EP3376308B1 - Winding mechanism of a timepiece - Google Patents

Description

Field of the invention

The invention relates to a winding mechanism of a timepiece comprising at least a first energy accumulator arranged to supply power to a first mechanism and a second energy accumulator arranged to supply power to a second mechanism, said winding mechanism comprising a winding stem, a winding pinion and a sliding pinion carried by said winding stem and having opposite to each other straight teeth arranged to allow the driving of the winding pinion by the pinion flowing in both directions of rotation of the winding stem, said winding stem and the sliding pinion occupying the same axial position of winding. The invention also relates to a timepiece comprising such a winding mechanism.

Background of the invention

Such a winding mechanism is for example described in the patent CH 330202 . This document describes an alarm watch comprising a first energy accumulator constituted by the movement barrel and a second energy accumulator constituted by the striking barrel. The mechanism comprises a winding stem arranged to perform all the commands of the movement and the alarm clock, including setting the time of movement and ringing, but also the winding of the barrel of movement or the barrel of ringing by turning in one way or the other the winding stem when it occupies its middle winding position. For this purpose, the sliding pinion is engaged with the winding pinion by teeth of straight shape, and there is provided a crown wheel engaged with the winding pinion, and two crown gear, meshing both with the crown wheel and intended to cooperate respectively with the ratchet of each of the barrels. The meshing of the crown gear with the ratchet of the corresponding barrel is provided by a spring which acts on the axes of the crown gear to push them and bring them into engagement with the corresponding ratchet. When the winding stem is turned in one direction or the other, by the tangential force exerted by the crown wheel on the returns, one of the crown returns operates the winding of the corresponding cylinder while the other makes unlatching. The unclamping causes the persistence of a weak and cyclic contact. Such a mechanism is fragile due to the permanent solicitation of the spring to ensure a good meshing of the crown returns with the corresponding ratchet. A loss of efficiency of the spring, by fatigue or aging, entails the risk that one or other of the referrals no longer cooperate with the corresponding ratchet so that the associated cylinder can not be reassembled. Another disadvantage is the wear of the crown gear during unclipping. In addition, this construction imposes a control of the manufacturing tolerances of the spring.

The patent CH 47977 also discloses a mechanism for winding and setting the watch clock to two barrels. This mechanism comprises a winding ratchet of the movement barrel constantly engaged with a crown wheel meshing with a winding pinion, and arranged to actuate the movement barrel shaft only in a direction of rotation of the rod. The winding ratchet of the movement barrel is used to transmit the reverse movement of rotation of the rod to either the winding ratchet of the revolving barrel or to the waking wheel by a return pivoted on a rocker operable from outside the watch . This mechanism has the disadvantage of requiring the actuation of an external control in addition to the rotation of the winding stem to raise the barrel of ringing.

Summary of the invention

The invention particularly aims to overcome the various disadvantages of known devices.

More specifically, an object of the invention is to provide a winding mechanism for the reassembly of two energy accumulators by the single rotation of the winding stem in both directions.

The invention also aims to provide a winding mechanism for reassembly of two energy accumulators having a high accuracy and reliable over time.

The invention also aims to provide a winding mechanism for the reassembly of two energy accumulators having a high degree of modularity in the choice of the positioning of the various elements of the mechanism, as well as in the choice of the direction of reassembly of the accumulators of energy.

To this end, the present invention relates to a winding mechanism of a timepiece comprising at least a first energy accumulator arranged to supply energy to a first mechanism and a second energy accumulator arranged to supply energy to a second mechanism, said winding mechanism comprising a winding stem, a winding pinion and a sliding pinion carried by said winding stem and having opposite to each other straight teeth arranged to allow the driving of the winding pinion by the pinion flowing in both directions of rotation of the winding stem, said winding stem and the sliding pinion occupying the same axial position of winding.

According to the invention, said winding stem is housed in a plate so that the winding pinion is operational on both sides of the winding stem relative to the plate and the winding mechanism comprises a first and a second device clutch / clutch disposed on either side of the winding stem relative to the plate, cooperating with the winding pinion and arranged so that one of the first and second clutch / clutch devices occupies a position of clutch for engaging the winder pinion and the first energy accumulator while the other of the first and second clutch / disengagement devices is in a disengaged position for disengaging the second energy accumulator when the winding stem is turned in one direction, and occupies a disengaging position to disengage the first energy accumulator while the other of the first and second clutch / disengagement devices occupies a clutch position to engage the winding pinion and the second clutch accumulator. energy when the winding stem is turned in the other direction.

