EP4105734A2 - Micromechanical mechanism provided with a system for actuating by impact, in particular for timepieces - Google Patents

Abstract

The invention relates to a micromechanical mechanism (1), in particular for a clock movement (3), the mechanism comprising a micromechanical device having a specific function, the device comprising a mobile element (8) requiring to be moved mechanically to trigger its operation, characterized in that it comprises an actuation system for the device, the actuation system comprising a movable striker (16, 17, 18) configured to pass from a trigger position (19) to a percussion position (21) in which it transmits to the movable element (8) a quantity of movement necessary for triggering the device, the actuation system further comprising a magnet (15) configured to attract the movable striker (16, 17, 18) in the percussion position (21).

The invention also relates to a clock movement (3) comprising such a mechanism (1).

Description

Technical field of the invention

The invention relates to a micromechanical mechanism provided with a percussion actuation system, in particular for watchmaking.

The invention also relates to a timepiece movement comprising such a micromechanical mechanism.

Technology background

In the field of watchmaking, various kinds of complications are known, some of which require a particular actuation device, in particular because they require occasional triggering.

For example, a striking mechanism can be combined with a traditional watch movement to serve in particular as minute repeaters or to signal a programmed alarm time. Such a striking mechanism generally comprises at least one gong made of sapphire, quartz or metallic material, such as steel, bronze, precious metal or metallic glass. This gong can describe for example at least a portion of a circle around the watch movement in the watch cage. The stamp is fixed by at least one of its ends to a stamp holder, which is itself secured to a watch plate.

To actuate the ringing, a hammer of the mechanism is rotatably mounted on the plate, for example near the gong holder, so as to strike the gong to make it vibrate. The sound produced by the gong struck by the hammer lies notably in the audible frequency range of 1 kHz to 20 kHz. This allows the wearer of the watch to be notified of a well-defined time, a programmed alarm or a minute repeater.

As depicted in the patent document EP 1 574 917 A1 , the striking mechanism of a watch can comprise two or more gongs fixed by one of their ends to the same gong holder, which is itself integral with a plate. Each stamp can be struck by a respective hammer. To do this, each hammer is driven by its own drive spring, which had to be wound beforehand, so as to drive the hammer against the gong, in order to signal a minute repeater or an alarm hour. Two damping counter-springs are each provided to push back and maintain the two hammers at a distance from the gongs in a rest mode. In a striking mode, the damping counter-springs act with great force and slow the fall of each hammer before striking against the respective gong. These counter-springs make it possible, following the strike, to push back each hammer towards their rest position. Eccentrics are also provided for adjusting the operation of the counter-springs to essentially prevent any bouncing of each hammer against the respective gong.

A drawback of known actuation systems is the amount of energy they require to operate optimally. This energy is either provided by the barrel or by manual actuation.

For example, in the case of a chime, the hammer must be actuated automatically in order to operate, in particular thanks to the energy supplied by the barrel.

In the case of manual pressure, the pressure required can be relatively high, which is not pleasant for the person using the mechanism.

More generally, one may also need an actuation system which operates continuously. For example, in the case of an escapement mechanism, the movement must be maintained at a predefined frequency. Now, today, there are few alternatives to an escape wheel cooperating with an anchor, the energy consumption of which is high. Detent escapement mechanisms are known, which do not include an anchor. However, these mechanisms are complex to implement and to actuate.

Summary of the invention

The object of the invention is therefore to overcome the drawbacks of the aforementioned state of the art by providing an innovative actuation system, in particular for a timepiece, with the aim of avoiding a significant use of energy necessary to its operation.

To this end, the invention relates to a micromechanical mechanism, in particular for a clock movement, the mechanism comprising a micromechanical device having a specific function, the device comprising a movable element requiring to be moved mechanically to trigger its operation.

The mechanism is remarkable in that it comprises a system for actuating the device, the actuating system comprising a movable striker configured to pass from a trigger position to a percussion position in which it transmits to the movable element a quantity of movement necessary to trigger the micromechanical device, the actuation system further comprising a magnet configured to attract the movable striker into the percussion position.

