EP4372480A1 - Timepiece assembly comprising a hairspring and a pin - Google Patents

Abstract

The invention relates to an assembly (1) for fixing a free end (8) of a last turn to the exterior (10) of a spiral spring (12) for a watch movement, this assembly of fixing (1) comprising a eyebolt (2) and a blocking element (14), the eyebolt (2) being provided with a groove (6) in which the free end (8) of the last turn outside (10) of the spiral spring (12) is engaged, the locking element (14) also being engaged in the groove (6), in contact with the last turn outside (10) of the spiral spring (12), the fixing assembly (1) also comprising a clamping member (16) which presses the blocking element (14) against the free end (8) of the last turn outside (10) of the spiral spring ( 12), so that the free end (8) of the last turn outside (10) of the spiral spring (12) is immobilized in the groove (6) of the eyebolt (2).

Description

Technical field of the invention

The present invention relates to a hairspring for a balance wheel of a watch movement. The present invention also relates to a eyebolt for fixing a final turn to the outside of such a hairspring. The invention also relates to a method of manufacturing such a hairspring.

Technology background

In the field of watchmaking, a hairspring, associated with a balance, forms a regulating organ commonly called a balance-spring for mechanical timepieces. At first glance, the hairspring appears in the form of a very fine spring which winds on itself in concentric turns when no constraint is exerted on it. In the assembled state, a first end of the hairspring, called the first turn on the inside, is fixed to a ferrule adjusted to an axis of the balance wheel, and a second end of the hairspring, called the last turn on the outside, is fixed to a eyebolt which is a part generally fixed by means of a eyebolt holder in a balance bridge also called cock.

More precisely, the time base for mechanical timepieces, also called an oscillating system, includes a balance-spring pair and an escapement. The balance wheel consists of a balance shaft pivoted between a first and a second bearing and connected to a balance wheel rim by means of radial arms. The hairspring is fixed via its first turn on the inside to the axis of the balance, for example by means of a ferrule, and it is fixed via its last turn on the outside to a fixed attachment point such as a piton carried by a piton carrier.

As for the exhaust, in a very widespread embodiment, it includes a double plate system consisting of a large tray which carries a tray pin and a small tray in which a notch is made. The escapement also includes an anchor, an anchor rod of which is pivoted between a first and a second bearing. The anchor consists of a rod that connects a fork to an input arm and an output arm. The fork consists of an entry horn and an exit horn and carries a stinger. The fork travel is limited by an entry limit pin and an exit limit pin which can be made in one piece with an anchor bridge. The input arm and the output arm respectively carry an input pallet and an output pallet. Finally, the anchor cooperates with an escape wheel comprising an escape wheel and an escape pinion, this assembly formed by the wheel and the escape pinion being pivoted between a first and a second bearing.

A hairspring is a spring which, as its name suggests, takes the shape of a spiral when it is at rest. Winded in a horizontal plane, parallel to the plane of the watch movement, the hairspring serves only one function: to make the balance oscillate around its equilibrium position, also called dead center, at the most constant frequency possible. When the balance leaves its equilibrium position by pivoting in a given direction, the hairspring contracts. This creates a restoring torque in the balance spring which has the effect of returning the balance to its equilibrium position. During this beat, the hairspring relaxes. However, as the balance has acquired a certain speed, and therefore kinetic energy, it exceeds its equilibrium position in the opposite direction to the previous one until the return torque exerted by the balance spring on the balance stops the latter again. and forces it to turn in the other direction.

The hairspring therefore relaxes and contracts alternately: we say that it breathes. However, many factors contribute to preventing a spiral from developing isochronously during the expansion and contraction phases. The hairspring must in particular resist oxidation and magnetism which stick the turns together and tend to disrupt the precision of the watch, or even stop it completely. The influence of atmospheric pressure, on the other hand, is weak. For a long time, it was temperature that was the heart of the problem, because heat expands the metal, while cold shrinks it. The hairspring must also be elastic to deform and yet always regain its shape.

The material used to make the hairsprings is usually steel. Ductile, the steel used must resist corrosion. For two decades now, developments have also proposed making hairsprings from silicon. Silicon hairsprings, particularly because they are insensitive to magnetism, make it possible to achieve greater running precision than their steel predecessors. On the other hand, their cost price is higher and, being fragile, they are more difficult to assemble.