Thus, the winding mechanism according to the invention makes it possible to go up two energy accumulators by the single rotation of the winding stem in one direction and the other.

In addition, each energy accumulator is reassembled by means of its own clutch / disengagement device ensuring a better reliability of the winding mechanism. The disengagement means a total absence of contact and therefore the elimination of the risk of wear, unlike unclipping.

The winding mechanism according to the invention is particularly suitable for assembling a movement barrel constituting one of the energy accumulators and for mounting a barrel of an independent automaton constituting the other of the energy accumulators.

The present invention also relates to a timepiece comprising a winding mechanism as defined above.

Brief description of the drawings

• la figure 1 est une vue de dessus, côté mouvement, du mécanisme de remontage conforme à l'invention ;
• la figure 2 est une vue en perspective, côté mouvement, du mécanisme de remontage conforme à l'invention ;
• la figure 3 est une vue en perspective, côté automate, du mécanisme de remontage conforme à l'invention ;
• la figure 4 est une vue en coupe du mécanisme de remontage le long de la tige de remontoir ;
• la figure 5 est une vue du mécanisme de remontage en coupe dépliée passant par les engrenages concernés lorsque le barillet de mouvement est entrainé et le barillet d'automate est débrayé;
• la figure 6 est une vue du dispositif d'embrayage/débrayage côté automate en position de débrayage ;
• la figure 7 est une vue du dispositif d'embrayage/débrayage côté mouvement en position d'embrayage ;
• la figure 8 est une vue du mécanisme de remontage en coupe dépliée passant par les engrenages concernés lorsque le barillet de mouvement est débrayé et le barillet d'automate est entrainé ;
• la figure 9 est une vue du dispositif d'embrayage/débrayage côté automate en position d'embrayage ;
• la figure 10 est une vue du dispositif d'embrayage/débrayage côté mouvement en position de débrayage ;
• la figure 11 est une vue en perspective du pignon de remontoir ;
• la figure 12 est une vue en perspective du pignon coulant ; et
• la figure 13 est une vue en perspective côté automate du pignon coulant et du pignon de remontoir en position de remontage.

Other characteristics and advantages of the invention will emerge more clearly on reading the following description of an embodiment. particular of the invention, given as a simple illustrative and nonlimiting example, and the appended figures, among which:

• the figure 1 is a top view, on the movement side, of the winding mechanism according to the invention;
• the figure 2 is a perspective view, on the movement side, of the winding mechanism according to the invention;
• the figure 3 is a perspective view, PLC side, of the winding mechanism according to the invention;
• the figure 4 is a sectional view of the winding mechanism along the winding stem;
• the figure 5 is a view of the winding mechanism in unfolded section passing through the gears concerned when the movement barrel is driven and the automaton barrel is disengaged;
• the figure 6 is a view of the clutch / clutch device on the PLC side in the disengaged position;
• the figure 7 is a view of the clutch / clutch device on the movement side in the clutch position;
• the figure 8 is a view of the winding mechanism in unfolded section passing through the gears concerned when the movement barrel is disengaged and the automaton barrel is driven;
• the figure 9 is a view of the clutch / clutch device on the PLC side in the clutch position;
• the figure 10 is a view of the clutch / clutch device on the movement side in the disengaged position;
• the figure 11 is a perspective view of the winding pinion;
• the figure 12 is a perspective view of the sliding pinion; and
• the figure 13 is a perspective view PLC side of the sliding pinion and the winding pinion in the winding position.

Detailed description of a preferred embodiment

The present invention relates to a winding mechanism of at least two energy accumulators provided in a timepiece. These two accumulators can be independent of each other or linked, for example at the discharge. More particularly, in the description that follows, the two energy accumulators are independent or autonomous, one of the energy accumulators being a movement cylinder supplying energy to the base movement of the timepiece and the other energy accumulators being an automaton barrel feeding an automaton provided in the timepiece. It is obvious that the energy accumulators can be used to supply energy to any other mechanism of a timepiece, for example a striking mechanism, dead second or alarm clock, or any other appropriate mechanism.

In the example described below, the first energy accumulator is the movement barrel and the second energy accumulator is the automaton barrel. It is however quite obvious that the roles can be reversed, the character "first" or "second" attributed in this description to the barrel of movement, respectively to the barrel of automaton is not limiting.