On the one hand, the force of attraction of the magnet is used to put the striker in the position of percussion. On the other hand, the striker transmits a quantity of movement necessary to the mobile element. Thanks to the momentum of the striker, the moving element receives enough energy to trigger the micromechanical device. Thus, the energy necessary for actuating the striker and/or the movable element is saved. In addition, the transmitted energy substantially corresponds to the momentum of the striker and is therefore relatively constant, independently of the energy of the striker actuation system, the system thus forming a constant-force system.

Thanks to the invention, the actuation energy of the micromechanical device is lower. Depending on the actuation system, the cylinder is less stressed, or manual actuation is easier.

Furthermore, by selecting a particular mass difference between the mobile element and the striker, the speed of the mobile element can be adapted. For example, one can choose a mobile element of reduced mass, which moves with a greater speed than that of the striker having a greater mass. A lighter mobile element moving quickly reduces the risk of rebound after the impact against the gong.

According to a particular embodiment of the invention, the movable element comprises a magnetic conductive material.

According to a particular embodiment of the invention, the striker comprises a magnetic conductive material, so as to be attracted by the magnet.

According to a particular embodiment of the invention, the movable element is in contact with the magnet in its rest position.

According to a particular embodiment of the invention, the striker is configured to strike the magnet so as to give an impulse to the mobile element.

According to a particular embodiment of the invention, the distance between the firing position of the striker and the magnet is chosen so that the magnet attracts the striker against itself in its percussion position.

According to a particular embodiment of the invention, the quantity of movement transmitted by the striker is sufficiently important to overcome the holding force of the magnet acting on the movable element, so that the movable element detaches from the magnet.

According to a particular embodiment of the invention, the mechanism comprises a flexible guide on which the movable element is mounted to allow it to move between its rest position and its impact position.

According to a particular embodiment of the invention, the flexible guide is configured to press the movable element against the magnet.

According to a particular embodiment of the invention, the actuation system comprises a flexible guide on which the striker is mounted to allow it to move between the release position and the percussion position.

According to a particular embodiment of the invention, the flexible guide comprises a flexible blade or a flexible neck.

According to a particular embodiment of the invention, the actuation system comprises a rotary device provided with the striker, the rotary device being configured to bring the striker into the release position.

According to a particular embodiment of the invention, the actuation system comprises at least one additional striker, preferably two additional strikers, arranged on the rotary device, so as to alternately bring each striker into the release position.

According to a particular embodiment of the invention, the rotary device comprises a rotary hub.

According to a particular embodiment of the invention, the rotary device comprises at least one arm, each arm carrying a striker.

According to a particular embodiment of the invention, the rotary device comprises several arms distributed angularly around the hub.

According to a particular embodiment of the invention, the mass of the striker is greater than that of the movable element, for example, the mass of the striker is at least twice greater than that of the movable element.

According to a particular embodiment of the invention, the micromechanical device is a bell, the device comprising at least one resonant element making it possible to emit a sound when it is struck, the mobile element being a hammer mobile between the position of rest and the shock position in which it strikes the resonant element to make it vibrate.

According to a particular embodiment of the invention, the micromechanical mechanism is a regulating member fitted with a balance wheel, an escapement mechanism fitted with an escapement wheel and a detent rocker cooperating with the wheel escapement, the balance wheel being actuated by the movable element.

According to a particular embodiment of the invention, the mobile element strikes the balance in the impact position.

According to a particular embodiment of the invention, the mobile element strikes the balance in the impact position, preferably with a single impact.

According to a particular embodiment of the invention, the balance comprises a release lever arranged to move the detent rocker in order to release the escape wheel.

According to a particular embodiment of the invention, the device can be triggered punctually.

According to a particular embodiment of the invention, the magnet is fixed relative to the clock movement.

The invention also relates to a timepiece movement comprising such a micromechanical mechanism.

