CH708817A2 - mechanical watch movement with torque feedback in the barrel by drawing on the work train. - Google Patents

Abstract

Mechanical clockwork movement, comprising at least one energy storage means (2) fed at the input by a ratchet driven by at least one winding mechanism and supplying a finishing gear train with output. It comprises first energy sensing means (6) connected to at least one mobile of said work train by at least a first elastic link, said first energy sensing means (6) cooperating with at least one mobile of ratchet drive (8) engaged with said ratchet for supplying said energy storage means (2) by reinjecting a portion of the energy picked up by said energy sensing means (6), said at least one mobile ratchet drive being disengageable under the action of at least one disengaging mechanism (9) active during operation of said at least one winding mechanism.

Description

Description

Field of the invention

The invention relates to a mechanical watchmaking movement, comprising at least one energy storage means fed into the input by a ratchet driven by at least one winding mechanism and supplying outputting a gear train.

The invention also relates to a timepiece comprising at least one such movement.

The invention relates to the field of mechanical clockwork movements.

Background of the invention

The power reserve of the watch mechanisms is a constant concern, and amplified by the number of complications and energy consuming mechanisms on a caliber. To increase the power reserve, it is possible to decrease the frequency of the oscillator, or the power at the exhaust, and / or to increase the power available at the barrel or barrels. In all cases, it is necessary to change the finishing gear, the adjustment, as well as the mainspring, which represents a significant modification, and expensive, of an existing caliber. In addition, the available space rarely allows expansion of the barrel, and it must then be restricted to an action on the regulator system.

Summary of the invention

The object of the invention is to perform a torque feedback in the barrel by a levy on the finishing train, to increase the power reserve of an existing movement, decreasing the power setting to the exhaust without retouching the base wheel.

For this purpose, the invention relates to a mechanical clockwork movement, comprising at least one energy storage means fed into the input by a ratchet driven by at least one winding mechanism and feeding an output of a gear train , characterized in that it comprises first energy capture means connected to at least one mobile of said work train by at least a first elastic connection, said first energy sensing means cooperating with at least one mobile device. ratchet drive engaged with said ratchet for supplying said energy storage means by reinjecting a portion of the energy picked up by said energy sensing means.

According to a feature of the invention, said at least one ratchet movable movable being disengageable under the action of at least one active disengaging mechanism during operation of said at least one winding mechanism.

The invention also relates to a timepiece comprising at least one such movement.

Brief description of the drawings

Other features and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, in which: FIG. 1 schematically shows in plan view a watch comprising a mechanical movement, which comprises a mechanical energy accumulator in the form of a barrel, and a regulating mechanism, this movement being in an improved power reserve with a mechanism reinjection of energy according to the invention; fig. 2 represents, schematically, partially and in section along the line EE, the movement of FIG. 1, and shows in particular the finishing gear; fig. 3 represents, schematically, partially and in section along the line BB, the movement of FIG. 1, and shows in particular the automatic gear; fig. 4 represents, schematically, partially and in section along the line DD, the movement of FIG. 1, and in particular shows manual winding; fig. 5 represents, schematically, partially and in section along the FF line, the movement of FIG. 1, and shows in particular the feedback mechanism; fig. 6 shows schematically, partially and in section along the line AA, the movement of FIG. 1, and in particular shows the ratchet drive wheel; fig. 7 shows schematically, partially and in section along the line CC, the movement of FIG.

1, and shows in particular the work of the feedback mechanism; fig. 8 is a diagrammatic perspective view of an intermediate mobile comprising the energy feedback mechanism, this intermediate mobile comprising a partial intermediate wheel.

2 free pivotally pivoted by elastic return means to a shaft integral with a first pinion; fig. 9 is a diagrammatic perspective view of the intermediate wheel of FIG. 8; fig. 10 is a diagrammatic perspective view of the intermediate wheel of FIG. 8 equipped with its elastic return means to an angular position of rest relative to the shaft; fig. 1 1 is a diagrammatic perspective view of an assembled ratchet drive according to the invention, comprising, on either side of a shaft, a first partially pivotally free wheel connected by resilient return means to this shaft, and a second wheel also partially free pivotally connected by elastic return means to the same shaft; figs. 12 to 18 show, schematically and in plan, different variants of the elastic return means equipping the first wheel and / or the second wheel of FIG. 1 1; fig. 19 represents, in the form of a block diagram, the energy reinjection system according to the invention.

