CH720139A2 - Spiral spring for a watch resonator mechanism provided with stiffness adjustment means. - Google Patents

Abstract

The invention relates to a spiral spring, in particular for a watch resonator mechanism, the spiral spring (1) comprising a flexible ribbon (2) wound on itself in several turns, the ribbon (2) having a predefined stiffness , the spiral spring (1) comprising means for adjusting its stiffness, the adjustment means comprising a single elongated flexible element (5) arranged in series with the ribbon (2), the elongated flexible element (5) connecting one end (4) of said ribbon (2) to a fixed support (11), so as to add additional stiffness to the ribbon (2), the elongated flexible element (5) preferably having a stiffness greater than that of the ribbon ( 2), the adjustment means comprising prestressing means (6) for applying at least two different forces on the elongated flexible element (5), the prestressing means (6) comprising a first lever (8) joined to the end (4) of the ribbon (2) to be able to adjust a first force, the prestressing means (6) comprising a second lever (8) also attached to the end (4) of the ribbon (2) to be able to adjust a second effort independently of the first effort. The invention also relates to a watch resonator mechanism comprising such a spiral spring (1).

Description

Technical field of the invention

[0001] The invention relates to a spiral spring for a watch resonator mechanism, the spiral spring being provided with means for adjusting the stiffness of said spiral spring. The invention also relates to a watch resonator mechanism provided with such a spiral spring.

Technology background

[0002] Most current mechanical watches are equipped with a sprung balance and a Swiss anchor escapement mechanism. The sprung balance constitutes the time base of the watch. It is also called a resonator.

[0003] The exhaust, for its part, fulfills two main functions: – maintain the comings and goings of the resonator; – count these comings and goings.

[0004] To constitute a mechanical resonator, you need an inertial element, guidance and an elastic return element. Traditionally, a spiral spring plays the role of an elastic return element for the inertial element that constitutes a balance wheel. This balance wheel is guided in rotation by pivots which rotate in smooth ruby bearings.

[0005] The balance spring must generally be able to be adjusted to improve the precision of a watch. To this end, means are used for adjusting the stiffness of the spiral spring, such as a racket to modify the effective length of the spring. Thus, we modify its stiffness to adjust the running precision of the watch. However, the effectiveness of a traditional snowshoe for adjusting gait remains limited, and it is not always effective in making the adjustment sufficiently precise, of the order of a few seconds or a few tens of seconds per day.

[0006] For finer adjustment of the rate, there are adjustment means comprising one or more screws arranged in the rim of the balance wheel. By acting on the screws, we modify the inertia of the balance, which has the effect of modifying its course.

[0007] However, this adjustment mode is not easy to carry out, because it disrupts the balancing of the balance, and still does not make it possible to obtain sufficient fineness of adjustment of the operation of the oscillator.

Summary of the invention

[0008] The aim of the present invention is to overcome all or part of the drawbacks cited above, by proposing a spiral spring provided with effective and precise adjustment means, configured in particular to adjust the rate of a timepiece in modifying the effective stiffness of said hairspring.

[0009] For this purpose, the invention relates to a spiral spring, in particular for a watch resonator mechanism, the spiral spring comprising a flexible ribbon wound on itself in several turns, the ribbon having a predefined stiffness , the spiral spring comprising means for adjusting its stiffness, the adjustment means comprising a single elongated flexible element arranged in series with the ribbon, the elongated flexible element connecting one end of said ribbon to a fixed support, so as to add additional stiffness to the ribbon, the adjustment means comprising prestressing means to apply at least two different forces on the elongated flexible element.

[0010] The invention is remarkable in that the prestressing means comprise a first lever attached to the end of the ribbon to be able to adjust a first force, the prestressing means comprising a second lever also attached to the end of the ribbon to be able to adjust a second effort independently of the first effort.

[0011] Thanks to the invention, it is possible to modify the stiffness of the elongated flexible element, such as a flexible blade. In fact, when we apply two forces, we manage to vary the stiffness of the elongated flexible element. With a single effort applied, whether force or torque, the stiffness of the elongated flexible member remains the same. With two perpendicular forces on the blade, longitudinally and orthogonally, we obtain an overall force, which varies the stiffness of the elongated flexible element. With a force and a torque, we also modify the stiffness. The combination of two efforts is essential to succeed in modifying the stiffness.