Brief description of figures

• la figure 1 est une représentation schématique d'une pièce d'horlogerie comportant un mécanisme micromécanique de sonnerie à percussion selon un premier mode de réalisation de l'invention;
• la figure 2 est une représentation schématique agrandie du mécanisme micromécanique de sonnerie de la figure 1;
• la figure 3 est une représentation schématique du mécanisme micromécanique de sonnerie de la figure 1, dans lequel le percuteur est en position de déclenchement;
• la figure 4 est une représentation schématique du mécanisme micromécanique de sonnerie de la figure 1, dans lequel le percuteur est en position de percussion avec l'aimant et l'élément mobile, ici un marteau, en position de choc avec le timbre;
• la figure 5 est une représentation schématique du mécanisme de sonnerie de la figure 1, dans lequel le percuteur n'est plus en position percussion ni en position de déclenchement et l'élément mobile est revenu en position de repos ;
• la figure 6 est une représentation schématique d'un mécanisme micromécanique d'échappement à percussion selon un deuxième mode de réalisation de l'invention ;
• la figure 7 est une représentation schématique du mécanisme micromécanique d'échappement de la figure 6, dans lequel la bascule de détente est déplacée par le balancier ;
• la figure 8 est une représentation schématique du mécanisme micromécanique d'échappement de la figure 6, dans lequel le percuteur est en position de déclenchement ;
• la figure 9 est une représentation schématique du mécanisme d'échappement de la figure 6, dans lequel le percuteur est en position de percussion avec l'aimant ;
• la figure 10 est une représentation schématique du mécanisme d'échappement de la figure 6, dans lequel l'élément mobile est en position de choc avec le balancier ; et
• la figure 11 est une représentation schématique du mécanisme d'échappement de la figure 6, dans lequel le balancier est en mouvement.

Other features and advantages will emerge clearly from the description given below, by way of indication and in no way limiting, with reference to the appended drawings, in which:

• the figure 1 is a schematic representation of a timepiece comprising a micromechanical percussion striking mechanism according to a first embodiment of the invention;
• the picture 2 is an enlarged schematic representation of the micromechanical striking mechanism of the figure 1 ;
• the picture 3 is a schematic representation of the micromechanical striking mechanism of the figure 1 , in which the firing pin is in the trigger position;
• the figure 4 is a schematic representation of the micromechanical striking mechanism of the figure 1 , in which the striker is in the percussion position with the magnet and the movable element, here a hammer, in the shock position with the gong;
• the figure 5 is a schematic representation of the striking mechanism of the figure 1 , in which the striker is no longer in the percussion position or in the trigger position and the movable element has returned to the rest position;
• the figure 6 is a schematic representation of a micromechanical percussion escapement mechanism according to a second embodiment of the invention;
• the figure 7 is a schematic representation of the micromechanical escapement mechanism of the figure 6 , wherein the trigger rocker is moved by the balance;
• the figure 8 is a schematic representation of the micromechanical escapement mechanism of the figure 6 , in which the firing pin is in the trigger position;
• the figure 9 is a schematic representation of the escapement mechanism of the figure 6 , in which the striker is in the percussion position with the magnet;
• the figure 10 is a schematic representation of the escapement mechanism of the figure 6 , in which the movable element is in a position of impact with the pendulum; and
• the figure 11 is a schematic representation of the escapement mechanism of the figure 6 , in which the pendulum is in motion.

Detailed description of the invention

As explained above, the invention relates to a micromechanical mechanism, which has a specific function of striking 1 in the first embodiment. By specific function is meant a micromechanical function different from the usual function linked to the display of the time.

The striking mechanism 1 is intended for a timepiece 10, such as a watch represented on the figure 1 . The timepiece 10 comprises a middle part 2 and a timepiece movement 3, preferably mechanical, which is for example provided with a plate 4 and a barrel spring to supply the operating energy. The embodiment described below is based on the combination of the “Gauss magnetic gun” principle and the principle of the conservation of momentum during a shock.

On the figures 1 to 5 , the striking mechanism 1 comprises a micromechanical device provided with a resonant element 5, for example a gong conventionally used in clock strikes. The resonant element 5 makes it possible to emit a sound when struck. In the figures, the resonant element 5 is a rod comprising a rectilinear portion 6. The resonant element 5 is preferably fixed to the plate 4, so as to extend above beside the plate 4, for example in a plane parallel to that of stage 4.