With reference to the figure 1 , there is shown a winding mechanism 1 of a timepiece which comprises in a conventional manner a winding stem 2 on which are mounted a winding pinion 4 and a sliding pinion 6. The winding stem 2 is housed in a plate 7 and is arranged to occupy at least two axial positions, namely a first winding position in which the rotation of the winding stem in one direction (here clockwise) causes the winding of the movement barrel and the rotation the winding stem in the other direction (here counterclockwise) causes the winding of the automaton barrel as will be seen below, and a second setting position in which the rotation of the winding stem in both the clockwise and counterclockwise directions allows the setting of the time of movement, none of the first and second energy accumulators can then be armed regardless of the direction of rotation of the winding stem. In a manner known to those skilled in the art, the winding pinion 4 is rotatably mounted on a cylindrical portion of the winding stem 2. The sliding pinion 6 has a square hole and is slidably mounted on a corresponding square provided at the end of the winding stem 2. The sliding pinion 6 can thus slide between the winding position in which it meshes with the winding pinion 4 and the setting time setting position in which the sliding pinion 6 is separated winding pinion 4 and meshes with the time setting mechanism. The displacement of the sliding pinion 6 is provided by a mechanism comprising a pull rod and a rocker. All these elements and mechanisms are known to those skilled in the art and do not require a more detailed description.

Note however that unlike conventional winding mechanisms, the sliding pinion and the winding pinion do not mesh with a Breguet toothing but have opposite of each other straight edge teeth arranged to allow the driving of the winding pinion 4 by the sliding pinion 6 in both clockwise and counterclockwise rotation of the winding stem 2, said winding stem 2 and the sliding pinion 6 occupying the same axial winding position.

With particular reference to Figures 11 to 13 the straight edge teeth of the sliding pinion 6 and of the winding pinion 4 may be dog teeth. For this purpose, the winding pinion 4 and the sliding pinion 6 respectively have, in place of a Breguet toothing, teeth 8 in the form of crenellations ending in two inclined faces joining the top of the crenel and alternating with recesses 10. of complementary shape to that of the teeth 8 allowing their meshing by the engagement of the teeth 8 of one in the corresponding recesses 10 of the other. This form of dog-toed toothings allows the sliding pinion 6 to come to fit easily ("clutch") in the winding pinion 4, and to transmit more torque when in the winding position, as shown in FIG. the figure 13 . These claw teeth are also machinable without great strain. In a manner known per se, the winding pinion 4 also comprises a peripheral toothing 12 arranged to cooperate with the first and second clutch / disengagement devices as will be detailed below. The sliding pinion 6 also comprises a toothing of edge 14, opposite the jaw teeth to jaw 8, arranged to cooperate with the setting mechanism.

In accordance with the invention, and with reference to Figures 1 to 4 , the winding mechanism comprises a first clutch / clutch device 16 and a second clutch / clutch device 18 arranged on either side of the winding stem 2 relative to the plate 7, said first and second devices clutch / clutch 16 and 18 each cooperating with the winding pinion 4. For this purpose, the winding stem 2 is advantageously housed in the plate 7 so that the winding pinion 4 is operational on both sides. other of the winding stem 2 relative to the plate 7. This means that the winding pinion 4 is disposed in a housing provided in the plate 7 and the members around the winding pinion 4 are arranged so that the winding pinion 4 can mesh with each of the first and second clutch / clutch devices 16 and 18 placed on either side of the winding stem 2 relative to the plate 7.

• occupe une position d'embrayage pour embrayer le pignon de remontoir 4 et le premier accumulateur d'énergie tandis que l'autre des premier et second dispositifs d'embrayage/débrayage 16, 18 occupe une position de débrayage pour débrayer le second accumulateur d'énergie lorsque la tige de remontoir 2 est tournée dans un sens, et
• occupe une position de débrayage pour débrayer le premier accumulateur d'énergie tandis que l'autre des premier et second dispositifs d'embrayage/débrayage 16, 18 occupe une position d'embrayage pour embrayer le pignon de remontoir 4 et le second accumulateur d'énergie lorsque la tige de remontoir 2 est tournée dans l'autre sens.

