CH712225B1 - Regulating device comprising an anisochronism correction member. - Google Patents

Abstract

The invention relates to a regulating device (1) for a mechanical watch movement, comprising a balance (3), a hairspring (2), and an anisochronism correction member (4) comprising: -a finger (42) arranged by relative to the hairspring (2) so as to be in point contact with the outer face (23) of said hairspring (2) when the hairspring (2) is at rest or expanding, and to no longer be in contact with the hairspring (2) ) when the hairspring (2) is in contraction with an amplitude beyond a threshold, a fixing point (40) intended for mounting on a plate or a bridge of said movement; -said finger (42) and said fixing point (40) being fixed with respect to one another, and not coaxial.

Description

Technical area

The present invention relates to a regulator device for mechanical watch movement, comprising a member for correcting anisochronism.

State of the art

[0002] The mechanical watch movements are regulated by means of a regulating device, which generally comprises a balance-spring assembly. The frequency of oscillation of this assembly determines the precision of the watch.

An escapement is controlled by this regulating device in order to periodically block or release the gear train so as to regulate the running of the watch at the rate of the regulating device. The role of the escapement is also to give an impulse to the balance at each alternation, in order to keep it in oscillation and to compensate for friction.

The escapement disturbs the oscillations of the spiral balance assembly; for example, conventional Swiss lever escapements oppose a resisting torque to the balance during disengagement before neutral and during impulse after neutral, which is only partially compensated by the advance given during the pulse before neutral. The escapement therefore tends to increase the duration of each alternation, and to cause delay.

This delay varies according to the amplitude of oscillation. The lower the amplitude of oscillation of the balance, the greater the duration and magnitude of the delay caused by the escapement.

[0006] The oscillation amplitude itself depends on the position of the watch, the accelerations undergone, and the motor torque supplied by the barrel of the watch. Therefore, the delay induced by the escapement is variable and cannot be fully compensated, which causes isochronism error.

[0007] The use of snowshoe pins is known which allow the active length of the hairspring to be varied. To this end, the last turn of the hairspring passes at rest between the two racket pins. At each oscillation, when the hairspring expands (or contracts), it touches one of the two racket pins, which reduces its useful length in oscillation and therefore increases the average rigidity and the oscillation frequency. The pins therefore make it possible to adjust the running of the watch and possibly to make up some of the delay created by the escapement.

[0008] The use of these racket pins is well known per se. However, they have a certain number of drawbacks which the present invention aims to avoid or to mitigate.

[0009] We note first of all that the more the amplitude increases, the more the duration of support of the hairspring against the pins increases, which has the effect of creating greater delay compensation at large amplitudes than at small amplitudes. . We have seen, however, that the delay created by the escapement is significant at low amplitudes, and less at large amplitudes. Consequently, the racket pins make it possible to partly make up for the delay created by the escapement; the compensation is however insufficient at small amplitudes, and too great at large amplitudes.

[0010] On the other hand, the assembly of the racket pins is complex; these are small elements that must be mounted in a hole provided for this purpose, usually on the racquet. It is not possible to position this racket and this pin freely all around the hairspring.

[0011] EP2781970 describes such a mechanism for adjusting the active length of a spiral spring, in which the pins form a one-piece assembly with a bridge. This solution facilitates assembly, but also requires a bridge near the point of contact. The operation of the pins is conventional.

[0012] EP2908187 describes a system for regulating a clockwork resonator. In one embodiment, a cam is controlled by a regulator device to continuously modify the active length of the hairspring, by changing the position along the hairspring of the point of contact of the cam with the hairspring. The operation of the oscillator therefore depends on the position in X and in Y of the cam at each instant t; this makes the device difficult to size and adjust. Furthermore, the mounting of the cam is complex.

[0013] EP2690508 describes a hairspring comprising on certain turns stop means making it possible to modify the rigidity of the hairspring by deactivating or reactivating certain turns.

[0014] EP2690507 describes a stud holder provided with a braking element comprising an outer lip and an inner lip to modify the resulting rigidity of the hairspring during acceleration in contraction or expansion greater than a set value. The hairspring is free during normal alternations, that is to say when the amplitude does not reach the set value; beyond this value, a portion of the last turn is in contact with a rough track on the outer lip, expanding, or the inner lip in contraction. This element requires a sufficient distance between the last turn and the penultimate turn of the hairspring in order to slide the internal lip there. Furthermore, the hairspring comes into contact with one of the lips during large amplitude expansion or contraction, which has the effect of reducing above all the duration of the large amplitude vibrations but hardly compensates for the delay at small alternations. Finally, the contact of the hairspring with a relatively long and rough track of the braking element prevents any longitudinal sliding of the hairspring along the braking element, as soon as it is in contact. This results in a rapid modification of the stiffness of the hairspring from the moment of contact, and relatively sudden braking.