Other configurations of resonant element 5 are possible. The resonant element 5 may further comprise a circular portion 7, represented on the figure 1 , in particular to lengthen the inner face of the middle part 2.

To emit a sound, the mechanism 1 comprises a movable element 8, here a hammer, which is movable relative to the plate 4. The movable element 8 is movable between two positions, a rest position 9 remote from the resonant element 5, and a shock position 11 in which it hits the resonant element to make it vibrate. Thus, the resonant element 5 produces a vibration which propagates in the watch. The outer part of the watch radiates these vibrations so as to emit sound. Other embodiments are possible with various forms of mobile element and resonant element 5.

The mechanism 1 here comprises a flexible guide 12 on which the movable element 8 is mounted to allow it to move between its rest position 9 and its impact position 11. The flexible guide 12 preferably comprises a first flexible blade 13 assembled at the turntable 4 on the one hand, and to the movable element 8 on the other hand. The first flexible blade 13 is preferably arranged substantially parallel to the resonant element 5 when the movable element 8 is in the rest position 9.

By the elastic deformation of the first flexible blade 13, the movable element 8 passes from the rest position 9 to the shock position 11 and vice versa.

The mechanism 1 further comprises a magnet 15 fixed relative to the plate 4. The magnet 15 is preferably assembled on the plate 4. The magnet 15 is for example arranged on a promontory 14 opposite the resonant element 5.

Preferably, the magnet 15 is configured to retain the mobile element 8 in its rest position 9. For this purpose the mobile element 8 comprises a magnetic conductive material, which induces a force of attraction of the mobile element 8 against magnet 15.

Alternatively, one can choose a mobile element 8 not comprising any magnetic conductive material. In this case, the flexible guide 12 is configured to apply a prestress to the movable element 8, so as to press it against the magnet 8.

Thus, in the rest position 9, the movable element 8 is in contact with a front face 29 of the magnet 15. The movable element 8 keeps this position permanently, except when it strikes the resonant element 5 The flexible guide 12 is assembled to the plate 4 between the promontory 14 and the resonant element 5. Thus, the movable element 8 can move between the magnet 15 and the resonant element 5 thanks to the flexible guide 12.

The front face 29 preferably has a substantially flat surface. The movable element 8 has for example a cylindrical or spherical shape. These rounded shapes make it easier to separate the movable element 8 of the front face 29 from the magnet 15.

According to the invention, the mechanism 1 comprises a system for actuating the movable element 8. This system is configured to cause the displacement of the movable element 8 from its rest position 9 to its impact position 11. In particular , it serves to separate the movable element 8 from the magnet 15 and to allow it to reach the resonant element 5. The actuation system includes the magnet 15.

To this end, the actuation system 20 comprises at least one movable striker 16, 17, 18 configured to transmit to the movable element 8 a quantity of movement sufficient for it to pass from its rest position 9 to its resting position. shock 11 and to vibrate the resonant element 5.

The striker 16, 17, 18 is configured to pass from a trigger position 19 to a percussion position 21 in which it transmits a quantity of movement to the mobile element 8.

In, the embodiment of figures 1 to 5 , the actuation system comprises a rotary device 20 provided with three movable strikers 16, 17, 18.

The rotary device 20 comprises a hub 22 and three arms 23, 24, 25, distributed angularly around the hub 22, and are connected to the hub 22 by one end. Each arm 23, 24, 25 carries a movable striker 16, 17, 18 disposed at the opposite end of the arm 23, 24, 25 relative to the hub 22. The arms 23, 24, 25 are preferably arranged in the same plane substantially perpendicular to the axis of the hub 22. This plane also preferably passes through the magnet 15, the movable element 8 and the resonant element 5.

The system can comprise a greater or lesser number of arms and strikers than those illustrated in the embodiment described.

Each movable striker 16, 17, 18 is mounted on an arm 23, 24, 25 so as to form an angle with the arm 23, 24, 25. The angle is typically between 30 and 60°, when the movable striker 16 , 17, 18 is trigger position 19, and the angle is typically between 60 and 90°, when the movable striker 16, 17, 18 is in the percussion position 21. An arm can, for example, be an oblong body, a cog or a plate.