A hairspring must be isochronous. No matter how far the pendulum turns, it must always take the same amount of time to swing. If the hairspring contracts only a few degrees, it accumulates little energy and slowly returns to its equilibrium position. If the hairspring is moved far from its equilibrium position, it moves very quickly in the opposite direction. The important thing is that these two trips take place within the same duration. The underlying idea is that the energy available to the hairspring is not constant and that it must still function whether the watch is fully wound or is in its last hours of power reserve.

Due to their small dimensions, hairsprings are difficult to assemble. However, the way in which the two ends of a hairspring are fixed also greatly influences the precision of the running of the watch movement. In most mechanical watch movements, the two ends of the hairspring are inserted into a pierced part and are immobilized by means of a pin force-fitted manually using with pliers. A slight rotation of the hairspring can then occur, which is detrimental to the precision of the movement.

Another technique consists of fixing the ends of the spirals using glue. However, this technique also showed its limits. It has in fact been observed that due to its viscosity, the glue exerts a traction force on the hairspring by capillary action and can press the ends of the hairspring against the walls of the piton in which these ends are engaged. The resulting deformation of the hairspring induces mechanical stresses in it which are detrimental to the regularity of its operation.

To remedy these problems, the Applicant has already proposed a method of fixing a spiral spring consisting of gluing the last turn to the outside of a spiral spring in a pin by means of a drop of polymerizable fluid glue for example by means of ultraviolet radiation. Thus, even if, at the time of depositing the drop of glue, for example by means of a syringe type glue dispenser, the free end of the last turn of the hairspring moves a little under the effect of the weight of the drop of glue, which induces unwanted mechanical stresses in the spiral spring, the glue is, before hardening, sufficiently fluid to allow the free end of the last turn of the spiral to spontaneously return to its rest position. The mechanical stresses induced in the spiral spring at the time of deposition of the drop of liquid glue therefore disappear by themselves, so that the regularity of the operation of the spiral spring is not affected by the gluing operation of the latter.

The above solution thus makes it possible to fix a spiral spring by the free end of its last turn outside in a eyebolt, completely eliminating, or at least for the most part, the mechanical stresses which are usually induced in such a spring. spiral during assembly. The regularity of operation of the spiral spring is thus greatly improved. In use, the Applicant has nevertheless realized that the block of hardened glue formed when the drop of liquid glue is polymerized which is used to fix the free end of the last turn to the outside of the spiral spring sometimes had a tendency to separate from the pin, which, of course, leads to the immediate breakdown of the watch movement in which this is installed. spiral spring. Such a situation is notably due to problems with the surface condition of the peg which prevent the glue pad from adhering perfectly to the peg as well as to the aging of the glue pad over time. In addition, when the ambient temperature increases, most glues soften, which has the effect of modifying the active length, and therefore the stiffness of the hairspring, and therefore negatively influencing the operation of the watch movement.

Finally, it should be noted that, particularly in the case of high-end watch movements, the use of glues or synthetic products is avoided as much as possible.

Summary of the invention

The present invention aims to remedy the problems mentioned above as well as others by providing an assembly for fixing a spiral spring of which a last turn on the outside can be immobilized reliably without recourse to glue or pins or even manual operations such as pinching, crimping or others whose success depends largely on the skill of the operators.

For this purpose, the present invention relates to an assembly for fixing a free end of a last turn to the outside of a spiral spring for a clock movement, this fixing assembly comprising a pin and a fixing element. blocking, the eyebolt being provided with a groove in which the spiral spring is engaged at one point along its length, the blocking element also being engaged in the groove, in contact with the spiral spring, the fixing assembly also comprising a clamping member which presses the blocking element against the free end of the last turn outside the spiral spring, so that the free end of the last turn outside the spiral spring is immobilized in the groove of the eyebolt.

According to a particular mode of execution of the invention, the spiral spring is engaged in the groove of the eyebolt by the free end of its last turn on the outside.

According to another particular mode of execution of the invention, the immobilization of the free end of the last turn outside the spiral spring is ensured by mechanical tightening and blocking in a direction perpendicular to the plane in which extends this free end of the spiral spring.