In addition, the first and second clutch / clutch devices 16 and 18 are arranged so that one of the first and second clutch / clutch devices 16, 18:

• occupies a clutch position to engage the winding pinion 4 and the first energy accumulator while the other of the first and second clutch / clutch devices 16, 18 occupies a position of disengaging to disengage the second energy accumulator when the winding stem 2 is turned in one direction, and
• occupies a disengaging position to disengage the first energy accumulator while the other of the first and second clutch / disengagement devices 16, 18 occupies a clutch position to engage the winding pinion 4 and the second accumulator energy when the winding stem 2 is turned in the other direction.

According to the invention, one of the first and second clutch / disengagement devices 16, 18, in this case here arbitrarily the first clutch / clutch device 16, comprises a first crown gear 20 cooperating with the peripheral toothing. 12 of the winding pinion 4 and on which is mounted a first clutch rocker 22. Said first clutch rocker 22 carries at its free end a first driving pinion 24 arranged to be able to kinematically connect the first crown wheel 20 to the first accumulator of energy 26, here the barrel of movement. More particularly, the first driving pinion 24 is positioned on the first clutch rocker 22 and arranged on the one hand to mesh with the first crown wheel 20 and on the other hand to be able to mesh with a first ratchet 28 cooperating with the first energy accumulator 26. It is obvious that, in another variant not shown in which the winding of the barrel of movement is by the drum in order to rotate the barrel in the opposite direction, the first driving pinion will be arranged to mesh with the drum of said barrel.

• en position d'embrayage et lier cinématiquement le premier pignon entraineur 24 au premier rochet 28 du premier accumulateur d'énergie 26 puis, une fois le premier pignon entraineur 24 au contact du premier rochet 28 du premier accumulateur d'énergie 26, la première bascule d'embrayage 22 est empêchée de continuer à pivoter et le premier pignon entraineur 24 se désolidarise de la première bascule d'embrayage 22 grâce à la friction, permettant ainsi l'entrainement du premier pignon entraineur 24 par le pignon de remontoir 4 via la première roue de couronne 20 pour remonter le premier accumulateur d'énergie 26 lorsque la tige de remontoir 2 est tournée dans un premier sens, par exemple le sens horaire,
• en position de débrayage en éloignant le premier pignon entraineur 24 du premier accumulateur d'énergie 26 lorsque la tige de remontoir 2 est tournée dans un second sens inverse, dans ce cas le sens antihoraire.

Said first clutch rocker 22 is freely mounted on the axis of said first crown wheel 20 and the first driving pinion 24 is frictionally mounted on said first clutch rocker 22, so that as long as the first clutch rocker 22 clutch 16 does not occupy its clutch position, said first clutch rocker 22 and the first gear coach 24 pivot integrally with said first crown wheel 20 to pass:

• in the clutch position and kinematically bind the first driving pinion 24 to the first ratchet 28 of the first energy accumulator 26 and, once the first driving pinion 24 in contact with the first ratchet 28 of the first energy accumulator 26, the first latch clutch 22 is prevented from continuing to pivot and the first driving pinion 24 is disengaged from the first clutch rocker 22 thanks to the friction, thus allowing the first driving pinion 24 to be driven by the winding pinion 4 via the first crown wheel 20 for refitting the first energy accumulator 26 when the winding stem 2 is turned in a first direction, for example clockwise,
• in the disengaged position by moving the first driving gear 24 away from the first energy accumulator 26 when the winding stem 2 is rotated in a second opposite direction, in this case counterclockwise.

In the example described here, the first clutch / clutch device 16 is disposed on the movement side to reassemble the movement barrel.

On the other side of the plate 7, opposed to the movement, there is provided a board 30 on which are mounted the elements of the automaton mechanism, and in particular the second energy accumulator 27, here the automaton barrel, and the other of the first and second clutch / clutch devices 16, 18, here the second clutch / clutch device 18, as shown in FIG. figure 3 . Thus, in the variant shown, the first and second energy accumulators are arranged on either side of the winding stem 2 relative to the plate 7. It is obvious that in a variant not shown, the first and second second energy accumulators can be arranged on the same side, intermediate mobiles being then used to kinematically link each clutch / disengagement device to its associated energy accumulator.