Detailed Description of the Preferred Embodiments

The object of the invention is to perform a torque feedback in an energy storage means, including at least one barrel, by a sample on the gear train 5 of a mechanical watch movement 1 a watch 100, to increase the power reserve of an existing movement, decreasing the power setting in the exhaust, without retouching the base wheel.

For simplification the invention is here described for the non-limiting case where the energy storage means is a cylinder 20. It is understood that the invention is applicable to other energy storage means: several barrels linear elastic means, physico-chemical transformation of energy by hydrides or the like, or the like.

To reduce the power to the exhaust, it is theoretically possible to take a portion of the torque directly on the gear train. This additional torque can be directly reinjected into the barrel to increase its capacity.

The barrel 20 is equipped with a ratchet 3. This ratchet 3 receives energy from a manual winding mechanism 40, or / and an automatic winding mechanism 45, and / or a mechanism reinjection according to the invention, and / or any additional means of supply of energy, such as solar energy converter, or other, and recharges the cylinder with the energy it receives.

The barrel 20 transmits torque to a finishing gear 5. A first portion of this torque is transmitted to a conventional exhaust mechanism and not detailed here. A second complementary part of this pair is extracted by first energy capture means 6 according to the invention, and transferred to ratchet 3.

This reinjection principle seems relatively simple in appearance, because it is sufficient to take a certain torque on the work train 5 and use the excess of this torque to raise the cylinder 20. However, it involves a number of problems to solve.

First, the torque must be taken as close as possible to the barrel 20 because the efficiency of the system depends mainly on the number of mobiles needed for its operation. If we raise the torque from a fast-rotating wheel, for example the second wheel, it will take a significant multiplicative gear to be able to raise the barrel 20.

In a conventional movement 1, the torque on the train is transmitted by the drum 21 of the cylinder 20. It is therefore not possible to reinject torque through the toothing 22 of the drum 20, because the speed is defined by the 5. It is therefore necessary to reinject the torque directly by the ratchet 3. Therefore, it is necessary to install a unidirectional or disengageable system between the gearing of the reinjection system and the ratchet 3. Fault of such a system providing safety, during a manual or automatic winding, the torque given on the ratchet 3 would be transmitted directly to the train by the feedback system, which would cause an increase in the torque on the exhaust, resulting in a massive increase in amplitude and rebate.

In the case of a movement 1 with an automatic winding mechanism 45, the ratchet 3 can be driven at any time by a movement of the automatic winding mass 46, oscillating or the like. The mass 46 is, in the embodiment illustrated by the figures, carried by an automatic device frame 15, and a toothing 47 causes the reassembly through a first inversion wheel 48 and a second inversion wheel 49. The latter attacks a board 17 of a reduction mobile 16 provided with a pinion 18, arranged to drive a toothing 89 of a second wheel 86 of a ratchet drive wheel, specific to the invention, which will to be exposed further.

At this time, the manual winding mechanism 40 is automatically disengaged. This implies that for a period of time, the energy provided by the feedback system is lost, until the teeth between the ratchet and the clutch wheel are again engaged. If the watch 100 is worn by a so-called strong carrier (which makes the automatic winding mechanism 45 work a lot), the reinjection system has only a limited influence on the

3 power reserve of the movement, since in this case the energy reserves are at the maximum level, as long as the watch 100 is worn. In addition, if the system is not engaged, all the torque remains on the gear train. After a while, there is a risk that the amplitude increases until it reaches the rebate.

The points mentioned above demonstrate the complexity of this reinjection system.