According to yet another particular embodiment of the invention, the groove extends from an exterior wall of the piton and towards the interior of the latter.

According to yet another particular embodiment of the invention, the groove has a height and the blocking element a thickness such that, once the blocking element is engaged in this groove, there remains sufficient space to be able to engage the free end of the last turn outside the spiral spring in the groove.

According to yet another particular embodiment of the invention, the space in which the free end of the last turn is engaged outside the spiral spring extends between the blocking element and a bottom of the groove.

According to yet another particular mode of execution of the invention, the free end of the last turn outside the spiral spring ends in a plate which is fixed on this free end or which is made in one piece with this free end.

According to yet another particular mode of execution of the invention, a hole in which the clamping member is engaged is provided in the eyebolt so that the clamping member opens into the groove and presses against the blocking element and presses the latter against the free end of the last turn outside the spiral spring.

According to yet another particular embodiment of the invention, the clamping member is a threaded rod and in that the hole is tapped.

According to yet another particular embodiment of the invention, the blocking element is a clamp provided with two jaws connected to each other at a distal end, these two jaws delimiting between them an open space on the side of their end proximal.

According to yet another particular embodiment of the invention, the piton comprises a wall which delimits the groove.

According to yet another particular embodiment of the invention, the interior face of one of the jaws of the pliers has a surface which moves away from the wall of the eyebolt in the direction of engagement of the pliers on the peak.

According to yet another particular embodiment of the invention, the interior face of the jaws of the pliers is provided with a recess whose shapes are complementary and match those of the wall, allowing the pliers to grip the wall and to ensure sufficient support for the time for the operator to engage the last turn outside the spiral spring in the groove made in the eyebolt.

According to yet another particular embodiment of the invention, the spiral spring fixing assembly is removable.

Thanks to these characteristics, the present invention provides an assembly for fixing the free end of the curve to the outside of a spiral spring for a clock movement with numerous advantages among which we can in particular cite the fact that the spiral springs can be attached without glue regardless of the type of material used to make such spiral springs. From this, it follows that the watch manufacturer enjoys complete freedom in the choice of the material in which the watch is made. spiral spring and that in addition, given that the free end of the spiral spring is not glued, the fixing assembly according to the invention is removable. In addition, as the immobilization of the free end of the last turn outside the spiral spring is ensured by the blocking element which is pressed against the free end of the last turn outside the spiral spring by the tightening member, no mechanical torque is transmitted to the spiral spring, so that the latter can be fixed in its rest position in the XY plane parallel to the plane in which the watch movement extends without any or almost no influence on its walking regularity qualities. We know in fact that the stress which is exerted on the free end of the last turn outside the spiral spring perpendicular to the plane in which this free end extends is almost non-existent. Yet another great advantage of the fixing assembly according to the invention lies in the fact that the mounting of the free end of the last turn outside the spiral spring does not depend in any way on the dexterity of the operator responsible for this assembly, so that the reproducibility of the operation of the balance-spring assemblies equipped with a fixing assembly according to the invention is quite remarkable.

Brief description of the figures

• la figure 1 est une vue de dessus en perspective de l'ensemble selon l'invention dans lequel est fixée une extrémité libre d'une dernière spire à l'extérieur d'un ressort spiral pour un mouvement d'horlogerie ;
• la figure 2 est une vue de dessous en perspective de l'ensemble de fixation selon l'invention illustré à la figure 1 ;
• la figure 3 est une vue de dessus en perspective à l'état dissocié de l'ensemble de fixation selon l'invention ;
• la figure 4 est une vue de dessous en perspective à l'état dissocié de l'ensemble de fixation selon l'invention ;
• la figure 5 est une vue de dessus de l'ensemble de fixation selon l'invention dans lequel est engagée l'extrémité libre de la dernière spire à l'extérieur d'un ressort spiral pour mouvement d'horlogerie ;
• la figure 6 est une vue en coupe de l'ensemble de fixation selon l'invention selon la ligne VI-VI de la figure 5 ;
• la figure 7 est une vue en coupe de l'ensemble de fixation selon l'invention selon la ligne VII-VII de la figure 5 ;
• la figure 8 est une vue de dessus de l'ensemble de fixation selon l'invention monté dans un ensemble balancier-spiral pour un mouvement d'horlogerie ;
• la figure 9 est une vue schématique d'un mode de réalisation simplifié de l'ensemble de fixation selon l'invention ;
• les figures 10 et 11 sont des vues en perspective respectivement de dessus et de dessous de l'ensemble balancier-spiral équipé de l'ensemble de fixation selon l'invention représenté en vue de dessus à la figure 8.