The second clutch / clutch device 18 comprises an intermediate winding pinion 32 mounted on the chassis of the movement and cooperating with the peripheral set of teeth 12 of the winding pinion 4 which is arranged so that its peripheral toothing 12 is accessible and operational also from this side of the timepiece, that is to say, side board or PLC side. The second clutch / clutch device 18 also comprises a second crown wheel 34 cooperating with the winding pinion 4 via the intermediate winding pinion 32, and on which is mounted a second clutch lever 36. Said second rocker arm clutch 36 carries at its free end a second driving pinion 38 arranged to be able to kinematically connect the second crown wheel 34 to the second energy accumulator 27, here the automaton barrel. More particularly, the second drive gear 38 is positioned on the second clutch lever 36 and arranged on the one hand to mesh with the second crown wheel 34 and on the other hand to be able to mesh with a second ratchet 40 cooperating with the second energy accumulator 27. It is obvious that, in another variant not shown in which the arming of the automaton barrel is made by the drum in order to rotate the barrel in the opposite direction, the first driving pinion will then be arranged to mesh with the drum of said barrel.

In the example described here, the first and second energy accumulators 26, 27 are raised by their respective ratchet, anti-return mechanisms (not shown) such as ratchet, spring or jumper, known to those skilled in the art, being provided at the ratchet to prevent the ratchet from going back.

• en position d'embrayage et lier cinématiquement le second pignon entraineur 38 au second rochet 40 du second accumulateur d'énergie 27 puis, une fois le second pignon entraineur 38 au contact du second rochet 40 du second accumulateur d'énergie 27, la seconde bascule d'embrayage 36 est empêchée de continuer à pivoter et le second pignon entraineur 38 se désolidarise de la seconde bascule d'embrayage 36 grâce à la friction, permettant ainsi l'entrainement du second pignon entraineur 38 par le pignon de remontoir 4 via le pignon de remontoir intermédiaire 32 et la seconde roue de couronne 34 pour remonter le second accumulateur d'énergie 27 lorsque la tige de remontoir 2 est tournée dans le second sens, à savoir ici le sens antihoraire,
• en position de débrayage en éloignant le second pignon entraineur 38 du second accumulateur d'énergie 27 lorsque la tige de remontoir 2 est tournée dans le premier sens, à savoir ici le sens horaire.

Said second clutch lever 36 is mounted free on the axis of the second crown wheel 34 and the second driving pinion 38 is frictionally mounted on said second clutch lever 36, so that as long as the second clutch lever 36 clutch 18 does not occupy its clutch position, said second clutch lever 36 and the second gear coach 38 pivot jointly with said second crown wheel 34 to pass:

• in the clutch position and kinematically link the second driving gear 38 to the second ratchet 40 of the second energy accumulator 27, and then, once the second driving pinion 38 is in contact with the second ratchet 40 of the second energy accumulator 27, the second latch the clutch 36 is prevented from continuing to pivot and the second driving pinion 38 disengages from the second clutch lever 36 by virtue of the friction, thus enabling the second driving pinion 38 to be driven by the winding pinion 4 via the pinion intermediate winding device 32 and the second crown wheel 34 to refit the second energy accumulator 27 when the winding stem 2 is turned in the second direction, namely here the counterclockwise direction,
• in the disengaged position by moving the second drive pinion 38 away from the second energy accumulator 27 when the winding stem 2 is turned in the first direction, namely here the clockwise direction.

It is obvious that the directions of rotation of the winding stem described here are not limiting and that they can be reversed, the first energy accumulator can be raised by rotation of the winding stem in the counterclockwise direction. second energy accumulator is then raised by rotation of the winding stem in the clockwise direction.

In addition, it should be noted that the use of an intermediate winding gear is optional and will be adapted by the skilled person depending eg on the positioning and direction of rotation of the other components of the construction, including for example depending on the direction of rotation of the barrels. If the barrels must have opposite operating directions, the skilled person knows how to arrange their components (drum, spring, shaft) accordingly.

The operation of the winding mechanism according to the invention is as follows: with reference to Figures 5 to 7 when it is necessary to winding the movement barrel, the winding stem 2 is positioned in its axial winding position so that the sliding pinion 6 meshes with the winding pinion 4 as shown in FIG. figure 13 then the winding stem 2 is turned clockwise. This rotation of the winding stem 2 causes the rotation of the winding pinion 4 in the clockwise direction. Movement side, the winding pinion 4 meshes with the first crown wheel 20 to rotate it counterclockwise. The first clutch lever 22 and the first drive pinion 24 being integral due to the friction and the absence of torque transmission through the gear trains, and the first drive pinion 24 being engaged with the first ring gear 20 , the first clutch rocker 22 and the first driving pinion 24 pivot integrally with said first crown wheel 20 about its axis counterclockwise until the first driving pinion 24 comes into contact with the first ratchet 28. The first clutch / clutch device 16 is in the clutch position, as shown by the Figures 5 and 7 . The pivoting of the first clutch rocker 22 is now prevented, the first driving pinion 24 then disengages from the first clutch rocker 22 thanks to the friction, so that the rotation of the first crown wheel 20 driven by the winding pinion 4 now causes the rotation of the first drive pinion 24 which meshes with the first ratchet 28 for the winding of the movement barrel.

