DEVICE FOR AUTONOMOUS ADJUSTMENT OF THE ACTIVE LENGTH OF A SPIRAL

Abstract

A device (6) for autonomous adjustment of the active length of a spiral (5), for oscillators (4, 5) of the balance-spiral type, comprising a cock (12) mounted on a plate (13) of a horological movement (2) and in which a balance shaft pivots, the spiral (5) including an inner end secured to the balance shaft and an outer end secured to a balance spring stud (8) fastened to a balance spring stud holder (10), the balance spring stud holder (10) being pivotably mounted on the cock (12) concentrically to the balance shaft, and means for modifying the active length of the spiral (5).

Claims

1. A device (6) for autonomous adjustment of the active length of a spiral (5), for oscillators (4, 5) of the balance-spiral type, comprising a cock (12) mounted on a plate (13) of a horological movement (2) and in which a shaft (7) of a balance (4) pivots, the spiral (5) including an inner end secured to the shaft (7) of a balance (4) and an outer end secured a first balance spring stud (8) fastened to a balance spring stud holder (10), the balance spring stud holder (10) being pivotably mounted on the cock (12) concentrically to the shaft (7) of the balance (4), and means for modifying the active length of the spiral (5); wherein the means for modifying the active length of the spiral comprise: at least one arm (60) capable of moving between a rest position and a correction position of the device, the at least one arm (60) having a first free end (600) and a second end (601) cooperating with a first pair of pins (19) mounted on the balance spring stud holder (10), the first pair of pins (19) being angularly offset with respect to the balance spring stud (8); elastic biasing means (62, 63) configured to exert an elastic action on the at least one arm (60) to return it in position; an inertia block (40) movable in rotation around a shaft (30) on which at least a first cam (31) is mounted, the inertia block being arranged to rotate freely around the shaft according to gravity, the rotation of the inertia block (40) causing a rotation of the at least first cam (31) and a movement of the arm (60) to act on the spiral and simultaneously modify the active length of the spiral (5); damping means comprising a gearwheel (34) coaxial with the inertia block (40) and mounted on the inertia block, and a damping device (20) arranged to cooperate with the inertia block via the gearwheel and limit the modification of the active length of the spiral (5) in the event of a sudden acceleration or deceleration.

2. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, further comprising a second arm (61) capable of moving between a rest position and a correction position of the device, the second arm having a first free end (610) and a second end (611) cooperating with a second pair of pins (19) mounted on the balance spring stud holder (10), the second pair of pins (19) being angularly offset with respect to the first pair of pins (19) and to the balance spring stud (8), and elastic biasing means (64, 65) configured to exert an elastic action on the second arm (61) to return it in position.

3. The device (6) for autonomous adjustment of the active length of a coil (5) according to claim 2, further comprising a second cam (32) arranged to cooperate with the second arm (61).

4. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the cams (31, 32) are radial cams with an external profile.

5. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the cams (31, 32) are angularly offset with respect to one another by an angle greater than 90?.

6. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein, in the rest position of the device (6), a planar portion of each cam (31, 32) is in contact with an arm (60, 61), and, in the correction position of the device (6), a wedge or angle of the cam (31, 32) is in contact with one of the arms (60, 61).

7. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the cams (31, 32) are in permanent contact with the free end (600, 610) of each arm (60, 61) regardless of the position of the inertia block (40).

8. The device (6) for autonomous adjustment of the active length of a coil (5) according to claim 1, wherein the free end (600) of the first arm (60) comprises elastically deformable adjustment means, the adjustment means being in the form of a spring leaf whose first end is secured to the arm and another end is free, the free end being arranged to be biased and adjust the length of the first arm (60).

9. The device (6) for autonomous adjustment of the active length of a coil (5) according to claim 1, wherein the free end (610) of the second arm (61) comprises elastically deformable adjustment means, the adjustment means being in the form of a spring leaf whose first end is secured to the arm and another end is free, the free end being arranged to be biased and adjust the length of the second arm (61).

10. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 9, further comprising means for adjusting the elastic load, the adjustment means being in the form of a screw, the screw passing through the free end and bearing against the arm.

11. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the first pair of pins (19) is fastened to the balance spring stud holder (10) via a first support (8), the arm (60) being arranged so that it slides between the two pins (19) and comes into contact with the outer coil of the spiral in the correction position.

12. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the second pair of pins (19) is fastened to the balance spring stud holder (10) via a second support (8), the arm (61) being arranged so that it passes between the two pins (19) and comes into contact with the outer coil of the spiral in the correction position.

13. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the inertia block (21) is a solid half-disc.

14. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, wherein the device comprises an air damper, the damper being in the form of a body with a cavity having a shape similar to that of the inertia block, the inertia block being arranged to pivot into the cavity.

15. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 1, further comprising a third heart-shaped cam (33) mounted on the shaft (30), the heart-shaped cam being arranged to cooperate with a spring (24, 25), the assembly forming a device for resetting the position of the first and second arms (60, 61).

16. The device (6) for autonomous adjustment of the active length of a spiral (5) according to claim 15, wherein the third heart-shaped cam (33) is superimposed on the cams (31, 32).

17. A horological movement (2) including an oscillator (4, 5) of the balance-spiral type and the autonomous adjustment device (6) for independent adjustment of the active length of the spiral (5) in accordance with claim 1.

18. A timepiece (1) including the horological movement (2), in accordance with claim 17.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0035] The purposes, advantages and features of the device for adjusting the active length of a spiral, as well as the horological movement and the timepiece comprising it, will appear better in the following description based on at least one non-limiting embodiment illustrated by the drawings in which:

[0036] FIG. 1 is a perspective view of a horological movement of a watch comprising a device for adjusting the active length of a spiral according to the invention;

[0037] FIG. 2 an exploded perspective view of the adjustment device of FIG. 1;

[0038] FIG. 3 is a top view of the adjustment device of FIG. 1;

[0039] FIG. 4 is a bottom view of the adjustment device of FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

[0040] In the following description, reference is made to a horological movement equipped with a device for adjusting the active length of a spiral, for oscillators of the balance-spiral type. The usual components of the horological movement, which are well known to a person skilled in the art in this technical field, are described only in a simplified form or not described at all. Indeed, a skilled person will be able to adapt these different components and have them cooperate for the operation of the horological movement. In particular, everything concerning the escapement mechanism of the horological movement will not be described later on, although such an escapement mechanism could advantageously cooperate with the adjustment device according to the invention.

[0041] FIG. 1 depicts a portion of a timepiece 1, which comprises a horological movement 2. In the particular embodiment of FIG. 1, the timepiece 1 is a watch. The horological movement 2 includes an oscillator equipped with a balance 4 and a spiral 5, and a device 6 for independent adjustment of the active length of the spiral 5. Conventionally, the spiral 5 is fastened to a shaft 7 of the balance 4 by its inner end (not visible). The shaft 7 of the balance 4 has a pivotably mounted end in a balance bridge (the latter is not visible in the figures for clarity). The outer end of the spiral 5 is conventionally fastened to a balance spring stud 8 fastened to a balance spring stud holder 10, the balance spring stud holder 10 being secured to a cock 12 by slight tightening. More specifically, the balance spring stud holder is pivotably mounted on the cock 12 concentric to the shaft 7 of the balance 4, as illustrated in FIG. 2. The shaft 7 of the balance 4 is pivotably mounted 10 in the cock 12.

[0042] The means for modifying the active length of the coil 5 are capable of modifying the active length of the coil 5 by acting on the length of the outer coil of the spiral 5.

[0043] In a particular embodiment illustrated in FIG. 2, the means for modifying the active length of the spiral 5 include at least one arm 60 capable of moving between a rest position and a correction position of the device, the at least one arm having a first free end 600 and a second end 601 cooperating with a first pair of pins 19 forming a guiding fork for the first arm 60, the first pair of pins 19 being mounted on the stud-holder 10 via a first support 8 and offset angularly relative to the stud 8. Thus, the second end 601 of the first arm 600 can slides between the first pair of pins 19.

[0044] The means for modifying the active length of the spiral also comprise an inertia block 40 movable in rotation about an axis 41 on which at least one first cam 31 is mounted against which the free end 600 of the at least one arm rests. The inertia block 40 is arranged to be able to rotate about the axis 41 according to the gravity to which it is subjected, the rotation of the inertia block 40 causing a rotation of the at least one cam 31, 32 and a movement of the at least one arm 60, 61 to act on the outer coil of the spiral and simultaneously modify the active length of the spiral.