Other characteristics and advantages of the present invention will emerge more clearly from the detailed description which follows of an embodiment of a fixing assembly according to the invention, this example being given for purely illustrative and non-limiting purposes only in connection with the attached drawing in which:

• there figure 1 is a top perspective view of the assembly according to the invention in which a free end of a last turn is fixed to the outside of a spiral spring for a clock movement;
• there figure 2 is a bottom perspective view of the fixing assembly according to the invention illustrated in figure 1 ;
• there Figure 3 is a top perspective view in the dissociated state of the fixing assembly according to the invention;
• there Figure 4 is a bottom perspective view in the dissociated state of the fixing assembly according to the invention;
• there Figure 5 is a top view of the fixing assembly according to the invention in which the free end of the last turn outside of a spiral spring for a watch movement is engaged;
• there Figure 6 is a sectional view of the fixing assembly according to the invention along line VI-VI of the Figure 5 ;
• there Figure 7 is a sectional view of the fixing assembly according to the invention along line VII-VII of the Figure 5 ;
• there figure 8 is a top view of the fixing assembly according to the invention mounted in a balance-spring assembly for a clock movement;
• there Figure 9 is a schematic view of a simplified embodiment of the fixing assembly according to the invention;
• THE figures 10 and 11 are perspective views respectively from above and below of the balance-spring assembly equipped with the fixing assembly according to the invention shown in top view at the figure 8 .

Detailed description of the invention

The present invention proceeds from the general inventive idea which consists of fixing the free end of the last turn to the outside of a watch spiral spring in a pin by means of a fixing assembly ensuring the immobilization of this end free by a combined pressing action and mechanical blocking. In this way, fixing the free end of the spiral spring does not require any gluing operation, so that one enjoys complete freedom in the choice of materials used to make the spiral spring. Furthermore, given the absence of any gluing, the fixing assembly according to the invention remains constantly removable. Another great advantage of the fixing assembly according to the invention: the immobilization of the free end of the last turn outside the spiral spring is ensured by mechanical tightening and blocking in a direction perpendicular to the plane in which it is extends this free end of the spiral spring. Consequently, the fixing of this free end of the spiral spring does not induce any mechanical traction or torsion torque in the free end of the last turn outside the spiral spring, so that the regularity of operation of the spiral spring is in no way affected by the fixing of the free end of its last turn outside in the eyebolt. This is all the more true since the mechanical stresses exerted on the last turn outside the spiral spring in the direction perpendicular to the plane in which this last turn extends are zero or completely negligible.

Designated as a whole by the general numerical reference 1, the fixing assembly according to the invention is represented as a whole on the figures 1 and 2 and includes in particular a peg 2. For purely illustrative purposes only, the peg 2 illustrated in the drawing is delimited externally by an envelope of generally cylindrical shape. We understand in fact that the shape of the peg 2 is not decisive for the purposes of the invention, such a peg 2 being able to deviate from a cylindrical shape and be, for example, parallelepiped in shape.

Preferably but not limitingly, a groove 6 is made from an exterior wall 4 of the eyebolt 2 and towards the interior of the latter, preferably of square or rectangular straight section, as is particularly visible on the figures 3 and 4 . This groove 6 is intended to receive a free end 8 of a last turn outside 10 of a spring hairspring 12 for a watch movement for blocking the latter as described in detail below.

The fixing assembly 1 according to the invention also comprises a blocking element 14 also intended to be engaged in the groove 6, in contact with the free end 8 of the last turn outside 10 of the spiral spring 12, then to be pressed against this free end 8 to ensure the immobilization of the spiral spring 12 in this groove 6.