Preferably, each movable striker 16, 17, 18 is mounted on the arm 23, 24, 25 by a flexible guide to allow it to move relative to the arm 23, 24, 25, and to pass from the trigger position 19 in the percussion position 21. The flexible guide here comprises a second flexible blade 26 assembled with the movable striker 16, 17, 18 on the one hand, and on the other hand at the end of the arm 23, 24, 25.

Each movable striker 16, 17, 18 comprises a contact face 31, 32, 33, which is intended to come into contact with the magnet 15, when it passes from the trigger position 19 to the percussion position 21. contact faces 31, 32, 33 of the movable strikers 16, 17, 18 are preferably rounded, to allow easier unhooking when the movable striker 16, 17, 18 returns to its release position.

When the rotary device 20 rotates, it positions one of the movable strikers 16, 17, 18 opposite the magnet 15. The movable striker 16, 17, 18 then passes from the trigger position 19 to the percussion position 21 according to a radial displacement. Once the percussion has been performed, the rotary device 20 continues to rotate in order to prevent the movable striker 16, 17, 18 from remaining against the magnet 15. The geometry of the movable strikers 16, 17, 18 is made in such a way as to require the least possible torque on the rotary device 20. For example, a contact face 32 is chosen having the shape of a ramp tangential to the rotary movement.

The rotary device 20 is actuated by rotating the hub 22 around its axis, so that the arms 23, 24, 25 rotate around the axis of the hub 22. Thus, the movable strikers 16, 17, 18 also rotate around of the axis of the hub 22 while remaining in the trigger position 19. In other words, the movable strikers 16, 17, 18 remain in the same position relative to the arms 23, 24, 25, which carry them.

To turn, the means 22 is mechanically connected to the barrel of the movement via gear means, not shown in the figures. These gear means comprise for example an actuation system configured to determine the chimes to be executed according to the time displayed by the movement 3, in particular to serve as minute repeaters or to signal a programmed alarm time. Thus, when one or more bells should sound, the actuation system triggers the rotation of the hub 22.

The rotary device 20 is configured to bring the striker into the trigger position 19 in front of the magnet 15. The picture 3 shows an example in which the striker is in the trigger position 19 closest to the magnet 15. The magnet 15 has an opposite face 30 oriented towards the rotary device 20, so that the opposite face 30 of the magnet 15 and a contact face 31, 32, 33 of a movable striker 16, 17, 18 face each other when the rotating device 20 rotates. The opposite face 30 preferably has a substantially planar surface.

The force of attraction of the magnet 15 and the distance between the contact face 31, 32, 33 of the movable striker 16, 17, 18 in the trigger position 19 and the opposite face 30 of the magnet 15 are chosen, so that the magnet 15 attracts the striker 16 against its opposite face 30, when it passes in front of its opposite face 30. Thus, the magnetic potential energy produced by the magnet 15 acting on the movable striker 16, 17, 18 is transformed into kinetic energy by the movable striker 16, 17, 18. This kinetic energy is transmitted to the movable element 8 by the impact of the movable striker 16, 17, 18.

Indeed, when the movable striker 16, 17, 18 is attracted by the magnet 15, it is accelerated and strikes the magnet 15. When the movable striker 16, 17, 18 collides with the opposite face 30 of the magnet 15, at least part of its momentum is transmitted to the movable element 8 through the magnet 15, the movable element 8 being placed against the front face 29 of the magnet in the rest position.

This principle of motion transmission combined with a magnetic attraction is known as the “Gauss cannon”. The attraction of the magnet 15 guarantees a minimum intensity on each strike of the mobile element 8. The resulting ringtone is more constant over the entire duration of the ringtone, independently of the barrel torque.

As shown in figure 4 , each movable striker 16, 17, 18 is configured to strike the magnet 15 so as to give an impulse to the movable element.

Furthermore, the movable strikers 16, 17, 18 and the rotary device 20 are configured so that the amount of movement transmitted to the movable element 8 by the striker 16, 17, 18 is greater than the retaining force of the magnet. acting on the movable element 8, so that the movable element detaches from the magnet 15 and strikes the resonant element 5 with sufficient force, as shown in figure 4 .