[0045] The adjustment device 6 further comprises damping means comprising a gearwheel 34 coaxial with the inertia block 40 and secured to the inertia block, and a damping device 20 arranged to cooperate with the inertia block 40 via the gearwheel 34 and limit the modification of the active length of the spiral 5 in the event of a sudden acceleration or deceleration.

[0046] The adjustment device comprises elastic biasing means configured to exert an elastic action on the at least one arm 60 to return it in position. The elastic biasing means are in the form of a rod 62 secured to the arm 60 and a spring leaf 63 secured to the balance spring stud holder 10, the spring leaf 61 exerting a return force on the rod 62 to exert an elastic action on the arm 60 for returning it in position.

[0047] Preferably, the adjusting device comprises a second arm 61 capable of moving between a rest position and a correction position of the device, the second arm 61 having a first free end 610 and a second end cooperating with a second pair of pins 19 forming a guiding fork for the second arm, the second pair of pins 19 being mounted on the stud-holder 10 via a second support 8 and offset angularly relative to the first pair of pins 19 and the stud 8. Thus, the second end 610 of the second arm 61 can slides between the second pair of pins 19.

[0048] The meshing means also comprise a second cam 32 arranged to cooperate with the second arm whose free end 610 rests against the second cam 32.

[0049] Elastic constraint means are also associated with the second arm 61, and comprise a rod 64 secured to the second arm 61 and a spring leaf 65 secured to the balance spring stud holder 10, the spring leaf 65 exerting a return force on the rod 64 and exerting an elastic action on the second arm 61 for returning it in position.

[0050] The adjustment device 6 also comprises means for adjusting the arms 60, 61, the free end 600, 610 of the first and second arms 60, 61 comprising elastically deformable means for adjusting the length of the arms. The adjustment means are in the form of a spring leaf whose first end is secured to the arm and another end is free, the free end being arranged to be biased and adjust the length of the arms 60, 61, the spring leaf forming a space between it and the free end of each arm. Such an adjustment is necessary depending on the position of the spiral and the correction to be made on the latter.

[0051] The means for modifying the active length of the spiral 5 include two pins 19 fastened to the second balance spring stud 8, the second end 601 of the arm 60 being arranged so that it slides between the two pins 19 and comes into contact with the outer coil of the spiral 5 in the correction position and thus modify the active length of the spiral.

[0052] The means for modifying the active length of the spiral 5 further comprise two other pins 19 fastened to the third balance spring stud 8, the second end 611 of the second arm 61 being arranged so that it passes between the two pins 19 and comes into contact with the outer coil of the spiral in the correction position.

[0053] In addition, each arm 60, 61 comprises means for adjusting the elastic load, the adjustment means being in the form of a screw, the screw passing through the free end of the spring leaf and bearing against the arm. Thus, when the screw is screwed, the free end of the leaf moves away and the distance between the leaf and the free end 600.610 of the arms 60, 61 increases, which allows increasing the length of the arms 60, 61. And vice versa, when the screw is unscrewed, the free end of the leaf gets closer and the distance between the leaf and the free end 600.610 of the arms 60, 61 decreases, allowing decreasing the length of the arms 60, 61.

[0054] According to a preferred embodiment, the inertia block 40 is freely mounted in rotation on the axis 41 on which the cams 31, 32 are mounted so that a rotation of the inertia block 40 causes a movement of the arms 60, 61 and simultaneously acts on the means for modifying the active length of the spiral 5. The movement of the arms under the effect of the rotation of the inertia block 40, itself subjected to gravity, is performed between a rest position of the device, and a correction position of the device, each of the arms enabling a separate correction according to the position of the clock. As illustrated in FIGS. 1 to 4, the inertia block 40 consists, for example, of a half-solid disc. In a variant not shown in the figures, the inertia block 40 consists of a solid bi-material disc, the two disc materials having different densities.