For this purpose, the fixing assembly 1 is further completed by a clamping member 16 which is arranged to press the blocking element 14 in an adjustable manner against the free end 8 of the last turn outside 10 of the spiral spring 12.

According to the mode of execution of the invention illustrated in the drawing (see for example the Figure 3 ), the clamping member 16 can be of the type of a threaded rod 18 provided with a slotted head 20. This threaded rod 18 is intended to be screwed into a threaded hole 22 made in the eyebolt 2 so that this rod threaded 18 opens into the groove 6 and presses against the blocking element 14 and presses the latter against the free end 8 of the last turn outside 10 of the spiral spring 12.

It is easy to understand that, depending on the degree of screwing of the threaded rod 18, it is possible to precisely adjust the tightening force which, via the blocking element 14, is exerted on the free end 8 of the last turn at the exterior 10 of the spiral spring 12 and ensures the immobilization of this free end 8 in the groove 6 of the pin 2.

A friction surface 24, for example a knurling 26, can be provided on the eyebolt 2. This friction surface 24 can in particular be used by the operator for better gripping of this eyebolt 2 when screwing the threaded rod 18 in the tapped hole 22 of the eyebolt 2.

As described above, the clamping member 16 is a threaded rod 18. Of course, this is only an example, the clamping member 16 which can take other forms such as, for example, a simple pin engaged with friction sufficiently thick in the hole made in the eyebolt 2 to be able to press against the blocking element 14 and firmly press the latter against the free end 8 of the last turn to the outside 10 of the spiral spring 12, while being able to be released from this hole if necessary, for example if the spiral spring 12 breaks.

In its preferred but non-limiting embodiment, the blocking element 14 is of the type of a clamp 28 provided with a certain elasticity and provided with two generally rectilinear jaws 30a and 30b which extend substantially parallel to, and at a distance from each other. Connected to each other at their distal end 32a, 32b, these two jaws 30a, 30b define between them a space 34 open on the side of their proximal end 36a, 36b.

Through its space 34 open on the side of the proximal end 36a, 36b of its jaws 30a, 30b, the clamp 28 is engaged on either side of a wall 38 of the piton 2 which results from the machining of the groove 6. The simple overlap of the clamp 28 on the wall 38 of the eyebolt 2 is sufficient to ensure sufficient retention of this clamp 28 for the time necessary for the operator to tighten the threaded rod 18. This retention can, however, be slightly increased by providing the inner face of one of the jaws 30a, 30b of the clamp 28 of a surface 40 which moves away from the wall 38 of the stud 2 in the direction of engagement of the clamp 28. Maintaining the clamp 28 on the wall 38 of the eyebolt 2 can be further improved by providing on the internal face of its jaws 30a, 30b recesses 42a, 42b whose shapes are complementary and match those of this wall 38, in this way allowing the clamp 28 to enclose the wall 38 of the piton 2 and to ensure its maintenance by friction.

It is important to understand that the height of the groove 6 is greater than the thickness of the jaws 30a, 30b of the clamp 28, so that, once the clamp 28 is engaged in this groove 6, there remains a space sufficient to be able to easily engage the free end 8 of the last turn outside 10 of the spiral spring 12 in the groove 6.