[0012] By acting on the prestressing means, the intensity level of the stress is modulated, which results in a modification of the stiffness of the assembly comprising the flexible element and the ribbon. In fact, the flexible element placed in series with the ribbon provides additional stiffness, which combines with that of the ribbon. Thus, when the prestressing means apply variable forces on the flexible element, they modify the stiffness of the flexible element and therefore of the assembly comprising the ribbon and the flexible element without modifying the stiffness of the ribbon, whatever the variable forces applied to the elongated flexible element.

In other words, a flexible element is placed in series with the ribbon between one end of the ribbon and the fixed support. This flexible element provides additional adjustable stiffness between the ribbon and the ribbon attachment point, and thus provides additional flexibility to the resonator. Thus, the effective stiffness of the resonator includes the stiffness of the ribbon and the stiffness of the flexible element. Variable forces are then applied to pre-stress the flexible element, preferably without pre-stressing the ribbon. By prestressing the flexible element, its stiffness changes, while the stiffness of the ribbon remains substantially unchanged. By changing the stiffness of the flexible element, the stiffness of the resonator (ribbon stiffness and stiffness of the flexible element changes, which consequently changes the operation of the resonator.

[0014] Consequently, a modification of the rigidity of the flexible element modifies the rigidity of the entire resonator, and consequently finely regulates its operation, which makes it possible to precisely adjust the frequency of the time base. . We thus obtain great precision in the adjustment of the rate, because we act very finely on a single additional element to adjust the rigidity of the spiral spring.

[0015] Furthermore, the two levers each allow a preload adjustment to be made independently of one another, so that a more precise adjustment is obtained. In addition, if the levers are different from each other, we obtain two settings of different intensities.

[0016] According to a particular embodiment of the invention, the first force is provided either by a first traction/compression force directed substantially in the longitudinal direction of the elongated flexible element, or by a first force directed substantially in a direction substantially orthogonal to the longitudinal direction of the elongated flexible element, or by a first torque, preferably a bending moment, so as to vary the stiffness of the elongated flexible element as a function of the prestress level.

[0017] According to a particular embodiment of the invention, the second force is provided either by a second traction/compression force directed substantially in the longitudinal direction of the elongated flexible element, or by a second force directed substantially in a direction substantially orthogonal to the longitudinal direction of the elongated flexible element, or by a second torque, preferably a bending moment, so as to vary the stiffness of the elongated flexible element as a function of the prestress level.

[0018] According to a particular embodiment of the invention, the prestressing means are configured to exert a third force on the elongated flexible element, the third force being provided, respectively to the first force, either by a force directed substantially in a direction substantially orthogonal to the longitudinal direction of the elongated flexible element, or by a torque, preferably a bending moment.

[0019] According to a particular embodiment of the invention, the prestressing means are configured to exert a third force on the elongated flexible element, the third force being provided, respectively to the first force, or by the first traction force /compression, either by the first substantially orthogonal force, or by the first couple. According to a particular embodiment of the invention, the third effort is adjustable by the first lever.

[0020] According to a particular embodiment of the invention, the third effort is adjustable by the first lever.

[0021] According to a particular embodiment of the invention, the prestressing means are configured to exert a fourth force on the elongated flexible element, the fourth force being supplied, respectively to the second force, or by the second traction force /compression, either by the second substantially orthogonal force, or by the second couple.

According to a particular embodiment of the invention, the fourth effort is adjustable by the second lever.

[0023] According to a particular embodiment of the invention, the prestressing means are configured to exert a fifth force on the elongated flexible element, the fifth force being supplied, respectively to the first force and to the third force, either by the first traction/compression force, either by the first substantially orthogonal force, or by the first couple.

According to a particular embodiment of the invention, the fifth effort is adjustable by the first lever.

[0025] According to a particular embodiment of the invention, the prestressing means are configured to exert a sixth force on the elongated flexible element, the sixth force being supplied, respectively to the second and to the fourth force, or by the second traction/compression force, either by the second substantially orthogonal force, or by the second couple.

[0026] According to a particular embodiment of the invention, the sixth effort is adjustable by the second lever.

According to a particular embodiment of the invention, the longitudinal flexible element is a single flexible blade.

[0028] According to a particular embodiment of the invention, the flexible element is arranged in a radial direction of the spiral spring.

According to a particular embodiment of the invention, the first and the second lever are flexible.

According to a particular embodiment of the invention, the first and the second are curved and surround at least partly the wound ribbon.