As shown on the figure 5 , the magnet 15 and the mobile element 8 are further configured so that the front face 29 attracts the mobile element 8 against it, after the latter has struck the resonant element 5. Thus, the mobile element 8 returns to its rest position 9, and can again be actuated by the mobile striker 16, 17, 18 next. It is also avoided that the movable element 8 rebounds and hits the resonant element 5 again inappropriately.

In the case of a mobile element 8 not comprising any magnetic conductive material, the flexible guide 12 brings the mobile element back against the magnet 15.

Continuing to rotate, the rotation device 20 pulls on the movable striker 16, 17, 18 so that it detaches from the opposite face. 30 of the magnet 15. At the same time, when the hub 22 rotates, the next movable striker 16, 17, 18 approaches the magnet 15.

The rotation device 20 is actuated by the movement, when a bell is required. Thus, the ringtone sounds automatically thanks to the movable strikers 16, 17, 18, the magnet 15, the movable element 8 and the resonant element 5.

In operation, each movable striker 16, 17, 18 strikes the magnet 15 one after the other, to produce a sound each time. With each percussion of a movable striker 16, 17, 18, the movable element 8 strikes the resonant element 5, and returns to the rest position 9 against the magnet 15 between two successive percussions.

Depending on the number of ringtones to be emitted, the rotation device is actuated for a predefined time.

Preferably, the rotation takes place at constant speed so that the ringtones are emitted periodically at the same frequency.

The rotation speed can also be variable to emit a particular ringtone.

The figures 6 to 11 represent a second embodiment of the invention, in which the micromechanical mechanism 10 is a regulating member for a clock movement. The micromechanical device comprises a detent escapement mechanism, a movable element 8 and a balance plate 36. The escapement mechanism comprises a rotating escapement wheel 34 provided with peripheral teeth 35 capable of cooperating with a notch 42 of the rotation of the escape wheel 34. The escape wheel 34 is preferably mechanically connected to means for driving the movement, for example a barrel.

The escapement mechanism further comprises a detent rocker 40 cooperating with the balance plate 36. During its actuation, the balance plate 36 reciprocates clockwise and counterclockwise.

The detent rocker 40 includes the detent 42 allowing the escape wheel 34 to be retained.

The detent rocker 40 further comprises a flexible blade 41 at one end, the flexible blade being capable of cooperating with the balance plate 36 to allow the balance to disengage the detent rocker during its counterclockwise rotation. The flexible blade 41 is fixed on the trigger rocker 40 and is arranged longitudinally in the extension of the trigger rocker 40. The trigger rocker 40 has a lug 43 at its end in order to retain the flexible blade 41 during movement. to the right. When the balance plate 36 rotates clockwise, the flexible blade 41 can move away from the lug 43 without the trigger rocker 40 moving. When the balance plate rotates counterclockwise, blade 41 presses against lug 43 and angularly moves the detent rocker so as to release notch 42 from escape wheel 34.

The balance plate 36 has a circular shape, for example a disc, and is provided with a release lift 37 and an impulse lift 38 arranged at the periphery of the disc 36, and extending over two different levels. above the disc, preferably close to each other. Here, clearance lift 37 extends above impulse lift 38.

During a counter-clockwise rotation, the release lever 37 makes it possible to move the trigger rocker 40 to release the detent 42 from the tooth 35 of the escape wheel 34 so that the latter can rotate.

Pulse lifting 38 makes it possible to receive a pulse from movable element 8 to cause rotation of balance plate 36, here in the counterclockwise direction.

The trigger rocker 40 extends longitudinally, and is arranged at the level of the release lift 37, and the movable element 8 is arranged at the level of the impulse lift 38. Thus, the trigger rocker 40 is above top of the mobile element 8.

The trigger rocker 40 is arranged tangentially to the escapement wheel 34, obliquely as far as the balance plate 36 at its end 41. The trigger rocker 40 is held by a flexible blade 39 in the extension of the second end .