The operation of fixing the free end 8 of the last turn to the exterior 10 of the spiral spring 12 is carried out as follows: we begin first by engaging the clamp 28 through its space 34 open on the side of the proximal end 36a, 36b of its jaws 30a, 30b in the groove 6 of the eyebolt 2, on either side of the wall 38 of this eyebolt 2. The overlap of the clamp 28 on the wall 38 of the eyebolt 2 is sufficient to ensure that the clamp 28 is maintained on this wall 38 for the time necessary to fix the free end 8 of the last turn to the exterior 10 of the spiral spring 12 on the pin 2. When mounting the clamp 28, we ensure that this clamp 28 is positioned so that there remains sufficient space 44 between the jaws 30a, 30b of this clamp 28 and a bottom 46 of the groove 6 to be able to easily engage the free end 8 of the last turn to the outside 10 of the spiral spring 12. Once the clamp 28 is properly positioned and fixed in the groove 6 of the eyebolt 2, the free end 8 of the last turn is easily engaged on the outside 10 of the spiral spring 12 in the groove 6, between the bottom 46 of the latter and the jaws 30a, 30b of the clamp 28. Frequently, the free end 8 of the last turn outside 10 of the spiral spring 12 ends with a plate 50. Depending on the case, this plate 50 is fixed on the free end 8 of the last turn outside 10 of the spiral spring 12 for example by welding or is made in one piece with this free end 8. We adjusts the mark by pivoting the fixing assembly 1, in other words by pivoting the point of attachment of the last turn outside 10 of the spiral spring 12 around an axis 52 of a balance 48, to align a pin 54 of a plate 56 with an exhaust line 58 (see figure 8 ). For this purpose (see figures 10 and 11 ), the eyebolt 2 is engaged in an opening 60 provided in a eyebolt supporting part 62 which is carried by a bridge 64 commonly called cock and which is pivotally mounted around the axis 52 of the balance 48. Likewise, rather than d be provided in the piton 2 from the outside of the latter, we can very well consider sparing the groove 6 in the manner of a through hole 66 in the thickness of the eyebolt 2 (see Figure 9 ). A blocking element 14 is engaged in this through hole 66, for example of the type of a rod 68. Finally, the operator tightens the threaded rod 18 so that the latter comes to press against the jaws 30a, 30b of the pliers 28 and press the latter against the free end 8 of the last turn outside 10 of the spiral spring 12. The operations of mounting the free end 8 of the last turn outside 10 of the spiral spring 12 are thus completed and the spiral spring 12 is fixed on the pin 2 in a removable manner.

It goes without saying that the present invention is not limited to the embodiment which has just been described, and that various modifications and simple variants can be envisaged by those skilled in the art without departing from the scope of the invention such as defined by the appended claims. In particular, it will be understood that the groove 6 may have a cross section other than square or rectangular. It will also be noted that the friction surface 24 such as the knurling 26 provided on the eyebolt 2 is especially very useful after driving the eyebolt 2 into the eyebolt supporting part 62. In fact, the threaded rod 18 can be screwed quite easily until to the locking position. Only the friction induced by the threads of the threaded rod 18 in the tapping of the eyebolt 2 is likely to cause the eyebolt 2 to rotate during this operation. At this stage of the operation, this friction is however negligible compared to the torque necessary to rotate the eyebolt 2. On the other hand, when the threaded rod 18 arrives in the locking position in the tapped hole 22, a large part of the torque of tightening transmitted to the threaded rod 18 by the operator is communicated to the eyebolt 2, which can cause the eyebolt 2 to pivot relative to the eyebolt supporting part 62. Of course, such pivoting must be avoided, which is why we thought of providing the eyebolt 2 for example with a knurling 26 which, by contact with the eyebolt supporting part 62, has the effect of increasing the resistance of the eyebolt 2 to this torque. It will also be understood that, depending on the geometric shape of the spiral spring 12 which may be particular, this spiral spring 12 can be engaged in the groove 6 of the pin 2 in one place of its length other than the free end 8 of its last turn outside 10. It will also be understood that the immobilization of the free end 8 of the last turn outside 10 of the spiral spring 12 is ensured by tightening and mechanical blocking in a direction perpendicular to the plane in which this free end 8 of the spiral spring 12 extends. In the case where the spiral spring 12 ends in a plate 50, if this plate 50 extends parallel to the plane in which is the spiral spring 12, the tightening-locking of this plate 50 will take place perpendicular to the plane of the spiral spring 12. Conversely, if the plate 50 extends perpendicular to the plane in which the spiral spring 12 is located, the tightening-locking of this plate 50 will be in a direction parallel to the plane of the spiral spring 12. In other words, the threaded rod 18 will be screwed into the eyebolt 2 in a direction perpendicular to the longitudinal axis of symmetry of the eyebolt 2. Care will also be taken to note that given that the spiral spring 12 is in the form of an extremely thin ribbon wound on itself in a succession of turns, the plane in which the free end 8 of the last turn extends outside 10 of the spiral spring 12 the plane in which this winding is included. It will also be noted that the plate 50 is a surface element, for example of rectangular shape, and that, depending on the case, this surface element is either included in the plane of the spiral spring 12, or perpendicular to this plane.