Brief summary of the invention

An object of the present invention is to provide a regulating device free from at least some of the limitations of the above devices.

According to the invention, these goals are achieved in particular by means of a regulator device for mechanical watch movement, comprising a balance, a hairspring, and an anisochronism correction member comprising: <tb> <SEP> -a finger (42) disposed relative to the hairspring so as to be in contact with the outer face (23) of said hairspring (2) when the hairspring is at rest or in expansion, and no longer be in contact with the hairspring when the hairspring is in contraction with an amplitude beyond a threshold, <tb> <SEP> -a fixing point intended for mounting on a plate or a bridge of said movement; <tb> <SEP> -said finger and said attachment point being fixed with respect to one another, and not coaxial.

The finger therefore reduces the useful length of the hairspring when it is in contact with the hairspring, which therefore increases the rigidity of the hairspring to compensate for the delay created by the escapement.

The point contact that the finger allows with the outer face of the hairspring allows for simplified sizing and adjustment, by exerting a constraint at a single point of the hairspring.

This point contact also allows a slight longitudinal sliding of the point of contact of the last turn along the finger. Only the radial expansion is limited.

[0020] The finger is advantageously provided with a smooth surface to allow this sliding.

Contact with the finger is punctual, and therefore does not require calculation of surface geometry or control of roughness. The accuracy obtained also depends little on manufacturing tolerances.

[0022] The finger can be made of smooth metal, silicon, etc.

[0023] The correction member is in contact with the outer face of the balance spring at rest. It thus exerts a preload on the balance spring at rest, reducing the useful length which can oscillate.

The correction member is advantageously arranged so as to be in contact with the outer face of the hairspring throughout the duration of small amplitude alternations, and so that the hairspring takes off from this point of contact during contraction of more large amplitude. The useful length of the hairspring therefore increases during large amplitude contractions, which reduces the average stiffness of the hairspring and reduces the correction at large amplitudes.

[0025] The correction member is advantageously constituted by a one-piece element provided with two faces on two levels only. It can thus be produced by machining, stamping, electroerosion, etching, etc. from a flat plate, which allows economical and precise manufacture.

The correction member can also be produced with an additive manufacturing method, for example by LIGA. Achieving only two levels reduces the number of masks and operations required.

Compared with conventional racket pins, the correction member can advantageously occupy a single plane in the movement. It thus makes it possible to act on a point of the hairspring even if the arrangement of the other components does not allow a pin to be easily fixed. For example, the correction member can be mounted in the same plane as the hairspring, between the plate and the balance.

[0028] The thickness of the correction member may be the same or less than that of the hairspring.

This planar shape of the correction member makes it possible to geographically move the finger and the point of attachment on the plate or the bridge.

In one embodiment, the point of attachment of the correction member to the plate is further from the outer end of the hairspring than the finger. This arrangement increases the range of possible positions for the mounting hole.

[0031] In one embodiment, the correction member is curved around the periphery of the hairspring. The finger is in this case advantageously located at one end of the correction member close to the outer end of said hairspring. The correction member extends around the periphery of the hairspring from this end in the direction of winding of the hairspring. This arrangement makes it possible to free up space near the end of the hairspring.

[0032] The correction member thus forms an arc of a circle around the axis of the balance. This arc extends over an angular distance between at least one fixing hole and the finger can be relatively large, for example between 90 ° and 270 °. This arrangement offers great freedom for the placement of the mounting hole anywhere on the plate or bridge.

In one embodiment, the fixing point is constituted by a fixing hole and allows rotation of the correction member relative to the plate or to the movement bridge in order to allow setting the mark, c ' ie the positioning of the plate pin on the “balance-anchor” line at the neutral point of the balance. This allows adjustment by moving the corrective member.

In one embodiment, the fixing point is constituted by an oblong hole in order to allow mounting with a fixing screw and a rotation of the correction member relative to the plate or to the movement bridge in order to set the mark. In this way, the point of contact with the anisochronism correction member is not changed with respect to the clamp for holding the end of the hairspring.

In one embodiment, the member has at least two fixing points, for example two fixing holes.

