CH708657A1 - Pendulum to clockwork adjustable inertia moment. - Google Patents

Abstract

The invention relates to a pendulum (1) for a clockwork movement with an adjustable moment of inertia, comprising a flywheel (10) with a rotation axis AA, moment of inertia I, and mounted on a flywheel. inertia (10), an adjustment device (20) of the moment of inertia I, of axis of inertia Δ coincides with the axis of rotation AA, comprising at least two flexible blades (23a, 23b) forming a winding of variable compactness about the axis AA, and a first mounting means (21), the blades (23a, 23b) being secured, at a first end, of the first mounting means (21). According to the invention, the adjustment device (20) further comprises a second mounting means (22) on the flywheel (10), the blades (23a, 23b) being integral, by the other end, with the second means of mounting (22). In addition, the second mounting means (22) is rotatable about the axis AA so as to adjust the degree of compactness of the winding.

Description

Description

The present invention relates to the field of watchmaking. It relates more precisely a balance for watch movement whose moment of inertia is adjustable finely and easily.

The balance forms, with the spiral spring, the regulating member of the movement, that is to say the reference member of the unit of time. This reference is given by the oscillation frequency of the pendulum-balance assembly, which is generally between 2.5 Hz and 5 Hz. The accuracy of the frequency f directly determines that of the movement, hence the interest of the improve by fine adjustment devices. Currently, a precision of the frequency f of the order of one per thousand is easily reached, which corresponds to an accuracy of the order of a few seconds per day. The present invention proposes to increase this value by a factor of ten.

The oscillation frequency f of the balance-balance oscillator is given by the following relation:

2π V / the value f depends either on the ratio M / 1, or on the individual precision of the respective values of the moment I and the torque M. One way of increasing the accuracy of the frequency f is to classify the pendulums and the spirals into depending on the value of the parameters M and I, then pair them judiciously. This method is widely used, but it does not preclude separately optimizing the accuracy of the torque M and the moment I, in order to avoid an excessive distribution of these values, and, finally, the rejection of a large number the rooms. In practice, we will therefore seek to produce spirals and balances of great precision.

The balance typically comprises a flywheel formed of a peripheral serge connected to a central hub by a junction surface. Its moment of inertia depends on the spatial distribution of the mass within this structure. Several means are known to those skilled in the art, in order to adjust this moment of inertia to a desired value.

Conventionally, weights are fixed to the serge by screwing or driving, as described in EP 1 351 103, EP 1 837719, or EP 2 395 402. Such an operation requires a large number of fine manipulations comprising risks of breaking the balance. It is therefore long and expensive. In addition, a major difficulty of this type of device is to make coincide the inertia axis of the balance with its geometric axis, which is also its axis of rotation. Indeed, if the arrangement of the weights is asymmetrical, or if one of them escapes during walking, the center of inertia is moved relative to the geometric center. There is then an imbalance, which greatly impairs the smooth operation of the regulating organ.

Alternatively, it is known to mount on the central hub of the flywheel, a rotary lever provided with two arms for moving radially massive elements mounted on the balance, between the hub and the serge. Said elements are, for example, flexible arms, articulated arms or flyweights. Such devices are described in US 2,880,570, US 2,770,942 and FR 1,322,923. Their use is limited because of their complexity, the number of parts required and the difficulty of mounting them.

One of the aims of the present invention is to overcome the various aforementioned drawbacks, by proposing a balance provided with a device for adjusting the moment of inertia of simplified design, having a great fine tuning and easy assembly without risk of unbalance. In addition, the present adjustment device proposes to achieve a precision of the moment of inertia much higher than that reached in the state of the art. More specifically, the present invention relates to a pendulum for a clockwork movement with an adjustable moment of inertia, comprising: an flywheel having an axis of rotation AA, of moment of inertia I, and mounted flying over inertia, a device for adjusting the moment of inertia I, of axis of inertia Δ coincides with the axis of rotation AA, comprising at least two flexible blades forming a winding of variable compactness about the axis AA, and a first mounting means, the blades being integral, by a first end, of the first mounting means. According to the invention, the adjustment device further comprises a second mounting means on the steering wheel, the blades being integral, by the other end, of the second mounting means. In addition, the second mounting means is rotatable about the axis AA so as to adjust the degree of compactness of the winding.