Nomenclature

• 1. Fixing assembly
• 2. Peak
• 4. Exterior wall
• 6. Groove
• 8. Free end
• 10. Last turn outside
• 12. Spiral spring
• 14. Blocking element
• 16. Clamping member
• 18. Threaded rod
• 20. Split head
• 22. Tapped hole
• 24. Friction surface
• 26. Knurling
• 28. Clamp
• 30a, 30b. Jaws
• 32a, 32b. Distal ends
• 34. Space
• 36a, 36b. Proximal ends
• 38. Wall
• 40. Area
• 42a, 42b. Recesses
• 44. Space
• 46. Background
• 48. Pendulum
• 50. Brochure
• 52. Axis
• 54. Ankle
• 56. Tray
• 58. Exhaust line
• 60. Oblong opening
• 62. Eyebolt piece
• 64. Bridge
• 66. Through hole
• 68. Stem

Claims (13)

Assembly (1) for fixing a free end (8) of a last turn to the exterior (10) of a spiral spring (12) for a watch movement, this fixing assembly (1) comprising a eyebolt (2) and a locking element (14), the eyebolt (2) being provided with a groove (6) in which the spiral spring (12) is engaged at one point along its length, the locking element (14) also being engaged in the groove (6), in contact with the spiral spring (12), the fixing assembly (1) also comprising a clamping member (16) which presses the blocking element (14) against the spiral spring (12), so that the spiral spring (12) is immobilized in the groove (6) of the eyebolt (2). Fixing assembly (1) according to claim 1, characterized in that the spiral spring (12) is engaged in the groove (6) of the eyebolt (2) by the free end (8) of its last turn on the outside (10). Fixing assembly according to claim 2, characterized in that the immobilization of the free end (8) of the last turn outside (10) of the spiral spring (12) is ensured by mechanical tightening and blocking in one direction perpendicular to the plane in which this free end (8) of the spiral spring (12) extends. Fixing assembly (1) according to one of claims 1 to 3, characterized in that the groove (6) extends from an exterior wall (4) of the eyebolt (2) and towards the interior of the latter. Fixing assembly (1) according to claim 4, characterized in that the groove (6) has a height and the blocking element (14) a thickness such that, once the blocking element (14) engaged in this groove (6), there remains sufficient space to be able to engage the free end (8) of the last turn outside (10) of the spiral spring (12) in the groove (6). Fixing assembly (1) according to claim 5, characterized in that the space in which the free end (8) of the last turn outside (10) of the spiral spring (12) is engaged extends between the blocking element (14) and a bottom (46) of the groove (6). Fixing assembly (1) according to claim 6, characterized in that the free end (8) of the last turn outside (10) of the spiral spring (12) ends in a plate (50) which is fixed on this free end (8) or which is made in one piece with this free end (8). Fixing assembly (1) according to one of claims 1 to 7, characterized in that a hole (22) in which the clamping member (16) is engaged is provided in the eyebolt (2) so that the The clamping member (16) opens into the groove (6) and presses against the blocking element (14) and presses the latter against the free end (8) of the last turn outside (10) of the spring hairspring (12). Fixing assembly (1) according to claim 8, characterized in that the clamping member (16) is a threaded rod (18) and in that the hole (22) is tapped. Fixing assembly (1) according to one of claims 8 and 9, characterized in that the blocking element (14) is a clamp (28) provided with two jaws (30a, 30b) connected to one another. another at a distal end (32a, 32b), these two jaws (30a, 30b) delimiting between them a space (34) open on the side of their proximal end (36a, 36b). Fixing assembly (1) according to claim 10, characterized in that the eyebolt (2) comprises a wall (38) which delimits the groove (6). Fixing assembly (1) according to claim 11, characterized in that the interior face of one of the jaws (30a, 30b) of the clamp (28) has a surface (40) which moves away from the wall (38) of the eyebolt (2) in the direction of engagement of the clamp (28) on the eyebolt (2). Fixing assembly (1) according to one of claims 11 and 12, characterized in that the interior face of the jaws (30a, 30b) of the clamp (28) are provided with recesses (42a, 42b) whose shapes are complementary and match those of the wall (38), allowing the clamp (28) to grip the wall (38) and ensure its maintenance.

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