[0055] Thus, depending on the position of the horological movement 2 in space, the inertia block 40, freely subjected to gravity, can rotate about its axis of rotation and thus cause a movement of the arms 60, 61. In doing so, this rotation of the inertia block 40 acts simultaneously on the means for modifying the active length of the spiral 5, allowing continuously adjusting the active length of the spiral in order to compensate for the disturbances of the isochronism of the balance due to gravity.

[0056] In order to avoid the inertia block forming a free wheel, and misadjusting the oscillator 4, 5 instead of correcting it, the adjusting device 6 comprises damping means comprising a gearwheel 34 coaxial with the inertia block and secured to the latter. The damping means comprise a damping device arranged to cooperate with the inertia block via the gearwheel to limit, or prevent, the modification of the active length of the spiral 5 upon a sudden acceleration or deceleration.

[0057] As illustrated in the figures, the damping device 20 is in the form of an air damper, the damper comprising a body 22 with a cavity in which a mass 21 with a shape similar to that of the cavity rotates about an axis 24. The axis 24 also comprises a pinion 23 arranged to cooperate with the toothing of the gearwheel 34. Thus, when the inertia block 40 moves, it drives the gearwheel 34 which engages the pinion 23, and makes the weight 21 of the damping device 20 rotate. It should be therefore understood that upon a sharp movement of the inertia block 40, the weight 21 will brake the rotation of the inertia block 40 thanks to the damping device 20. Of course, other types of dampers can be implemented, such as a weight moving in a cylinder, or a magnetic damper.

[0058] It should be noted that the shaft 30 bearing the inertia block 40, the gearwheel 34 and the cams 31, 32, also comprises a third heart-shaped cam 33 secured to the shaft 30, and superimposed on the cams 31, 32. The heart-shaped cam 33 is arranged to cooperate with a spring 24, 25 whose end 26 cooperates with the profile of the heart-shaped cam 33, thereby forming a device for resetting the position of the first and second arms 60, 61 to return them to their rest position naturally.

[0059] In the preferred embodiment, the device 6 comprises two cams 31, 32 for driving the arms 60, 61. The cams 31, 32 are secured to the shaft 30, angularly offset with respect to each other, and are respectively in contact with the free end 600, 610 of the arms 60, 61.

[0060] Preferably, each cam 31, 32 is a radial cam with an external profile. Although radial cams with a substantially rectangular external profile are shown in FIGS. 1 to 4, in practice the shape considered for the external profile of each cam will depend on the type of spiral 5 used and the correction to be made thereto. For example, a radial cam with a triangular, oblong or oval external profile may also be used in the context of the present invention. Preferably, and as shown in FIGS. 3 and 4, in the rest position of the adjustment device 6, a planar portion of each cam is in contact with an arm 60, 61, whereas in the correction position of the device 6, a wedge or angle of the cam 31, 32 is in contact with the arm 60, 61. Still preferably, as visible in FIGS. 1, 3 and 4, each cam 31, 32 is in contact with its respective arm regardless of the position of the inertia block 40.

[0061] It should thus be understood that, depending on the position of the horological movement 2 in space, the inertia block 40, freely subjected to gravity, can rotate about its axis of rotation and thus cause a movement of the arms 60, 61. In doing so, this rotation of the inertia block 40 acts simultaneously on the means for modifying the active length of the spiral 5, allowing continuously adjusting the active length of the spiral in order to compensate for the disturbances of the isochronism of the balance due to gravity. The rotation of the inertia block 40 causes a rotation of the shaft 30 and has the effect of moving the cams 31, 32 which are secured to the shaft, the cams then acting on the free end 600, 610 of the arms 60, 61 and moving at least one of the arms 60, 61 so that the second end of one of the arms comes into contact with the spiral 5 so as to modify the active length of the spiral 5.

[0062] Once the inertia block is stabilised following a change of its position, the device will automatically return to the rest position thanks to the action of the spring 24, 25 on the heart-shaped cam 33 which is also secured to the shaft 31.

[0063] The invention also relates to a horological movement 2 including an oscillator 4, 5 of the balance-spiral type and a device 6 for autonomous adjustment of the active length of the spiral 5 as described before.

[0064] The invention also relates to a timepiece 1 including a horological movement 2 equipped with a device 6 for autonomous adjustment of the active length of the spiral 5 as described before.