The integration of a torque feedback mechanism in a movement 1 with manual winding mechanism 40 is entirely justified because the gain in power reserve is directly observed by the user. In addition, the reinjection system is still engaged with the ratchet 3, except at the time of reassembly by a rod 41. In principle, a user with a manual movement back his watch only 3 to 4 times a week, depending of the power reserve of this one. The loss of potential energy during this period is therefore not perceptible.

The integration of a torque feedback mechanism in a movement 1 with automatic winding mechanism 45 is useful when the watch 100 is not worn, for example if it is deposited for several days during the weekend. . At this moment, an increase of the power reserve is appreciable so as not to have to put up his watch on Monday morning.

The architecture of the mechanism according to the invention is presented below, the calculation justifications will be presented later in the presentation.

The invention therefore relates to a mechanical movement 1 of watchmaking, comprising at least one energy storage means 2, in particular a cylinder 20.

This barrel 20 comprises a drum 21 with a toothing 22, a cover 24, a shaft 25.

This energy storage means 2 is fed at the input by a ratchet 3 driven by at least one winding mechanism 4, and it feeds at the output of a finishing train 5. The ratchet 3 has a toothing 31, means 23 to cooperate with the shaft 25, and a fastener 32. The finishing gear 5 conventionally comprises a mobile of average 51 with a pinion 52 and a board 53, a floor of minutes 54 with a toothing 59, a mobile second 55 with a pinion 56 and a board 57, and a hour wheel 58.

The various components of the movement 1 are housed, as the case and as visible in the various figures, on a dial support plate 1 1, a gear train 12, a lower automatic device 13 bridge, a bridge barrel 14, the automatic device frame 15, a winding bridge 19.

According to the invention, this movement 1 comprises first energy sensing means 6, which are connected to at least one mobile of the finishing train 5 by at least a first elastic connection 7.

These first energy sensing means 6 cooperate with at least one ratchet movable wheel 8, which is engaged with the ratchet 3, for supplying the energy storage means 2 by reinjection of a part energy taken by the energy collection means 6.

Advantageously, this at least one mobile ratchet drive 8 is disengageable under the action of at least one disengaging mechanism 9 active during operation of the at least one winding mechanism 4.

Advantageously, the first elastic connection 7, forming disengagement mechanism 7, is interposed between the energy sensing means 6 and the ratchet 3.

According to the invention, the energy sensing means 6 are located, downstream of the energy storage means 2, at the level of at least one intermediate mobile device 60.

This intermediate mobile 60, shown in FIG. 8, comprises, coaxial about a shaft 68, and on either side of a first pinion 61 driven by the energy storage means 2, in particular the toothing 22 of a drum 21 of a barrel 20:

- On the one hand an intermediate wheel 62 connecting with a mobile of the work train 5, this intermediate wheel 62 being pivotally secured to the first gear 61,

- And secondly an additional intermediate wheel 63 connection, having a toothing 64, and meshing with such a ratchet drive wheel 8, the additional intermediate wheel 63 being pivotally mounted on a shaft 68 that includes the intermediate mobile 60 and linked to this shaft 68 by resiliently rotating return means or at least one main spring 67 constituting the first elastic connection 7 and inserted in a housing 65 of the wheel 63 and in a housing 66 of the intermediate mobile 60.

The additional intermediate wheel 63 is shown in FIG. 9, in an advantageous embodiment which comprises a recess 630 for the housing of a main spring 67. This spring 67 comprises an outer turn 651 housed in this recess 630 in which it is pivotally stopped by the cooperation of pins 650 spring 67 with notches 65 of the wheel 63, or vice versa. The spring 67 comprises at least one spiral strand 654 which joins this outer turn 651 with an inner turn 652, which comprises pivoting stop means 653 on the shaft 68 of the intermediate mobile 60. Here these stop means 653 are a female square cooperating with a male square 683 of the shaft 68. During its operation, the additional intermediate wheel 63 pivots freely on the axis 68 of the intermediate wheel 62, driven by the spring 67 whose inner turn 652 is thus fixedly connected to the axis 68 of the mobile 60.