In one embodiment, said fixing point or points consist of round through holes.

The position of the correction member can be fixed, that is to say not adjustable.

The correction member may include a non-elastic deformation zone allowing adjustment of the position of said finger relative to the hairspring during adjustment.

The correction member can incorporate a clamp to fix the outer end of the hairspring to it. This makes it possible to produce a single piece which is simple to produce and which combines two functions. This also makes it possible to precisely link the position of the end of the hairspring and that of the finger.

The clamp may include several jaws to clamp the end of the hairspring. This arrangement allows mounting without glue. It is easy to make in a flat room on two levels. Nevertheless, the use of glue is possible to seal the hairspring clamp assembly, in particular for gauges requiring increased resistance to shocks.

The correction member may include three jaws for clamping the end of the hairspring in three distinct directions and / or for isostatic mounting at three points.

[0042] At least one of the jaws can be elastically deformable to clamp the end of the hairspring. The hairspring is therefore maintained by elastic deformation of one or more jaws.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> • <SEP> FIG. 1 illustrates a top view of a regulating device according to a first embodiment of the present invention (the rooster has been intentionally removed from this view for greater clarity). <tb> • <SEP> FIG. 2 illustrates a top view of the hairspring and of the correction member according to the first embodiment. <tb> • <SEP> FIG. 3 illustrates a top view of a regulator device and of an exhaust according to a second embodiment of the present invention. <tb> • <SEP> Figure 4 illustrates a perspective view of a regulating device according to the second embodiment of the present invention (the rooster being removed from view). <tb> • <SEP> FIG. 5 illustrates a top view of the hairspring and of the correction member according to the second embodiment. <tb> • <SEP> FIG. 6 illustrates a top view of the hairspring and of the correction member according to a third embodiment. <tb> • <SEP> FIG. 7 illustrates a top view of the hairspring and of the correction member according to a fourth embodiment.

Example (s) of embodiment of the invention

Figure 1 illustrates a top view of a watch movement portion including in particular the regulator device mounted on the plate 7. The regulator device comprises a balance 3 mounted on an axis 31 and a hairspring 2. The correction member 4 is visible behind the balance.

The hairspring 2 can be a hairspring of the type described in patent application CH708429, the content of which is incorporated here by reference. It can be made of silicon with one or more thermocompensation layers.

In the example illustrated, the hairspring 2 is mounted on the balance shaft side plate 7, and the balance 3 is mounted over the hairspring. The correction member 4 is then located in a plane between the plate and the plane of the balance. An arrangement of the hairspring above the balance is also possible.

FIG. 2 illustrates a top view of the hairspring 2 and of the correction member 4 according to a first embodiment of the invention. This member makes it possible to exert a pre-stress on the balance spring at rest and during its expansion. The anisochronism correction is effected by means of a point contact at point 22 between the outer face of the hairspring and a finger 42 of the correction member, so as to push this portion back towards the axis of the balance. The support of the hairspring 3 against this correction member 4 is released during a contraction of the hairspring of sufficient amplitude.

The support of the finger 42 on the hairspring reduces the useful length of the latter. The spring loaded 2 is therefore more rigid, and consequently oscillates at a higher frequency, which makes it possible to compensate at least in part for the delay caused by the escapement.

When the oscillation amplitude increases, the hairspring 2 leaves the support against the finger 42 on each contraction, which extends the useful length of the hairspring and thus reduces the oscillation frequency. The time during which the spring is released increases with the amplitude of the oscillations, which reduces the delay compensation at large amplitudes. The correction made is therefore significant at small amplitudes, when the escapement induces a significant delay, and less or zero at large amplitudes when the influence of the escapement is less sensitive.

The correction member 4 is advantageously constituted by a flat part. It therefore has two faces on two levels only. It is advantageously one-piece. It can be produced by subtractive manufacturing from a metal foil, for example by stamping, electroerosion, machining, etching, etc., or using an additive process of the LIGA type, for example.

In this variant, the correction member 4 is fixed at a single fixing point 40 on the plate 7 or on a bridge. The fixing point is constituted in this example by an oblong hole 40 in which a screw 41 is engaged for mounting on the plate. This attachment with an oblong hole allows setting the mark, by adjusting the position of the member 4 according to two degrees of freedom (for example in translation and in rotation). The screw 41 can be locked after adjustment, for example with a point of glue.

In a variant not shown, the radial distance of the finger relative to the hairspring is adjustable by elastic deformation of the correction member using an element such as a screw (or an eccentric).