With mounting means positionable in rotation about the axis AA, the mass of the resilient blades can move radially on the flywheel, winding or unwinding in a simple and continuous manner. For this, simply move said mounting means angularly about the axis AA, in one direction or the other, depending on whether the moment of inertia I must be increased or decreased. The moment of inertia of the balance is thus modified without displacement of its center of inertia, since the axis of inertia Δ of the adjustment device coincides with the axis of rotation AA of the flywheel, and that the rotational movement of the mounting means does not change the position of said axis of inertia, but only the radial distribution of the mass of the blades. The range of adjustment of the moment of inertia I and the fineness of its adjustment are given by the length, the geometry, and the mass of the blades, which can form a winding of variable length and compactness. The adjustment of the moment of inertia is done continuously, over a range extending from a minimum value corresponding to a maximum number of turns of the winding, to a maximum value corresponding to a minimum number of turns in which M is the elastic torque of the spiral and I is the moment of inertia of the balance. It appears that the precision of

2 of the winding. It is thus possible to adjust the moment of inertia of the balance without complicated handling, with extreme precision and a wide adjustment range.

Other features and advantages of the present invention will appear on reading the description which follows, given solely by way of example and with reference to the accompanying drawings, in which: FIGS. 1 and 2 figs. 3a and 3b in FIG. 4 are respectively views from above and in section of a balance according to the invention, represent the balance according to the invention respectively in the minimum and maximum inertia position, and is a perspective view of the balance wheel mounted on a balance bridge .

The balance shown in fig. 1 and 2, respectively in plan view and in section, and referenced as a whole 1, comprises an inertia flywheel 10 of axis of rotation AA, conventionally formed of a central hub 11 connected to a peripheral serge 12 by a joining surface 13. The assembly is rigid and has an axis of inertia coincides with the axis of rotation AA, so that the rotational movement about the axis AA is free of imbalance. For this purpose, and conventionally, the joining surface 13 consists of an even or odd number of spokes arranged at regular angular intervals, as shown in FIG. 1 and 2, or a continuous surface. The flywheel 10 may be made of metal, for example, brass, nickel, or titanium, or a metal alloy, or silicon, using micromachining techniques known to man business.

The moment of inertia I of the flywheel 10 thus described has a fixed value, determined by its geometry and the material used to constitute it.

The rocker 1 further comprises an adjustment device 20 of the moment of inertia I, generally plane, mounted on said wheel 10, and for adjusting the moment of inertia I to a given value. The adjustment device 20, of axis of inertia Δ, comprises a first and a second mounting means, 21, 22, respectively at the central hub 1 1 and the peripheral serge 12, connected to each other by two flexible blades 23a. , 23b, of greater length than the radius of the flywheel 10, symmetrical with respect to the axis of inertia Δ. The flexible blades 23a, 23b are secured to the first and second mounting means 21, 22, respectively, by one and the other of their ends. They are, optionally, equipped with weights intended to increase their own mass, preformed or not, and geometry chosen according to the parameters of the balance 1. Alternatively, the flexible blades 23a, 23b are formed of a cellular structure intended to reduce their density. As an alternative to this embodiment, the elastic blades are three, four or more, and arranged at regular angular intervals. Preferably, one will opt for an adjustment device 20 having between two and four preformed flexible blades, which form, in the rest position, a winding comprising between one and five turns.

The adjustment device 20 is mounted centrally on the flywheel 10, which means that its axis of inertia Δ coincides, by construction, with the axis of rotation AA of the flywheel 10. A this effect, the mounting means 21, 22 are themselves autocentered with respect to the axis AA, and the flexible blades 23a, 23b are symmetrical with respect to the axis of inertia Δ. Thus, the mounting of the adjustment device 20 on the wheel 10, does not create unbalance, and this, by construction of the assembly.

In the present embodiment, the first mounting means 21, the central hub 1 1, is formed of an elastically deformable rhombus, whose inner faces form friction surfaces 41. Alternatively, the first means of mounting 21 is formed of a square, a rectangle, a hexagon, or other elastically deformable polyhedron. The central hub 1 1 has, for its part, a cylindrical outer surface, forming a bearing surface 51, in contact with which come the friction surfaces 41. The central hub can obviously be the arbe of the friction coefficient between the surfaces 41 and 51 are chosen so that the diamond is locked angularly by the friction force acting during the operation of the balance 1. In order to ensure the self-centering of the adjustment device 20, the geometric axis of the rhombus is located on the axis of inertia Δ of the adjustment device 20, and the geometric axis of the bearing surface 51 coincides with the axis of rotation AA.