The geometry of the spirally shaped spring 67 defined by the calculation is shown in FIG. 10. In order to maximize the number of winding turns of the spring, the turn must be as long as possible while respecting the manufacturing constraints of the "LIGA", in the preferred case of an embodiment of this type. The geometry is optimized so as to guarantee a calculated armature equivalent to about 18 °. For a higher torque, the outer point of the attachment of the turn in the center can certainly come in contact with the inner point of the attachment of the turn on the ring (circle wheel), which is not a problem and even allows to partially relieve the stresses in the turn.

In the usual manner, at least one winding mechanism 4 of the movement 1 is a manual winding mechanism 40 actuated by the user. And at least one such ratchet drive wheel 8 according to the invention comprises at least one additional ratchet drive wheel 82, which is coaxial with a pinion 81 driving the ratchet 3. This first ratchet drive wheel additional 82, carrier of a toothing 85 arranged to cooperate with the toothing 64 of the additional intermediate wheel 63, is pivotally mounted on a bearing 83 of a shaft 80 that includes the ratchet driving mobile 8. The first wheel of additional ratchet drive 82 is connected to this shaft 80 by first resiliently rotating return means or at least a first spring 84 constituting such disengaging means 9, during operation of the manual winding mechanism 40 actuated by the user . Such a first additional ratchet drive wheel 82 is visible in the lower part of a more complex mobile illustrated in FIG. 1 1.

Preferably, some of these disengaging means 9, constituted by the first elastic return means in rotation or by the at least one first spring 84, exert on the first additional ratchet drive wheel 82 a force of friction, the torque of which is different depending on the direction of relative pivoting between these disengaging means 9, and the first additional ratchet wheel 82.

In particular, the first spring 84 is thus arranged to generate a unidirectional pivoting direction without play of the first additional ratchet drive wheel 82 relative to the shaft 80 of the ratchet drive wheel 8, so as to prevent any transmission of a torque to the gear 5 during a reassembly of the movement 1 by at least one such winding mechanism 4.

When at least one such winding mechanism 4 is an automatic winding mechanism 45, at least one such ratchet drive wheel 8 further comprises a second additional ratchet wheel 86, as shown in FIG. . 11. This second additional ratchet drive wheel 86, carrier of a toothing 89 arranged to cooperate with the pinion 18 of the reduction wheel 16, is pivotally mounted on a bearing 87 of the shaft 80, and is connected to this shaft 80 by second elastic return means of rotation or at least a second spring 88 constituting such disengaging means 9, during operation of the automatic winding mechanism 45. In short, it has, on one side of the mobile ratchet drive 8, the feedback system, and on the other hand, automatic winding, which explains the need for a disengagement system between the two torque inputs.

Preferably, some of these disengaging means 9, constituted by these second elastic return means of rotation or by the at least one second spring 88, exert on the second additional ratchet wheel 86 a force of friction whose moment of the torque is different according to the direction of relative pivoting between the disengaging means 9, and the second additional ratchet wheel 86.

In particular, the second spring 88 is thus arranged to generate a unidirectional pivoting direction without play of the second additional ratchet drive wheel 86 relative to the shaft 80 of the ratchet drive wheel 8, so as to prevent any transmission of a torque to the work train 5 during a reassembly of the movement 1 by the manual winding mechanism 40 actuated by the user, or during operation of the first energy sensing means 6.

The design of the ratchet drive mobile 8 thus takes into account the various functions to be fulfilled:

transmitting the torque of the gear of the automatic winding mechanism 45 to ratchet 3;

- transmit the torque of the feedback system;

- Decoupling the torque transmission between the two systems, which requires the use of unidirectional wheels.

It is important that, during a winding by the automatic winding mechanism 45, the torque on the mobile does not cause the feedback system, because, failing that, the additional torque on the finishing gear by the The intermediary of the feedback system may cause a rebate. In the other direction, during the drive by the feedback system, it is necessary to avoid driving all the wheels of the automatic winding mechanism 45 to the ratchet wheels, in order to minimize the losses.