The finger 42 could be adjustable or elastically deformable by an element such as a screw (or an eccentric), or plastically deformable according to two degrees of freedom, one tangential and the other radial.

The correction member 4 comprises oblong openings 48 allowing it to be guided during the adjustment, by means of pins 49 or screws mounted in the plate 7 or in a bridge. In another embodiment not shown, a guide member is engaged in a groove in the plate and guided by its sides.

The elements 46 are friction springs which make it possible to position the correction member 4 at a distance from a vertical flank in the plate, and to position it more easily during assembly while avoiding the risk of sudden involuntary rotation.

The angular distance relative to the axis of the balance between the fixing point 40 on the plate and the finger 42 is relatively large, for example between 90 and 120 °, preferably between 120 and 180 °. This distance offers great freedom of positioning for the fixing point 40 and for the screw 41 which can be placed fairly freely at a distance from the correction point 22.

The outer end of the spiral 2 is provided or shaped as a plate 21 thicker than the turns. The plate may have a trapezoidal upper face. It is fixed by clamping in one end of the isochronism corrector 4 opposite the finger 42 and shaped as a clamp 44. In the example illustrated, this clamp has three jaws 440, 441 and 442 in order to exert a clamping force on three different portions of the plate 21 and in three different directions. The clamp can be actuated by means of the lever 443, the actuation of which makes it possible to move the jaws apart to open the clamp and release or insert the plate 21. The opening and closing of the clamp 44 is effected by elastic deformation of portions of the corrective organ 4.

The hairspring is therefore not attached to the cock as is usually the case, but to the corrective member 4.

In a variant not shown, the end of the hairspring 21 could be provided with a profile, for example at least one toothing or a succession of bumps, making it possible to select the insertion position between the jaws of the holding clamp 44 among several available positions. Thus, the hairspring could be more or less engaged in the clamp, more or less reducing the active length of the hairspring and, therefore, its stiffness.

The angular distance of the member portion 4 between the finger 42 and the end of the clamp 44 is advantageously less than 90 ° relative to the axis of the balance, in order to immobilize only a limited portion of the end of the hairspring at rest and expanding.

The jaws and the lever are formed in the same one-piece part as the corrective member 4. The adjustment of the position of the corrective member 4 around the fixing point 41 for setting the mark therefore does not affect the distance between the end of the hairspring 21 and the point of contact 22.

In one embodiment, the hairspring 2 and the correction member 4 could be in one piece, and made in one piece, for example on a single flat piece.

[0063] Figures 3 to 5 illustrate another embodiment of the invention. In this example, the correction member is integrated into a regulating device comprising a balance 3, a hairspring 2, an escape wheel 5 and an anchor 6. The escape wheel 5 rotates around an axis 50 linked to an escape wheel bridge 32. The balance wheel rotates around the axis 31 linked to the balance wheel bridge 30. The balance wheel bridge and the escape wheel bridge are linked to each other and to the plate by two rods or screws 41.

The anchor 6 is in this example devoid of axis and pivots thanks to a compliant mechanism provided with flexible blades 60 which are deformed with each oscillation. The invention can also be applied to a regulating device provided with a conventional anchor.

The correction member 4 comprises in this example two holes for fixing it to the bridges 30, 32 at the two fixing points 41. As in the example of Figure 1, it comprises a finger 42 in contact with the face balance of the hairspring at rest, during the expansion of the hairspring, and as long as the amplitude of contraction does not exceed a minimum threshold.

The correction member 4 is linked at several points to the bridges 30, 32 and therefore to the plate or, in the case presented here, to the lower bridge of the tourbillon cage, by means of screws 41 engaged in through holes circulars. Its position in the plane therefore cannot be adjusted. The position of the point of contact 22 with the hairspring 2 can however be adjusted by permanently deforming, during adjustment, a deformable portion 45 of the part 4 in order to move the finger 42 relative to the fixing points 40. The part comprises a lever 450, on the side opposite to the finger 42 with respect to the deformable portion 45. An action on this lever makes it possible to move easily and with a reduced torque the position of the finger 42.

It is also possible to provide through holes 41 that are not circular, or with a diameter larger than that of the elements engaged in these holes, in order to allow adjustment of the position of the correction element even in the case of 'fixing at several points.

A correction member 4 comprising several oblong holes can be envisaged in order to allow movement relative to the plate. The mounting at several fixing points facilitates the positioning of the correction member in the plane of the hairspring.

