 g / cm ³ , for example gold or platinum, provided with a head 18b and a body 18c, and a ring 18d made of the same material. The body 18c of each of the weights 18 is engaged in a hole 16d, the head 18b bearing against the board 16. The ring 18d associated with it is fixed on the other side of the board 16, by driving, gluing or welding.

The weights 18 have a symmetrical structure with respect to the axis BB of each of the nails 18a. In this way, during changes in temperature, the nails expand or contract radially relative to the axis BB, without their center of gravity moves. Consequently, as a first approximation, this expansion does not modify the inertia of the pendulum.

The weights 19 have a center of gravity offset from the axis of the hole 16d in which they are engaged. In this way, by turning them, it is possible to modify the moment of inertia and thus correct the frequency of the oscillator. To allow this rotation, the weights 19 comprise a cylindrical portion 19a provided with axially oriented slots 19b, allowing a frictional attachment.

As mentioned above, the material used to make the balance 10 and the spiral 12 of the mechanical oscillator according to the present invention is likely to be insensitive to temperature. In addition, this material is likely to be consistent with the margins established by the Swiss chronological chronometric criteria listed in Table 1 illustrated below.

Nonlimiting examples of materials satisfying the criteria indicated in Table 1, which are thus usable in the context of the present invention, are diamond, titanium, ceramic and quartz, as already described in more detail above. These materials have the following physical properties:

Volumic mass:

- Diamond: 3.515 g / cm ³

- Grade 5 Titanium: 4.42 g / cm ³

- AI ₂ O ₃ ceramic: 3.9 g / cm ³

- Quartz: 2.6 g / cm ³

Coefficient of thermal expansion:

- Diamond: 1-10 ^"6 ppm / C °

- Grade 5 Titanium: 9-10 ^"6 ppm / C °

- Ceramic AI ₂ O ₃ : 8 ^• 10 ^"6 ppm / C °

- Quartz: 0.5- 10 ^"6 ppm / C °

Thanks to this particular selection of the nonmagnetic material used for producing the balance 10, and / or its board 16, as well as the spiral 12, a low coefficient of thermal expansion and an optimized mass-radius ratio are obtained. More particularly, as the mechanical oscillator of FIGS. 1 and 2 comprising the balance 10 and the spiral 12 is made from a very stable material relative to the temperature, its frequency is very stable and varies very little depending on the temperature. This frequency stability is enhanced by the fact that the flyweights 18 have a fixed center of gravity with respect to the axis of the balance 10. This makes it possible to achieve a high degree of isochronism of the mechanical oscillator according to a preferred embodiment of the invention. of the present invention, as illustrated in FIG. 3.

Fig. 3 illustrates a diagram showing exemplary diurnal cycle variations of two different mechanical oscillators by way of example. These diurnal cycle variations are represented in seconds ([s]) on an axis 41, depending on the different temperatures at which the corresponding mechanical oscillators were tested. These temperatures are represented in degrees Celsius ([ ⁰ C]] on an axis 31.

A first curve 30 illustrates a diurnal step variation of a timepiece comprising a standard mechanical oscillator. As shown in FIG. 3, this day-time variation is between a 6-second advance, as indicated by point 32, and a delay of 4 seconds, as indicated by point 34, when the timepiece is tested in a range. of temperatures between +8 and +38 ⁰ C.

A second curve 40 illustrates a diurnal step variation of this timepiece when it is made with a mechanical oscillator according to a preferred embodiment of the present invention. As shown in FIG. 3, in this case the variation in daytime running is between a zero advance, as indicated in point 42, and a delay of approximately 1.3 seconds, as indicated in point 44, during the test of the workpiece. in the temperature range between +8 and +38 ⁰ C.

It will be noted, however, that this frequency stability relative to the temperature of the mechanical oscillator according to the invention is added to other advantages obtained by the choice of the material used. For example, the materials constituting the balance 10 and spiral 12 being non-magnetic, a magnetic field can not interact with them. Only in the configuration described above, which uses the shaft 14 made of hardened steel, a magnetic field can interact with the shaft 14, but the influence of this interaction is virtually zero. Finally, since the specific mass of the constituent material of the board 16 is small, while the material constituting the weights 18, 19 is high, the total mass of the balance 10 is low for a given moment of inertia. As a result, the isochronism defect can be further reduced.

Weights 18, 19 gold or platinum can realize the balance 10 with a moment of inertia / mass ratio particularly favorable. It is also possible to use less expensive materials, for example brass or invar. In the latter case, the expansion of the weights 18, 19 could be further reduced.