FIG. 1 1 shows the mounted ratchet drive wheel, consisting of five parts: an axis 80, preferably a 20AP steel neck, the first additional ratchet wheel 82 and the second additional ratchet wheel 86, which pivot freely, and the first spring 84 and the second spring 88 which ensure the drive or non-driving of these wheels.

As regards the first additional ratchet drive wheel 82 and the second unidirectional additional ratchet drive wheel 86, preferably made of hardened copper-beryllium (CuBe), their function is to drive the 80 axis when they undergo a torque from either the automatic winding mechanism 45 or the feedback system. However, they must not transmit a couple when they

5 are driven by the axis 80 (disengaging system between the two wheels). In addition, the wheel 82 or 86 must have no dead angle, unlike a ratchet wheel, for example. In addition, the teeth 85 and 89 of these wheels 82 and 86 are optimized to minimize gearing. The very different behavior of each spring 84, 88, according to the direction of the torque applied to it can be simplified in a first "free" direction and a second "friction" drive direction. However, even in the so-called free direction of the spring, there is a small friction between the spring and the wheel concerned, because of a slight preload applied to the spring on its outer diameter, which implies that the wheel will be driven by this weak friction torque, and will turn up to come catch the game with the next wheel or pinion.

The two wheels 82 and 86 are preferably designed to receive the same spring, which limits the number of components. In addition, their pivot diameters are identical. This allows to have the same size for the attachment of the spring in the center on the drive, including hexagon, axis 80.

The first 84 or second 88 flexible spring has the function of driving the axis 80 when working in blocking direction. In the case where the axis 80 drives a spring, it should not drive the corresponding wheel. Preferably, the friction torque is minimized and the locking torque is maximized.

It is understood that such a disengagement system is essential to avoid force feedback by the feedback train, during a manual or automatic winding of the watch. The ratchet drive wheel 8 forms a unidirectional wheel whose operation resembles a reversing ratchet wheel. The mobile 8 represents a big improvement over the known inverters, because it is much less bulky, and therefore easier to implement in the immediate vicinity of the ratchet 3. The mobile 8 according to the invention has no blind spot, this which allows its mounting in an automatic movement.

Figs. 12 to 18 illustrate various non-limiting geometries of springs which are applicable to both the first spring 84 and the second spring 88. FIG. 12 shows more particularly the first spring 84 housed in the first additional ratchet drive wheel 82, and FIGS. 13 to 18 the second spring 88 housed in the second additional ratchet drive wheel 86. Their attachment to the corresponding wheel is based on friction: an outer turn 841, respectively 881, the first spring 84, respectively the second spring 88 , cooperates with a housing 820, respectively 860, of the wheel 82, respectively 86, in which it is held by friction at its periphery or / and lugs 84A, respectively 88A that includes said first spring 84, respectively second spring 88. The inner part of each spring, 842, respectively 882, cooperates with the shaft 80, by a female part 840, respectively 880, of the first spring 84, respectively of the second spring 88, of profile complementary to a male portion 800 of the tree 80.

The particular profile of the illustrated springs, with an asymmetric stiffness of at least one arm 843, respectively 883, joining the inner portion of each spring, 842, respectively 882, to its outer portion 841, respectively 881, allows applying a torque with a high moment differential, depending on whether the relative pivotal movement between the shaft 80 and the respective wheel, is in one direction or the other. The ratio of the torque exerted in one direction with respect to the other is greater than 3; depending on the shape of the spring, the sections used, and the pairs of materials present, this ratio can be notably increased, in particular beyond a factor of 10.

In FIGS. 12 and 13, the profile of the spring is closed: the inner part of each spring, 842, respectively 882, has the shape of a rhombus centered on the shaft 80, one of the ends A of the rhombus constitutes the beginning of the outer part 841, respectively 881, which is circular in almost a complete turn, before winding on itself at point C and forming an arm 843, respectively 883, in a circular sector of about a half-turn, radius less than that of the outer part, clinging to point B at the other end of the symmetrical rhombus at the first end A.