[0031] According to a particular embodiment of the invention, the first and the second lever comprise a first free end actuable by a movement of said first free end in order to apply said forces on the elongated flexible element.

[0032] According to a particular embodiment of the invention, the second lever comprises a second free end actuable by a movement of said second free end in order to apply said forces on the elongated flexible element.

[0033] According to a particular embodiment of the invention, the end of the ribbon comprises an appendage, the prestressing means and the elongated flexible element being joined to the appendage.

[0034] According to a particular embodiment of the invention, the longitudinal force(s), and possibly the torque, are continuously adjustable by the prestressing means.

[0035] According to a particular embodiment of the invention, the flexible element is arranged at an external end of the ribbon.

According to a particular embodiment of the invention, the end of the ribbon is more rigid than the elongated flexible element and the ribbon.

According to a particular embodiment of the invention, the elongated flexible element and the levers are arranged at an external end of the ribbon.

[0038] According to a particular embodiment of the invention, the elongated flexible element comprises a flexible neck.

[0039] According to a particular embodiment of the invention, the first and the second lever are configured to allow adjustment of the force(s) to different intensities.

According to a particular embodiment of the invention, the first and the second lever have a stiffness or a section different from one another.

[0041] The invention also relates to a rotary resonator mechanism, in particular for a watch movement, comprising an oscillating mass and such a spiral spring.

Brief description of the figures:

[0042] The aims, advantages and characteristics of the present invention will appear on reading several embodiments given solely by way of non-limiting examples, with reference to the appended drawings in which: – Figure 1 schematically represents a top view of a spiral spring according to one embodiment of the invention, and - Figure 2 schematically represents an enlarged top view of the appendage and the forces applied to the appendage according to the first embodiment of the invention .

Detailed description of the invention

[0043] Figure 1 shows a schematic representation of an embodiment of a spiral spring 1, in particular for a watch resonator mechanism. Here, the spiral spring 1 extends substantially in the same plane. The spiral spring 1 comprises a flexible ribbon 2 wound on itself in several turns, the ribbon 2 having a predefined stiffness. The spiral spring 1 includes means for adjusting its stiffness. For example, the adjustment means are particularly operable when the spiral spring 1 is mounted on a plate of a clock movement, not shown in the figures.

According to the invention, the adjustment means comprise an elongated flexible element 5 extending longitudinally, which is arranged in series with the ribbon 2, the flexible element 5 connecting one end 4 of said ribbon 2 to a fixed support 11 In other words, the ribbon 2 is connected to the fixed support 11 only by this flexible element 5.

The flexible element 5 is secured to one of the ends 4 of the ribbon 2. The embodiments described below include a flexible element 5 secured to the outer end 4 of the ribbon 2. The inner end 19 of the ribbon 2 is intended to be assembled to a support 3 of an oscillating mass of the resonator 1.

The flexible element 5 adds additional stiffness to that of the ribbon 2. The flexible element 5 preferably has a stiffness greater than that of the ribbon 2. The flexible element 5 is here arranged in the extension of the ribbon 2. Preferably, the adjustment means 5 and the ribbon 2 are in one piece, or even made of the same material.

[0047] Furthermore, the end of the ribbon 2 is here curved perpendicularly to form an appendix 9. The appendix 9 serves as an attachment point, and allows forces to be received. It is preferably substantially rigid, that is to say at least more rigid than the ribbon 2 and/or the elongated flexible element 5, to minimize its influence on the stiffness of the ribbon 2.

Preferably, the longitudinal flexible element 5 is a single flexible blade 13, 15 connecting the appendix 9 to the fixed support 11, 14.

The single flexible blade 13 is arranged in the extension of the appendix 9. The single flexible blade 13 is arranged in a direction perpendicular to the end of the ribbon 2.

[0050] Thus, the single flexible blade 13 is arranged in a radial direction, preferably passing through the center of the spiral spring 1, in the rest position of the spiral spring 1.

The spiral spring 1 further comprises prestressing means 6 for applying to the flexible element 5 at least two different forces, a first force and a second force.

[0052] The first force is provided either by a first traction/compression force directed substantially in the longitudinal direction FL1 of the elongated flexible element, or by a first force directed substantially in a direction substantially orthogonal FT1 to the longitudinal direction of the elongated flexible element, or by a first couple M1, preferably a bending moment, so as to vary the stiffness of the elongated flexible element as a function of the prestress level.