In general, pendulums for timepieces must be balanced. This can be done by removing or adding material. This operation is particularly advantageous by working on the weights 18, which have a symmetrical structure with respect to their axis BB. In. more, at least a portion of said flyweights 18 preferably has a cylindrical shape of axis BB in their portion engaged in the board 16. In order to avoid that the symmetry of these is affected, it is possible to remove the material either mechanically or by laser firing, ensuring that this is done evenly over the entire surface or symmetrically with respect to the BB axis. It is also possible to add material by spraying on one or the other of the weights 18, always being careful to keep the symmetry with reference to the axis BB. Thus, the present invention also claims a method of balancing by removal or addition of material from / to the balance 10, characterized in that material is removed from at least one of said weights 18 so symmetrical with reference to the axis of the cylinder or in that the equilibration is achieved by adding the material to at least one of the weights 18 symmetrically with reference to the axis of its cylinder.

Finally, the material used to make the weights 18 preferably has a specific mass greater than 10. It may be in particular gold or platinum, while the balance 10 and the spiral 12 are made of diamond. In this way, the ratio between the moment of inertia and the specific mass is particularly favorable.

It will also be noted that, depending on the material of the board 16, it is also possible to add or remove material and more particularly on the 16c serge.

Although a particular embodiment is described above, multiple variations can be made to the mechanical oscillator according to the invention without impairing its functionality. As a result, all these variations are also considered and generally contemplated.

Claims

1. Mechanical oscillator for a timepiece comprising a balance (10) and a spiral (12), wherein the balance (10) and the spiral (12) are made from the same first material.

2. Mechanical oscillator according to claim 1, wherein said rocker (10) comprises a board (16), a shaft (14) carrying said board (16) and weights (18, 19) mounted on said board (16), and wherein said tree

(14) and said weights (18, 19) are made from at least one other second material.

3. Mechanical oscillator according to claim 2, wherein said shaft (14) is made of hardened steel and at least a portion of the weights (18) is made of a heavy material whose density is greater than 15 g / cm ³ .

4. Mechanical oscillator according to one of the preceding claims, wherein the first material has a low coefficient of thermal expansion of 2 * 10 ^{~ 6} ppm / C ° maximum.

5. Mechanical oscillator according to one of the preceding claims, wherein the first material is non-magnetic.

6. Mechanical oscillator according to one of the preceding claims, wherein the density of the first material is in a range of 2.0 to 5.0 g / cm ³ .

7. Mechanical oscillator according to one of the preceding claims, wherein the first material is of diamond, quartz or ceramic type.

8. Mechanical oscillator according to claim 7, wherein the first material is diamond-based.

9. Mechanical oscillator according to one of the preceding claims, wherein the timepiece is a wristwatch.

10. Mechanical oscillator according to one of the preceding claims, wherein the rocker (10) comprises a board (16) having a thickness in a range of 0.05 mm to 0.3 mm.

11. Mechanical oscillator for a timepiece comprising a balance (10) and a balance spring (12), in which the balance (10) comprises:

a board (16) made of a first material,

- a shaft (14) carrying said board (16) and intended to pivot the balance about a pivot axis,

- weights (18, 19) mounted on said board

(16), distributed symmetrically with respect to said pivot axis, said spring (12) being made of a second material and said first and second materials being selected from diamond and quartz.

The mechanical oscillator of claim 11, wherein said first and second materials are the same.

Mechanical oscillator according to claim 11 or 12, wherein at least a part of said flyweights (18) has a cylindrical shape with respect to an axis of symmetry in their portion engaged in said board (16), said weights (18) having a symmetrical structure with reference to the axis of symmetry.

14. Mechanical oscillator according to one of claims 11 to 13, wherein said weights (18) are made of a third material having a density greater than 10.

The mechanical oscillator of claim 14, wherein the third material is a heavy material having a density greater than 15 g / cm ³ .

16. Mechanical oscillator according to one of claims 11 to

15, wherein the first material is diamond.

17. Mechanical oscillator according to one of claims 11 to

16, wherein the board (16) has a thickness in a range of 0.05 mm to 0.3 mm.

18. A material balancing balancing method (10) for a mechanical oscillator according to claim 13, wherein material is removed from at least one of said symmetrical weights (18) symmetrically with reference to its axis of symmetry.

19. Method of balancing by adding material, a rocker arm (10) for a mechanical oscillator according to claim 13, wherein material is added to at least one of said symmetrical flyweights (18) in a symmetrical manner. reference to its axis of symmetry.