In FIG. 14, the profile of the spring is open: the inner part, 842, respectively 882, has the shape of a disk extended on a radius by a triangle, whose distal tip E is the start of an arm 843, respectively 883, in a circular sector of about one half-turn, before winding on itself at the point F and forming therein the outer portion 841, respectively 881, which is circular in almost one complete revolution, of radius greater than that of the arm, before stopping at a distal end G.

In FIG. 15, the profile of the spring is open: the inner part, 842, respectively 882, has the shape of a disc extended on a radius by a triangle, whose distal tip H constitutes the start of an arm 843, respectively 883, in a spiral increasing about a half-turn to the point I where starts an outer portion 841, respectively 881, circular, before stopping at a distal end J, after about a turn and a quarter with respect to the point H.

In FIG. 16, the profile of the spring is open, the spring having two symmetrical strands: the inner part, 842, respectively 882, has the shape of a disc which is hooked in K, N, an arm 843, respectively 883, spiral increasing about three-quarters of a turn to the point L, P, where starts an outer portion 841, respectively 881, circular one-half turn, before stopping at a distal end M, Q.

In FIG. 17, the profile of the spring is closed, and comprises a mesh with a pitch of 120 °: the inner part, 842, respectively 882, has the shape of a disc whose part R at point R an arm 843, respectively 883, substantially radial but curved, which joins at point S a rope 885 which joins two circular sectors of larger diameter, of which a sector TU forming an outer portion 841, respectively 881, the spring starting at point U on another rope 885

6 making about 120 ° with the previous, and joining at point V another radial arc similar to the first arc, the point V being the conjugate of the starting point S.

In FIG. 18, the profile of the spring is open, the spring having two symmetrical strands: the inner part, 842, respectively 882, has the shape of a disc to which a radial arm 886 of strong section is attached in W, up to a point X of which part at right angle arm 843, respectively 883, of smaller section than the radial arm 886, to a distal end Y periphery of the wheel.

These springs of Figs. 12 to 18 can be achieved by stamping, or, for those with very fine strands, in a "LIGA", "DRIE" or similar manufacturing.

According to the invention, the main spring 67 of the intermediate wheel 60 is advantageously sized and arranged to catch the clearance between the additional intermediate wheel 63 and the additional ratchet wheel 82.

In a particular embodiment, the movement 1 comprises at least one regulator member 90 to balance, and the energy sensing means 6 take a constant mechanical torque on the work train 5 when this regulator member 90 operates. According to the invention, this balance is dimensioned more weakly than would be the same movement 1 lacking energy sensing means 6, so as to maintain a sufficient oscillation amplitude to its proper operation.

In a particular variant, the movement 1 comprises at least one regulating member 90 to balance, and at least one such winding mechanism 4 is an automatic winding mechanism 45, and the energy sensing means 6 take a couple mechanically steadily on the work train 5 only when the movement 1 is maintained in a fixed position in space and when the automatic winding mechanism 45 is inactive, so as to then reduce the amplitude of oscillation of the balance and to increase the power reserve of movement 1.

Preferably, in the movement 1, the winding mechanism 4 comprises a manual winding mechanism 40, which comprises a rod 41 actuated by the user and which is arranged to drive in an axial position of winding of the rod 41 and in a winding direction of rotation which is printed to it by the user, a sliding pinion 43 arranged to mesh with a winding pinion 42 for driving a crown gear 44 meshing with the ratchet 3. According to the invention , the crown wheel 44 is arranged to cooperate with a pawl 31 comprising means of catching back of gear between the ratchet 3 and the crown wheel 44 during a maneuvering of the rod 41.

The invention also relates to a timepiece 100, including a watch, comprising at least one such movement.

The mechanism according to the invention must make up the game created in the reinjection system under the action of the automatic winding, before continuing to drive the ratchet, while avoiding all the torque goes through the finishing gear and then causes rebate. This is possible when the torque take on the finishing gear is constant when the movement is running. As regards the energy level, then decreases the power required for the balance, by the constant torque torque of the finishing gear. This implies a downsizing of the pendulum, to ensure a satisfactory amplitude. The dimensioning of the balance corresponds directly to the reduction of torque taken by the reinjection system. In the variant illustrated in the figures, we go from a basic movement with an oscillator that has a control power of 3100 erg / s, to a modified movement which has a control power of 1120 erg / s. This represents a decrease of the inertia of 16mgxcm2 to 14 mgxcm2, with correlatively a decrease of the frequency from 4 Hz to 3 Hz.