[0053] The second force is provided either by a second traction/compression force directed substantially in the longitudinal direction FL2 of the elongated flexible element, or by a second force directed substantially in a direction substantially orthogonal FT2 to the longitudinal direction of the element elongated flexible element 5, or by a second couple M2, preferably a bending moment, so as to vary the stiffness of the elongated flexible element as a function of the prestress level.

[0054] In this embodiment, the first force is the first longitudinal traction-compression force FL1, and the second force is the second orthogonal force FT2, which are variable. The two forces preferably belong to the plane of the spiral spring 1. Thus, the stiffness of the spiral spring 1 can be finely adjusted, in particular to improve the precision of the movement.

The prestressing means 6 allow the flexible element 5 to undergo a compressive or tensile force depending on the value of the forces. Thus, the stiffness of the flexible element 5 is varied.

We only act on the flexible element 5 to modify its stiffness without acting directly on the ribbon 2. We thus obtain even more precision because a single element is used to adjust the rigidity. During the oscillations, the end 4 of the ribbon 2 can be mobile.

[0057] Furthermore, the forces, such as the longitudinal forces FL1, FL2 and orthogonal forces FT1, FT2, are continuously adjustable by the prestressing means 6. In other words, the forces are not restricted to discrete values. Thus, the stiffness of the flexible element 5 can be adjusted with great precision.

The prestressing means 6 comprise a first lever 8 attached to the outer end 4 of the ribbon 2. The first lever 8 is curved and surrounds a part of the wound ribbon 2. The first lever 8 has the shape of a semi-circle, or arc of a circle with an angle at the center close to 180°, attached to the appendix 9 of the end 4 of the ribbon 2.

The first lever 8 further comprises a first free end 12 actuable by a movement of said first free end 12, in order to apply said forces. The first lever 8 is preferably flexible. The first free end 12 is arranged opposite the appendage 9. The first lever 8 is preferably arranged in the plane of the spiral spring 1. The first lever 8 thus makes it possible to adjust the first force.

The prestressing means 6 comprise a second lever 15 attached to the outer end 4 of the ribbon 2. The second lever 15 is curved and surrounds a part of the rolled up ribbon 2, preferably on the other side of the ribbon 2 by relative to the first lever 8. The second lever 15 has the shape of a semi-circle, or of an arc of a circle with a central angle close to 90°, joined to the appendix 9 of the end 4 of the ribbon 2.

The second lever 15 further comprises a second free end 16 actuable by a movement of said first free end 16, in order to apply said forces. The second free end 16 is arranged opposite the appendix 9.

The second lever 16 is preferably flexible. The second lever 15 is preferably arranged in the plane of the spiral spring 1. The second lever 15 thus makes it possible to adjust the second force. Thus, the first 8 and the second lever 15 come together and are joined to the same appendix 9 of the curved part of the end 4 of the ribbon 2.

The first lever 8 allows the first force to be adjusted, while the second lever 15 allows the second force to be adjusted. Thus, the two forces are adjustable independently of each other.

The prestressing means 6 are preferably configured to exert other forces on the elongated flexible element 5 by means of the first 8 and the second lever 15. Each lever 8, 15 preferably exerts several forces, independently the one from the other, here three efforts simultaneously.

The prestressing means 6 are configured to exert a third force on the elongated flexible element. The third effort being provided, respectively to the first effort, either by the first traction/compression force FL1, or by the first substantially orthogonal force FT1, or by the first couple M1. In this embodiment, the third force is the first substantially orthogonal force FT1. The third effort is adjustable using the first lever 8.

[0066] Thus, the first lever 8 makes it possible to simultaneously adjust the first and third forces.

The prestressing means 6 are further configured to exert a fourth force on the elongated flexible element 5, the fourth force being supplied, respectively to the second force, either by the second traction/compression force FL1, or by the second substantially orthogonal force FT2, or by the second couple M2. In this embodiment, the fourth force is the second substantially longitudinal force FL2. The fourth effort is adjustable using the second lever 15.

[0068] The prestressing means 6 are further configured to exert a fifth force on the elongated flexible element 5, the fifth force being supplied, respectively to the first force and to the third force, i.e. by the first traction/compression force FL1, either by the first substantially orthogonal force FT1, or by the first couple M1.