The actuation system 20 is identical to the first embodiment. The rotary device 20 is mounted on the escapement wheel 34 in a plane parallel to that of the escapement wheel 34. Thus, when the escapement wheel 34 rotates, the rotary device 20 also rotates.

The rotary device 20 is configured to bring a striker 16, 17, 18 into the trigger position 19 in front of the magnet 15. The actuating mechanism operates in a manner similar to that of the first embodiment.

The figures 6 to 11 show different stages of micro-mechanism dynamics, which is described below.

On the figure 6 , the detent 42 of the detent rocker 40 blocks the rotation of the escapement wheel 34. The movable element 8 is in contact with the magnet 15 in its rest position 9. The strikers 16, 17, 18 of the rotary device are in positions which do not allow the moving element 8 to be actuated.

The balance plate 36 is in rotation around its axis of rotation in the clockwise direction, according to the arrow indicated.

The balance plate 36 performs a clockwise/counterclockwise rotation alternately on each actuation at a predefined frequency.

As shown on the figure 7 , when passing counterclockwise, the clearance lift 37 comes into contact with the blade flexible 41 of the trigger rocker 40. Thus, the trigger rocker 40 is moved laterally, so that the detent 42 shifts from the tooth 35 in order to release the escapement wheel 34.

Thus, the escape wheel 34 can rotate around its axis of rotation. On the figure 8 , the rotation of the escapement wheel 34 brings a striker 16 into the trigger position 19 to actuate the actuation system 20. Attracted by the magnet 8, the striker 16 moves into the percussion position 21 against the magnet 15 , and transmits a quantity of movement to the movable element 8, as shown in the figure 9 .

On the figure 10 , when the movable element 8 receives the quantity of movement via the magnet 15, the movable element 8 strikes the impulse lift 38 of the balance plate 36 in the shock position 11. The energy transmitted to the balance plate 36 is received as a single point shock. This form of pulse is advantageous, from a chronometric point of view, as known to those skilled in the art.

Thus, at least part of the quantity of movement transmitted by the striker 16 to the movable element 8 is supplied to the balance plate 36. The quantity of movement is sufficient for the balance 36 to continue its rotation and maintain its amplitude, here counterclockwise, as shown in the figure 11 .

A hairspring, not shown in the figures, applies a fore this return to the balance, so that the balance plate 36 then performs a rotation in the clockwise direction, after having reached its extreme position in the counterclockwise direction.

In the clockwise direction, the disengagement lift 37 comes into contact with the flexible blade 41, which flexes to let the disengagement lift 37 pass. Indeed, in this direction, the flexible blade 41 is not retained by a lug. The escape wheel 34 is not affected by the flexing of the flexible blade 41. The passage of the lift 37 only lifts the blade 41 without given impulse, this empty passage being called "lost blow" by those skilled in the art.

Thus, as shown by the figure 6 , the balance plate 36 continues its rotation in the clockwise direction, up to an extreme clockwise position.

Finally, the spiral spring exerts a restoring force to return the balance plate 36 counterclockwise, until the disengagement lift 37 is retained by the flexible blade 41 of the detent rocker 40, as shown in the figure 7 .

During the rotations of the balance plate 36, the mobile element 8 comes back against the magnet 15, while the detent rocker 40 returns to its initial position, the detent 42 blocking the escape wheel 36 by contact with the next peripheral tooth 35 of escapement wheel 34.

The actuation mechanism makes it possible to maintain the movement of the balance wheel, and consequently the movement of the regulating organ and of the escapement mechanism. The frequency of the balance wheel determines the operating frequency of the regulating organ. Thus, it is possible to maintain the oscillation with a Gauss cannon type system.

Of course, the present invention is not limited to the illustrated examples of striking mechanism and regulating organ, but it is susceptible of various variants and modifications which will become apparent to those skilled in the art.

In particular, the actuation system can be adapted to other types of micromechanical devices comprising a mobile element. For example, the mobile element can be a date-type display disc.

The actuation system can be connected to a push button of the timepiece. By pressing the push button, via a mechanical relay, such as gears, the striker is placed in the position of release, for example by rotating the hub. Thus, such an actuation system can be used to trigger a micromechanical device manually on demand.