When wearing an automatic movement watch, the movement does not need an increase in the power reserve. On the other hand, this autonomy becomes important at the moment when the user deposits his watch. Therefore, it becomes interesting to increase this power reserve by the feedback system. We can then, for a self-winding watch, consider not to catch the game when wearing the watch. By cons, when it is deposited after a certain time that corresponds to the catching of this game (and which may be different depending on the carrier), a part of the torque of the work train is taken by the feedback system, which allows to increase the power reserve in proportion to the couple taken. It retains the entire torque on the gear train when wearing. The balance remains identical to the balance of the standard movement (without reinjection system). By cons, when depositing the watch and when the feedback system starts, the amplitude of the pendulum will decrease proportionally to the torque taken for reinjection. But in this case, the decrease in amplitude, which slightly alters the chronometric performance of the watch during a period of non-use, allows to spend several days without stopping the movement, which would be impossible without the reinjection system according to the invention.

The gear set retrofit system makes it possible to compensate for the backlash caused during automatic winding, which makes it possible to ensure permanent contact with the toothing of the ratchet even when it is driven. The use of a unidirectional wheel without play at the intermediate mobile 60 is a good solution: it turns freely in one direction and blocks in the other, all with a very low dead angle. Regarding the gear set, it is still possible to use a tooth geometry with a reduced clearance, or a no-play toothing comprising flexible teeth elements.

The mechanism according to the invention satisfies the following criteria:

7

Claims (15)