In parallel, board side or PLC side, the rotation of the winding pinion 4 in the clockwise direction causes the rotation of the intermediate winding pinion 32 in the counterclockwise direction. This rotation of the intermediate winding pinion 32 causes the rotation of the second crown wheel 34 in the clockwise direction. The second clutch lever 36 and the second drive pinion 38 being integral due to the friction and the absence of torque transmission through the gear trains, and the second drive pinion 38 being engaged with the second ring gear 34 , the second clutch lever 36 and the second drive pinion 38 pivot integrally with said second crown gear 34 about its axis in a clockwise direction to move said second drive gear 38 away from the second energy accumulator 27 as shown by the Figures 5 and 6 . The second clutch / clutch device 18 is then in the disengaged position so that the second energy accumulator 27 is not raised during the reassembly of the first energy accumulator 26 by rotation of the winding stem 2 in the clockwise.

To reassemble the second energy accumulator, here the automaton barrel, with reference to Figures 8 to 10 , the winding stem 2 is always positioned in its axial winding position so that the sliding pinion 6, which has not moved, always meshes with the winding pinion 4 as shown in FIG. figure 13 , then the winding stem 2 is rotated counterclockwise. This rotation of the winding stem 2 causes the rotation of the winding pinion 4 counterclockwise. Side plank or automaton, the rotation of the winding pinion 4 counterclockwise causes the rotation of the intermediate winding pinion 32 in the clockwise direction. This rotation of the intermediate winding pinion 32 causes the rotation of the second crown wheel 34 counterclockwise. The second clutch lever 36 and the second drive pinion 38 being integral due to the friction and the absence of torque transmission through the gear trains, and the second drive pinion 38 being engaged with the second ring gear 34 the second clutch lever 36 and the second drive gear 38 pivot integrally with said second ring gear 34 about its axis counterclockwise until the second drive gear 38 comes into contact with the second ratchet 40. The second clutch / clutch device 18 is in the clutch position as shown by the Figures 8 and 9 . Since the pivoting of the second clutch lever 36 is now prevented, the second drive pinion 38 then disengages from the second clutch lever 36 thanks to the friction, so that the rotation of the second ring gear 34 driven by the winding pinion 4 and the intermediate winding pinion 32 now causes the rotation of the second drive pinion 38 which meshes with the second ratchet 40 for the winding of the automaton barrel.

In parallel, on the movement side, the winding pinion 4 rotating counterclockwise meshes with the first crown wheel 20 to rotate it clockwise. The first clutch lever 22 and the first drive pinion 24 being integral due to the friction and the absence of torque transmission through the gear trains, and the first drive pinion 24 being engaged with the first ring gear 20 the first clutch lever 22 and the first drive gear 24 pivot integrally with said first ring gear 20 about its axis in a clockwise direction to move said first drive gear 24 away from the first energy accumulator 26 as shown by FIGS. Figures 8 and 10 . The first clutch / clutch device 16 is then in the disengaged position so that the first energy accumulator 26 is not raised during reassembly of the second energy accumulator 27 by rotation of the winding stem 2 in the anticlockwise.

Thus, the winding mechanism according to the invention allows a precise and reliable reassembly of two energy accumulators by the single rotation of the winding stem in both directions, the winding stem occupying the same axial position of winding.