The second mounting means 22, at the peripheral serge 12, is formed of an elastically deformable elliptical ring whose external face forms a friction surface 42. The peripheral serge 12 comprises, for its part, a surface internal cylindrical forming a bearing surface 52, in contact with which comes the friction surface 42. As previously, the coefficient of friction between the surfaces 42 and 52 is chosen so that the elliptical ring is locked angularly by the friction force s exercising during the operation of the balance 1. The elliptical ring further comprises two holes 32a, 32b, symmetrical with respect to the axis of inertia Δ, formed in two bulges provided for this purpose, and intended for the gripping and handling of the elliptical ring. Similarly, for the purpose of self-centering the adjustment device 20, the geometric axis of the elliptical ring coincides with the axis of inertia Δ of the adjustment device 20, and the geometric axis of the surface 52 is merged with the axis of rotation AA.

The adjustment device 20 being mounted on the flywheel 10 with the mounting means 21, 22, the flexible blades 23a, 23b take place in the space between the peripheral serge 12 and the central hub 1 1, in

3 forming a winding that can count one or more turns, or only a portion of turn, depending on the length of the arms 23a, 23b. Thanks to the self-centering properties of the mounting means (21, 22) with respect to the axis AA, and the symmetry of the flexible blades 23a, 23b with respect to the axis of inertia Δ of the adjustment device 20, the axis of inertia Δ coincides with the axis of rotation AA, and the flywheel 10 is, by construction, free of imbalance. This property is retained whatever the degree of winding of the flexible blades 23a, 23b, which retain their symmetry when their degree of winding varies.

The adjustment device 20 is preferably made of metal, in one piece, by a LIGA type process, consisting of an electrodeposition of a metal in a two-dimensional structure obtained by photolithography. This process makes it possible to obtain flat parts with high precision and complex shapes. Alternatively, the adjustment device 20 will be made of silicon, by physicochemical micromachining of a silicon wafer. It is possible, thanks to these manufacturing processes, to preform the flexible blades 23a, 23b in a more or less tight winding.

Referring now to FIGS. 3a and 3b which illustrate the principle of operation of the adjustment device 20 of the moment of inertia I of the balance 1 according to the invention. The adjustment device 20 of the moment of inertia I is mounted on the flywheel 10 with a tweezer whose pointed ends are introduced into the holes 32a, 32b. The relative angular position of the mounting means 21, 22, respectively at the central hub 1 1 and the peripheral serge 12, determines the degree of winding of the flexible blades 23a, 23b, between the hub 11 and the serge 12. Thus, the variation of the relative angular positions of the elliptical ring and the diamond changes the distribution of the mass within the balance 1, and therefore its moment of inertia I.

In fig. 3a and 3b, there is shown the balance 1 according to the invention, in moment of inertia position I, respectively, minimum and maximum. When the flexible blades 23a, 23b, form a compact winding around the central hub 1 1, by a given relative positioning of the mounting means 21, 22, the mass of the adjustment device 20 is moved towards the axis AA, and the moment of inertia I is minimum. Conversely, when the flexible blades 23a, 23b are pushed towards the serge 12 by the relative position of the mounting means 21, 22, the mass of the adjustment device 20 is moved outwards, and the moment of inertia I is maximum. Between these two extreme positions, a wide range of values of I is possible, depending on the length of the flexible blades 23a, 23b, and their geometry. The adjustment range of the moment of inertia increases with the length of the flexible blades 23a, 23b, and the fineness of the adjustment increases as the length of the blades 23a, 23b decreases. By way of example, the following numerical values will be given. Considering a flywheel 10 of moment of inertia I equal to 180mg / cm <2>, and an angular positioning accuracy of the elliptical ring 22 of 1 °. For an adjustment device comprising two arms forming five turns in the rest position, the setting range of the moment I is 1.6 mg / cm 2, which is equivalent to a resolution of 6.4 E-3 mg / cm. <2>, 0.47 seconds per day. For an adjustment device comprising two arms forming a turn in the rest position, the setting range of the moment I is 1.82 mg / cm 2, which equates to a resolution of 5E-3 mg / cm 2 > 0.27 seconds per day.

Note that, in this case, the two mounting means 21, 22 are rotatable about the axis AA, but the same result is achieved if one of the mounting means is fixed in rotation and the other positionable in rotation. One of the two mounting means 21, 22 may be fixed by gluing, welding, or any other suitable means, the central hub 1 1 or the peripheral serge 12. For practical reasons, and as it appears in FIG. 4, it is preferable to leave the elliptical ring 22 positionable in rotation, because it is more accessible once the rocker mounted on the balance bridge 60 by means of a balance shaft 61. The moment of inertia I can then be adjusted in normal operating condition.