[0069] In this embodiment, the fifth effort is the first couple M1. The fifth effort is adjustable using the first lever 8. The fifth effort is adjustable using the first lever 8.

The prestressing means 6 are also configured to exert a sixth force on the elongated flexible element 5, the sixth force being supplied, respectively to the second and to the fourth force, either by the second traction/compression force FL2, or by the second substantially orthogonal force FT2, or by the second couple M2. In this embodiment, the sixth effort is the second couple M2. The sixth effort is adjustable by the second lever 15.

[0071] In this embodiment, the forces produced by each lever 8, 15 are opposite, except for the longitudinal forces FL1, FL2 which have an identical direction. However, the first 8 and the second lever 15 have a similar effect on the stiffness of the elongated flexible element 5. The more one raises a lever 8, 15, the more the stiffness of the elongated flexible element 5 increases.

[0072] Each lever makes it possible to individually modify the stiffness of the elongated flexible element 5, because it provides at least two forces.

[0073] Preferably, the first 8 and the second lever 18 are configured to allow adjustment of the forces it applies at different intensities. Thus, one lever allows adjustment within a wider adjustment range, and the other lever allows adjustment within a finer adjustment range.

[0074] To obtain a difference in intensity of adjustment of the stiffness of the elongated flexible element 5 between the two levers 8, 15, the section of the two levers 8, 15 is for example chosen different, or else the stiffness of each lever 8, 15 is chosen different.

[0075] Thus, the forces or torques applied are less with a smaller section or stiffness than with a larger section or stiffness, so that the two levers 8, 15 make it possible to modify the stiffness of the flexible element. lying 5 on two different scales.

[0076] Such levers 8, 15 make it possible to keep a spiral spring 1 with reduced bulk, the dimensions being restricted to be able to be inserted into a watch movement.

[0077] Indeed, the prestressing means 6 have a shape which matches the ribbon 2, so as to keep the dimensions sufficiently small, because each part of the prestressing means 6 is close to the ribbon 2. The width of the spring -spiral 1 is therefore little modified by the prestressing means. Thus, the spiral spring 1 is sufficiently compact to be able to be easily inserted into a movement.

[0078] As shown in Figure 2, the actuation of the first lever 8 produces on the end 4 of the ribbon 2 the longitudinal force FL1 directed along the longitudinal axis of the longitudinal flexible element 5, as well as an orthogonal force FT1 directed in an orthogonal direction. The actuation of the first lever 8 also produces a torque or a bending moment M1 on the single blade 5, represented by a curved arrow.

[0079] Actuation of the second lever 15 produces the longitudinal force FL2 directed in the same direction as the longitudinal force FL1, the orthogonal force PT2 directed in the opposite direction of the orthogonal force FT, and a torque M2 in the opposite direction of the torque M1.

[0080] Thus, the stiffness of the single blade 13 is modified, and therefore of the assembly comprising the ribbon 2 and the single flexible blade 13.

[0081] The longitudinal forces FL1, FL2 and orthogonal forces FT1, FT2 as well as the torques M1, M2 are varied by the movement of the first free end 12 of the first lever 8 and by the movement of the second free end 16 of the second lever 15. first 12 and the second free end 16 are preferably rigid to facilitate their actuation. Thus, the stiffness of the flexible element 5 and therefore of the assembly comprising the flexible element 5 and the ribbon 2 is varied.

[0082] The invention also relates to a watch movement comprising such a spiral spring 1. The spiral spring is used in particular to actuate the movement of a balance wheel.

[0083] Naturally, the invention is not limited to the embodiments described with reference to the figures and variants could be considered without departing from the scope of the invention.

[0084] Concerning the longitudinal element, the flexible blades described in the different embodiments of the spiral spring can be continuous flexible blades, as is generally the case in the figures, or else blades with rigid sections and flexible necks connecting the sections.

[0085] Furthermore, the single flexible blade can take orientations other than radial and orthogonal relative to the spiral spring. Thus, it can be oriented in any direction between the radial and orthogonal directions.