Claims (19)

Micromechanical mechanism (1), in particular for a clock movement (3), the mechanism comprising a micromechanical device having a specific function, the device comprising a movable element (8) requiring to be moved mechanically to trigger its operation, characterized in that it comprises an actuation system for the device, the actuation system comprising a movable striker (16, 17, 18) configured to pass from a trigger position (19) to a percussion position (21) in which it transmits to the movable element (8) a quantity of movement necessary to trigger the micromechanical device, the actuation system further comprising a magnet (15) configured to attract the movable striker (16, 17, 18) into position percussion (21). Micromechanical mechanism according to Claim 1, characterized in that the movable element (8) is in contact with the magnet (15) in its rest position (9). Micromechanical mechanism according to Claim 2, characterized in that the movable striker (16, 17, 18) is configured to strike the magnet (15) so as to give an impulse to the movable element (8) via the magnet (15 ). Micromechanical mechanism according to Claim 3, characterized in that the distance between the release position (19) of the movable striker (16, 17, 18) and the magnet (15) is chosen so that the magnet (15) attracts the movable striker (16, 17, 18) against it in its percussion position (21). Micromechanical mechanism according to Claim 4, characterized in that the quantity of movement transmitted by the movable striker (16, 17, 18) overcomes the magnetic retaining force of the magnet (15) acting on the movable element (8), so that the movable element (8) detaches from the magnet (15). Micromechanical mechanism according to any one of the preceding claims, characterized in that it comprises a flexible guide (12) on which the movable element (8) is mounted to allow it to move between its rest position (9 ) and its shock position (11). Micromechanical mechanism according to any one of the preceding claims, characterized in that the actuation system comprises a flexible guide on which the movable striker (16, 17, 18) is mounted to allow it to move between the position of trigger (19) and percussion position (21). Micromechanical mechanism according to Claim 7, characterized in that the flexible guide (12) comprises a flexible blade (13, 26, 27, 28) or a flexible neck. Micromechanical mechanism according to any one of the preceding claims, characterized in that the actuation system comprises a rotary device (20) provided with the movable striker (16, 17, 18), the rotary device being configured to bring the striker mobile (16, 17, 18) in the release position (19). Micromechanical mechanism according to Claim 9, characterized in that the actuation system comprises at least one additional striker (16, 17, 18), preferably two additional strikers, arranged on the rotary device (20), so as to alternately bring each movable striker (16, 17, 18) in the trigger position (19). Micromechanical mechanism according to any one of Claims 9 and 10, characterized in that the rotary device (20) comprises a hub (22). Micromechanical mechanism according to Claim 11, characterized in that the rotary device (20) comprises at least one arm (22, 23, 24), each arm (22, 23, 24) carrying a movable striker (16, 17, 18) . Micromechanical mechanism according to Claim 12, characterized in that the rotary device (20) comprises several arms (22, 23, 24) distributed angularly around the hub (22). Micromechanical mechanism according to any one of the preceding claims, characterized in that the micromechanical mechanism is a bell, the device (1) comprising at least one resonant element (5) making it possible to emit a sound when struck, and a hammer as movable element (8) between the rest position (9) and the shock position (11) in which it strikes the resonant element (5) to make it vibrate. Micromechanical mechanism according to any one of Claims 1 to 13, characterized in that the micromechanical mechanism (10) is a regulating member provided with a balance, an escapement mechanism provided with an escapement wheel (34) and a detent rocker (40) cooperating with the escapement wheel (34), the balance being actuated by the movable element (8). Micromechanical mechanism according to Claim 15, characterized in that the movable element (8) strikes the balance in the impact position (11). Micromechanical mechanism according to Claim 15 or 16, characterized in that the movable element (8) strikes the pendulum in the impact position (11), preferably with a single impact. Micromechanical mechanism according to any one of Claims 15 to 17, characterized in that the balance includes a release lever (37) arranged to move the detent rocker (40) in order to release the escapement wheel (34) . Clock movement (3), characterized in that it comprises a micromechanical mechanism (1) according to any one of the preceding claims.

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