Thus has been described a pendulum for clockwork with adjustable moment of inertia. Of course, the present invention is not limited to the embodiments described above, but extends to all variants within the scope of those skilled in the art, falling within the scope of the claims below. In particular, the person skilled in the art could be made to mount the first mounting means 21 of the adjustment device directly on the balance shaft 61, rather than on the central hub 1 1. The rocker 1 being mounted integral with the 61, the adjustment device 20 of the moment of inertia is mounted indirectly to the flywheel 10, with the first mounting means 21. This option is possible, in the case where the hub is small size or even nonexistent.

Listing:

[0022]

1: Rocker

10: flywheel

1 1: central hub

12: peripheral serge

13: joining surface

4

Claims (12)

20: adjustment device 21: first mounting medium 22: second mounting medium 23a: flexible blade 23b: flexible blade 32a: hole 32b: hole 41: friction surface of the first mounting means 42: friction surface of the second mounting means 51: bearing surface of the central hub 52: bearing surface of the peripheral serge 60: bridge of the pendulum 61: balance shaft claims 1. Pendulum for a clockwork movement with adjustable moment of inertia, comprising: an flywheel (10) with axis of rotation AA, moment of inertia I, and mounted on said flywheel (10), - An adjustment device (20) of the moment of inertia I, of axis of inertia Δ coincides with the axis of rotation AA, comprising at least two flexible blades (23a, 23b) forming a variable compactness winding around of the axis AA, and a first mounting means (21), the blades (23a, 23b) being integral, at a first end, with said first mounting means (21), characterized in that said adjustment device ( 20) further comprises a second mounting means (22) on the flywheel (10), said blades (23a, 23b) being integral, by the other end, of said second mounting means (22), and in that said second mounting means (22) is positionable in rotation about the axis AA so as to adjust the degree of compactness of the winding. 2. Pendulum for a watch movement according to claim 1, characterized in that said flywheel (10) is formed of a peripheral serge (12) connected to a central hub (11) by a connecting surface (13). ), and in that said first and second mounting means (21, 22) are mounted respectively on said central hub (11) and said peripheral web (12). 3. Pendulum according to one of claims 1 and 2, characterized in that said adjustment device (20) is mounted centrally on said flywheel (10). 4. Pendulum according to claim 2, characterized in that said mounting means (21, 22) are of axis of inertia Δ, and are mounted self-centering on said flywheel (10), and in that said blades hoses (23a, 23b) are arranged symmetrically with respect to the axis of inertia Δ. 5. Pendulum according to one of claims 2 to 4, characterized in that said first and second mounting means (21, 22) are elastically deformable and have friction surfaces (41, 42), and in that the serge peripheral (12) and the central hub (11) have bearing surfaces (51, 52), said friction surfaces (41, 42) engaging respectively with said bearing surfaces (51, 52), coefficient of friction between said friction surfaces (41, 42) and said bearing surfaces (51, 52) being chosen so that said mounting means (21, 22) are angularly locked by the friction force exerted during the operation of the balance. 6. Pendulum according to claim 5, characterized in that said first mounting means (21) is formed of an elastically deformable rhombus, of geometric axis coincides with said axis of inertia Δ, whose inner faces form one of said surfaces. friction (41), and in that said central hub (11) has a cylindrical outer surface, of geometric axis coincident with the axis of rotation AA, forming one of said bearing surfaces (51). 7. Pendulum according to claim 5, characterized in that said second mounting means (22) is formed of an elastically deformable elliptical ring, geometric axis coincides with said axis of inertia Δ, whose outer face forms one of said friction surfaces (42), and in that said peripheral serge (12) has a cylindrical inner surface, of geometric axis coinciding with the axis of rotation AA, forming one of said bearing surfaces (52). 5 8. Pendulum according to one of claims 2 to 7, characterized in that said joining surface (13) is formed of spokes arranged at regular angular interval. 9. Pendulum according to one of claims 2 to 7, characterized in that said joining surface (13) is formed of a solid disk. 10. Pendulum according to claim 7, characterized in that said elliptical ring has holes (32a, 32b) for handling said device (20) for adjusting the moment of inertia I. 1 1. pendulum according to one of claims 2 to 10, characterized in that said first and second mounting means (21, 22) are mounted rotatably positionable about the axis AA. 12. Pendulum according to one of claims 1 to 10, characterized in that said first mounting means (21) is fixedly mounted in rotation about the axis AA. 6