Claims (9)

1. Winding mechanism of a timepiece comprising at least one first power accumulator (26) arranged such that it supplies a first mechanism with power and a second power accumulator (27) arranged such that it supplies a second mechanism with power, said winding mechanism including a winding stem (2), a winding pinion (4) and a sliding pinion (6) borne by said winding stem (2) and having straight toothings facing one another, arranged so as to allow the winding pinion (4) to be driven by the sliding pinion (6) in the two directions of rotation of the winding stem (2), said winding stem (2) and the sliding pinion (6) occupying the same axial winding position, characterised in that said winding stem (2) is housed inside a plate (7) such that the winding pinion (4) is operational on either side of the winding stem (2) relative to the plate (7) and in that the winding mechanism comprises a first and a second coupling/uncoupling devices (16, 18) disposed on either side of the winding stem (2) relative to the plate (7), cooperating with the winding pinion (4) and arranged such that one of said first and second coupling/uncoupling devices (16, 18) occupies a coupling position for coupling the winding pinion (4) and the first power accumulator (26), while the other of the first and second coupling/uncoupling devices (16, 18) occupies an uncoupling position for uncoupling the second power accumulator (27) when the winding stem (2) is turned in one direction, and occupies an uncoupling position for uncoupling the first power accumulator (26), while the other of the first and second coupling/uncoupling devices (16, 18) occupies a coupling position for coupling the winding pinion (4) and the second power accumulator (27) when the winding stem (2) is turned in the other direction.
2. Winding mechanism according to claim 1, characterised in that one of the first and second coupling/uncoupling devices (16, 18) comprises a first transmission wheel (20) cooperating with the winding pinion (4) and on which a first coupling lever (22) is mounted, bearing a first driving pinion (24) arranged such that it is able to kinematically connect the first transmission wheel (20) to the first power accumulator (26), said first coupling lever (22) being mounted such that it is free on the first transmission wheel (20) and the first driving pinion (24) being mounted frictionally on said first coupling lever (22) so as to pivot integrally with said first transmission wheel (20) into the coupling position in order to kinematically connect the first driving pinion (24) to the first power accumulator (26), then to allow the first driving pinion (24) to be driven by the first transmission wheel (20) in order to wind the first power accumulator (26), when the winding stem (2) is turned in a first direction, and so as to pivot integrally with the first transmission wheel (20) into the uncoupling position in order to move the first driving pinion (24) away from the first power accumulator (26), when the winding stem (2) is turned in a second inverse direction.
3. Winding mechanism according to one of claims 1 and 2, characterised in that the other of the first and second coupling/uncoupling devices (16, 18) comprises a second transmission wheel (34) cooperating with the winding pinion (4) and on which a second coupling lever (36) is mounted, bearing a second driving pinion (38) arranged such that it is able to kinematically connect the second transmission wheel (34) to the second power accumulator (27), said second coupling lever (36) being mounted such that it is free on the second transmission wheel (34) and the second driving pinion (38) being mounted frictionally on said second coupling lever (36) so as to pivot integrally with said second transmission wheel (34) into the coupling position in order to kinematically connect the second driving pinion (38) to the second power accumulator (27), then to allow the second driving pinion (38) to be driven by the second transmission wheel (34) in order to wind the second power accumulator (27), when the winding stem (2) is turned in the second direction, and so as to pivot integrally with the second transmission wheel (34) into the uncoupling position in order to move the second driving pinion (38) away from the second power accumulator (27), when the winding stem (2) is turned in the first direction.
4. Winding mechanism according to one of the preceding claims, characterised in that the straight toothings of the sliding pinion (6) and of the winding pinion (4) are dog clutch toothings.
5. Winding mechanism according to the preceding claim, characterised in that the sliding pinion (6) and the winding pinion (4) have respectively crenelated teeth (8) ending in two inclined faces that meet at the top and alternate with recesses (10) of complementary shape to that of the teeth (8), allowing the meshing thereof by engagement of the teeth (8) of one in the corresponding recesses (10) of the other.
6. Winding mechanism according to claim 2, characterised in that the first driving pinion (24) is arranged such that it is able to mesh with a first ratchet (28) cooperating with the first power accumulator (26) when the first coupling/uncoupling device (16) is in the coupling position.
7. Winding mechanism according to claim 3, characterised in that the second driving pinion (38) is arranged such that it is able to mesh with a second ratchet (40) cooperating with the second power accumulator (27) when the second coupling/uncoupling device (18) is in the coupling position.
8. Winding mechanism according to any of the preceding claims, characterised in that the first and second power accumulators (26, 27) are disposed on either side of the winding stem (2) relative to the plate (7).
9. Timepiece comprising at least one first power accumulator (26) arranged such that it supplies a first mechanism with power, a second power accumulator (27) arranged such that it supplies a second mechanism with power, and a winding mechanism according to one of the preceding claims.

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