Claims (20)

1. Spiral spring, in particular for a watch resonator mechanism, the spiral spring (1) comprising a flexible ribbon (2) wound on itself in several turns, the ribbon (2) having a predefined stiffness, the spring- hairspring (1) comprising means for adjusting its stiffness, the adjustment means comprising a single elongated flexible element (5) arranged in series with the ribbon (2), the elongated flexible element (5) connecting one end (4 , 19) of said ribbon (2) to a fixed support (11), so as to add additional stiffness to the ribbon (2), the elongated flexible element (5) preferably having a stiffness greater than that of the ribbon (2) , the adjustment means comprising prestressing means (6) for applying at least two different forces on the elongated flexible element (5), characterized in that the prestressing means (6) comprise a first lever (8) joined at the end (4, 19) of the ribbon (2) to be able to adjust a first force, the prestressing means (6) comprising a second lever (8) also attached to the end (4, 19) of the ribbon (2 ) to be able to adjust a second effort independently of the first effort. 2. Spiral spring according to claim 1, characterized in that the first force is provided, either by a first traction/compression force directed substantially in the longitudinal direction FL1 of the elongated flexible element (5), or by a first force directed substantially in a direction substantially orthogonal FT1 to the longitudinal direction of the elongated flexible element (5), or by a first couple M1, preferably a bending moment, so as to vary the stiffness of the elongated flexible element (5 ) depending on the prestressing level. 3. Spiral spring according to claim 1 or 2, characterized in that the second force is provided either by a second traction/compression force directed substantially in the longitudinal direction FL2 of the elongated flexible element (5), or by a second force directed substantially in a direction substantially orthogonal FT2 to the longitudinal direction of the elongated flexible element (5), or by a second couple M2, preferably a bending moment, so as to vary the stiffness of the elongated flexible element ( 5) depending on the prestressing level. 4. Spiral spring according to any one of the preceding claims, characterized in that the prestressing means (6) are configured to exert a third force on the elongated flexible element (5), the third force being provided, respectively at the first effort, either by the first traction/compression force FL1, or by the first substantially orthogonal force FT1, or by the first couple M1. 5. Spiral spring according to claim 4, characterized in that the third force is adjustable by the first lever (8). 6. Spiral spring according to any one of the preceding claims, characterized in that the prestressing means (6) are configured to exert a fourth force on the elongated flexible element (5), the fourth force being provided, respectively at the second effort, either by the second traction/compression force FL2, or by the second substantially orthogonal force FT2, or by the second couple M2. 7. Spiral spring according to claim 6, characterized in that the fourth force is adjustable by the second lever (15). 8. Spiral spring according to any one of the preceding claims, characterized in that the prestressing means (6) are configured to exert a fifth force on the elongated flexible element (5), the fifth force being provided, respectively at the first effort and the third effort, either by the first traction/compression force FL1, or by the first substantially orthogonal force FT1, or by the first couple M1. 9. Spiral spring according to claim 8, characterized in that the fifth force is adjustable by the first lever (8). 10. Spiral spring according to any one of the preceding claims, characterized in that the prestressing means (6) are configured to exert a sixth force on the elongated flexible element (5), the sixth force being provided, respectively at the second and fourth effort, either by the second traction/compression force FL2, or by the second substantially orthogonal force FT2, or by the second couple M2. 11. Spiral spring according to claim 10, characterized in that the sixth force is adjustable by the second lever (15). 12. Spiral spring according to any one of the preceding claims, characterized in that the elongated flexible element (5) is a single flexible blade (13). 13. Spiral spring according to any one of the preceding claims, characterized in that the flexible element (5) is arranged in a radial direction of the spiral spring (1). 14. Spiral spring according to any one of the preceding claims, characterized in that the first (8) and the second lever (15) are flexible. 15. Spiral spring according to any one of the preceding claims, characterized in that the first lever (8) comprises a first free end (12) actuable by a movement of said first free end (12) in order to apply said forces on the elongated flexible element (5), and the second lever (15) comprises a second free end (16) actuable by a movement of said second free end (16) in order to apply said forces on the flexible element elongated (5). 16. Spiral spring according to any one of the preceding claims, characterized in that the first (8) and the second lever (15) are configured to allow adjustment of the force(s) to different intensities. 17. Spiral spring according to claim 16, characterized in that the first (8) and the second lever (15) have a section or a stiffness different from each other. 18. Spiral spring according to any one of the preceding claims, characterized in that the force(s) are continuously adjustable by the prestressing means (6). 19. Spiral spring according to any one of the preceding claims, characterized in that the flexible element (5) and the levers (8, 15) are arranged at an external end (4) of the ribbon (2). 20. Rotary resonator mechanism, in particular for a watch movement, comprising an oscillating mass, characterized in that it comprises a spiral spring (1) according to any one of the preceding claims.