[0069] Alternatively, a hairspring fixing clamp could also be integrated into this correction member, as for the first embodiment.

Figure 6 illustrates a variant of the regulator device similar to the variant of Figures 3 to 5, but in which a finger 42 is located at the end of a slender blade which can be plastically deformed to adjust the point of support on the hairspring.

A finger 42 at the end of a blade which can be elastically deformed, in order to compensate for manufacturing tolerances, could also be considered.

FIG. 7 illustrates a variant of a regulator device similar to the variant of FIG. 6, also devoid of a deformable portion. The finger 42 is located at the end of a relatively rigid blade, in order to precisely and consistently define the position of the point of contact.

Reference numbers used in figures

1 Regulator device 2 Spiral 20 Ferrule 21 End of the hairspring 22 Point of contact with the anisochronism correction member 23 External face of the hairspring 3 Balance wheel 30 Balance bridge 31 Axle of the balance 32 Escapement wheel bridge 4 Anisochronism correction device 40 Fixing point on plate or bridge, for example fixing hole 41 Fixing screw on plate or bridge 42 Finger 44 Clamp holding the end of the balance-spring (cock) 440 Internal jaw 441 Intermediate jaw 442 External jaw 443 Gripper lever 45 Deformation zone 450 Deformation adjustment lever 46 Friction spring 48 Guide holes 49 Guide pins 5 Escape wheel 50 Escape wheel shaft 6 Anchor 60 Flexible blades 7 Plate 8 Bridge

Claims (18)

1. Regulator device (1) for a mechanical watch movement, comprising a balance (3), a hairspring (2), and an anisochronism correction member (4) comprising: –A finger (42) arranged relative to the hairspring so as to be in contact with the outer face (23) of said hairspring (2) when the hairspring is at rest or expanding, and to no longer be in contact with the hairspring when the hairspring is in contraction with an amplitude beyond a threshold, –A fixing point (40) intended for mounting on a plate or a bridge of said movement; –Said finger (42) and said fixing point (40) being fixed with respect to each other, so as to be distant from each other 2. Device according to claim 1, said member (4) being constituted by a one-piece element provided with two faces on two levels only. 3. Device according to claim 1 or 2, said fixing point (40) being further from the outer end of the hairspring (2) than said finger (42). 4. Device according to one of claims 1 to 3, said finger (42) located at one end of the correction member (4) near the outer end of said hairspring (2), said member (4) s 'extending around the periphery of the hairspring (2) from this end in the direction of winding of the hairspring. 5. Device according to one of claims 1 to 4, said fixing point (40) allowing rotation of said member (4) relative to said plate or to said bridge of said movement in order to mark the balance (3). 6. Device according to one of claims 1 to 5, said fixing point (40) being constituted by an oblong hole in order to allow a displacement of said member (4) relative to said plate or to said bridge of said movement in order to put in mark the balance (3). 7. Device according to one of claims 1 to 6, comprising at least two said fixing points (40). 8. Device according to one of claims 1 to 5, comprising at least two said fixing points (40), said fixing points being constituted by round through holes (40). 9. Device according to one of claims 1 to 8, comprising a zone intended to be plastically deformed in order to adjust the position of said finger (42). 10. Device according to one of claims 1 to 9, comprising an element, for example a screw or an eccentric, intended to adjust the position of said finger (42). 11. Device according to one of claims 1 to 10, said corrective member (4) comprising at least one friction spring (46) to facilitate its positioning during assembly. 12. Device according to one of claims 1 to 11, comprising a clamp (44) for fixing the outer end of the hairspring (2). 13. Device according to claim 12, said clamp (44) comprising several jaws (440, 441, 442) for clamping the end of the hairspring (2). 14. Device according to claim 13, comprising three said jaws (440, 441, 442) for clamping the end of the hairspring in three distinct directions. 15. Device according to claim 13 or 14, at least one of said jaws being intended to be elastically deformed to clamp the end of the hairspring (2). 16. Device according to one of claims 12 to 15, the end of the hairspring (2) being provided with a profile, for example teeth or bumps, to allow adjustment of the depth of insertion into the clamp. 17. Device according to one of claims 1 to 16, the correction member (4) and the hairspring (2) forming a single piece. 18. Device according to one of claims 1 to 17, said member being arranged so as to be in contact with the outer face (23) of the hairspring throughout the duration of small amplitude alternations, and so that the hairspring takes off from this point of contact during contractions of greater amplitude.