- system safety during operation; - simplicity of realization and implementation in an existing movement; - system reliability for both manual and automatic movement; - optimal reinjection efficiency by minimizing losses. The solution without blind spots can maximize the efficiency in a self-winding movement. The release system by a unidirectional wheel meets the requirements of simplicity of implementation and realization. This makes it possible to limit the number of components and their complexity. The catch-up and blocking functionalities are ensured each time directly by a single component. claims 1. Mechanical movement (1) watchmaking, comprising at least one energy storage means (2) fed at the input by a ratchet (3) driven by at least one winding mechanism (4) and supplying a gear output finisher (5), characterized in that it comprises first energy sensing means (6) connected to at least one mobile of said finishing train (5) by at least a first elastic connection (7), said first energy harvesting means (6) cooperating with at least one ratchet drive wheel (8) engaged with said ratchet (3) for supplying said energy storage means (2) by reinjection of a portion of the energy taken by said energy sensing means (6). 2. Movement (1) according to claim 1, characterized in that said at least one ratchet driving wheel (8) being disengageable under the action of at least one clutch mechanism (9) active during operation of said at least one winding mechanism (4). 3. Movement (1) according to claim 2, characterized in that said first elastic connection (7) forming a disengaging mechanism is interposed between said energy sensing means (6) and said ratchet (3). 4. Movement (1) according to one of the preceding claims, characterized in that said energy sensing means (6) are located, downstream of said energy storage means (2), at least an intermediate wheel (60) which comprises, coaxially, and on either side of a first pinion (61) driven by said energy storage means (2), on the one hand an intermediate wheel (62) of connection with a mobile of said work train (5), said intermediate wheel (62) being pivotally secured to said first gear (61), and secondly an additional intermediate wheel (63) of engagement meshing with a said mobile of ratchet drive (8), said additional intermediate wheel (63) being pivotally mounted on a shaft (68) which comprises said intermediate mobile (60) and connected to said shaft (68) by means of elastic return in rotation or at least one main spring (67) constituting said first link elastic (7). 5. Movement (1) according to one of the preceding claims, characterized in that at least one said winding mechanism (4) is a manual winding mechanism (40) actuated by the user, and in that at least one said ratchet drive wheel (8) comprises at least one additional ratchet drive wheel (82) coaxial with a pinion (81) engaging said ratchet (3), said first additional ratchet drive wheel (82) ) being pivotally mounted on a shaft (80) that comprises said ratchet movable movable (8) and connected to said shaft (80) by first resiliently rotating return means or at least a first spring (84) constituting said disengaging means (9), during operation of said manual winding mechanism (40) actuated by the user. 6. Movement (1) according to the preceding claim, characterized in that said disengaging means (9), constituted by said first means of resilient return in rotation or by said at least one first spring (84), exert on said first additional ratchet drive wheel (82) a friction force whose torque moment is different in the relative pivoting direction between said clutch means (9) and said first additional ratchet drive wheel (82). 7. Movement (1) according to claim 5 or 6, characterized in that said first spring (84) is arranged to generate a unidirectional swing direction without play of said first additional ratchet wheel (82) relative to said shaft (80) of said ratchet drive wheel (8), so as to prevent transmission of a torque to said wheel (5) during reassembly of said movement (1) by at least one said winding mechanism (4); ). 8. Movement (1) according to one of claims 5 to 7, characterized in that at least one said winding mechanism (4) is an automatic winding mechanism (45), and in that at least one said mobile d ratchet drive (8) further includes a second additional ratchet drive wheel (86), said second additional ratchet drive wheel (86) being pivotally mounted on said shaft (80) and connected to said shaft (80) by second resilient means of rotation in rotation or at least a second spring (88) constituting said disengaging means (9), during operation of said automatic winding mechanism (45). 9. Movement (1) according to the preceding claim, characterized in that said disengaging means (9), constituted by said second elastic return means in rotation or by said at least one second spring (88), 8 exert on said second additional ratchet drive wheel (86) a friction force whose moment of torque is different in the direction of relative pivoting between said disengaging means (9) and said second ratchet drive wheel additional (86). 10. Movement (1) according to claim 8 or 9, characterized in that said second spring (88) is arranged to generate a unidirectional pivoting direction without play of said second additional ratchet wheel (86) relative to said shaft (80) of said ratchet driving wheel (8), so as to prevent any transmission of a torque to the wheel (5) during a reassembly of said movement (1) by said manual winding mechanism (40) actuated by the user, or during operation of said first energy sensing means (6). 1 1. Movement (1) according to one of claims 5 to 10, characterized in that said main spring (67) is arranged to catch the clearance between said additional intermediate wheel (83) and said drive wheel of additional ratchet (82). 12. Movement (1) according to one of the preceding claims, characterized in that said movement (1) comprises at least one regulating member (90) rocker, and in that said energy harvesting means (6) sample a mechanical torque steadily on said work train (5) when said regulating member (90) is operating, and in that said balance is dimensioned more weakly than would be the same said movement (1) devoid of said pickup means d energy (6), so as to maintain a sufficient oscillation amplitude to its proper operation. 13. Movement (1) according to one of claims 1 to 12, characterized in that said movement (1) comprises at least one regulating member (90) to balance, and in that at least one said winding mechanism (4 ) is an automatic winding mechanism (45), and in that said energy sensing means (6) take a constant mechanical torque on said work train (5) only when said movement (1) is maintained in a fixed position in space and when said automatic winding mechanism (45) is inactive, so as to reduce the amplitude of oscillation of said balance and increase the power reserve of said movement (1). 14. Movement (1) according to one of the preceding claims, characterized in that said winding mechanism (4). comprises a manual winding mechanism (40), which comprises a rod (41) actuated by the user and which is arranged to drive, in an axial position of winding of said rod (41) and in a winding direction of rotation which it is printed by the user, a sliding pinion (43) arranged to mesh with a winding pinion (42) driving a crown wheel (44) meshing with said ratchet (3), said crown wheel (44) being arranged to cooperate with a pawl (31) having means of catching back of gear between said ratchet (3) and said crown wheel (44) during a maneuver of said rod (41). 15. Timepiece (100) comprising at least one movement (1) according to one of the preceding claims. 9