CH712597B1 - Mechanism for a watch movement comprising two regulating organs. - Google Patents

Abstract

The invention relates to a mechanism (100) for a watch movement, comprising: an energy source (1), a first drive train (RV1) connecting the energy source (1) to a first regulating member (O1 ), a second drive train (RV2) connecting the energy source (1) to a second regulator member (O2), the second regulator member (O2) having an operation different from the first regulator member (O1), a mobile output (S) used to drive the time display, adapted to be kinematically connected to both the first drive train (RV1) and the second drive train (RV2), the mechanism (100) being arranged so that the time display is driven alternately, and with the same speed by the operation of the first regulator member (O1) or by the operation of the second regulator member (O2) and in which the first regulator member (O1 ) has a first frequency (f1) and the second regulator (O2) has a second frequency (f2) different from the first frequency (f1).

Description

Technical area

The present invention relates to a mechanism for a watch movement comprising two regulators, such as oscillators, which allows the adaptation of the driving energy.

State of the art

[0002] Watch movements with several regulating organs have been known for a long time (patent CH156801 of 1931) and are used for various reasons. By regulating member is meant a regulating system comprising a time base, such as a sprung balance oscillator, and a counting device such as an escapement. For example, the use of two permanently coupled oscillators, driven by a single barrel, aims mainly to improve the running of a watch by averaging the deviations of each oscillator or by giving each oscillator compensatory qualities with regard to disturbances. exterior (temperature, positions, ..).

[0003] Some movements have two regulators, driven by a single energy source, intended to operate alternately. This is the case of the movement presented in document EP1864190, which allows alternating day and night operation. Indeed, the document EP1864190 describes a solution in which a single energy source in the form of a barrel alternately drives one then the other among two identical regulating bodies (carousels or vortices), and this with an automatic rocker. every twelve hours carried out by means of a suitable return system.

[0004] Other movements have two separate cogs, each having its motive power, its cog and its oscillator. The first gear can be dedicated to displaying the time and the second gear can be sized for a specific application. This dissociation makes it possible not to disturb the first gear and therefore the precision of the time display.

The above mechanisms do not allow, or little, to modulate the driving energy of a single source of energy to drive two separate oscillators, different.

Brief summary of the invention

An object of the present invention is to provide a movement for a timepiece free from the limitations of known movements.

Another object of the invention is to provide a movement for a timepiece with two regulating members, such as oscillators, which are different and which are intended to be able to operate in a decoupled manner: when a regulating member is active, the other is at rest.

[0008] According to the invention, these goals are achieved in particular by means of a mechanism for a watch movement, comprising a source of energy, a first drive train connecting the source of energy to a first regulator member, a second drive train connecting the energy source to a second regulator member, the second regulator member having an operation different from the first regulator member, an output mobile used to drive the time display, capable of being kinematically connected both to the first drive train and to the second drive train, the mechanism being arranged so that the time display is driven alternately, and at the same speed, by the operation of the first regulator member or by the operation of the second regulator member in which the first regulator member has a first frequency and the second regulator member has a second frequency different from the first frequency.

This solution has the particular advantage of proposing an adaptation of the motive energy available in the energy source to drive one or the other of the two regulatory bodies, without any particular constraint linking these two regulatory bodies.

[0010] Thus, the movement according to the invention allows two operating modes, these two operating modes controlled respectively by the first regulator member, and by the second regulator member, make it possible to adapt the movement to the desired use and, for example, depending on the “complications” offered by such a movement.

[0011] According to one embodiment, the first regulator member has a first frequency and the second regulator member has a second frequency different from the first frequency.

[0012] According to another embodiment, the energy source cooperates directly with the first drive train and with the second drive train.

[0013] Still according to another embodiment, the mechanism comprises a first differential, the first drive train and the second drive train being kinematically connected to the output mobile via the first differential.

[0014] Still according to another embodiment, the mechanism comprises a second differential, the energy source cooperating with the first drive train and with the second drive train via the second differential.

[0015] Yet another embodiment, said energy source comprises a barrel provided with a drum and a barrel shaft between which is mounted a motor spring, the drum comprising a first toothing.

The use of a barrel as a source of energy makes it possible to integrate the movement according to the invention into a timepiece with well-known operating energy parameters.

[0017] Still according to another embodiment, the movement further comprises a locking device making it possible to simultaneously stop the walking of one of the first and second regulating member and to release the walking of the other among the first and second regulatory body. In this way, the movement is continuously driven either by the first regulator member O1 or by the second regulator member O2, without dead time.

[0018] Still according to another embodiment, the output mobile of said mechanism is in kinematic connection with an hour wheel or a minute wheel or a seconds wheel. In this way, a single display of the time is kept, regardless of the regulating organ which drives the movement.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> <SEP> FIG. 1 is a perspective view of an embodiment of the movement according to the invention, from above the movement; <tb> <SEP> figure 2 is a perspective view of the movement of figure 1, from below the movement, <tb> <SEP> FIG. 3 schematically represents a configuration of the mechanism according to a variant; <tb> <SEP> FIG. 4 schematically represents a configuration of the mechanism according to another variant; <tb> <SEP> FIG. 5 schematically represents a configuration of the mechanism according to yet another variant; <tb> <SEP> FIG. 6 shows a view in section and in perspective of an alternative embodiment of the mechanism according to the configuration of FIG. 5; <tb> <SEP> FIG. 7 is a view in section and in perspective of another variant embodiment of the mechanism according to the configuration of FIG. 5; <tb> <SEP> FIG. 8 schematically represents a configuration of the mechanism according to yet another variant; and <tb> <SEP> FIG. 9 is a view in section and in perspective of another variant embodiment of the mechanism according to the configuration of FIG. 8.

Example (s) of embodiment of the invention

Reference is made to Figures 1 and 2 illustrating a first embodiment of a mechanism according to the invention. The mechanism 100 comprises (see FIGS. 1 and 2) a barrel drum 1 capable of rotating about the axis 111 and equipped with a first barrel teeth 1a. A barrel shaft 1d pivoting about the barrel axis 111 is integral with a winding toothing 1c. At least one mainspring (not visible in the figures) is arranged in the barrel and has a first end fixed on the barrel shaft 1d and a second end fixed on or cooperating with the barrel drum 1a. The barrel 1 also comprises a second barrel toothing 1b connected to the barrel shaft 1d by a one-way clutch (for example a one-way clutch release system by pawl) so that the winding of the mainspring of barrel 1 can be reassembled. using the winding teeth 1c.

The energy supplied by the barrel 1 can be transmitted to a first regulator member O1 via a first gear train formed of a first drive gear 4 and a first finishing gear RF1. According to the embodiment illustrated in Figures 1 and 2, the first drive gear comprises a first mobile 4 mounted to pivot about an axis 40 and comprising a first wheel 4a and a first pinion 4b meshing with the first barrel teeth 1a.

The energy supplied by the barrel 1 can also be transmitted to a second regulator member O2 via a second gear train formed by a second drive train 2, 3 and a second RF2 finishing gear. According to the embodiment illustrated in Figures 1 and 2, the second drive train comprises a second mobile 2 mounted to pivot about an axis 20 and comprising a second wheel 2a and a second pinion 2b meshing with the second barrel teeth. 1b. The second drive train comprises a third mobile 3 mounted to pivot about an axis 30 and formed of a third pinion 3a meshing with the second wheel 2a, and of a third wheel 3b.

The mechanism 100 further comprises a first differential D1, 9, 10,11, 12 cooperating with the first and the second gear train 4, RF1 and 2, 3, RF2.

Still according to the example of Figures 1 and 2, the first differential D1 comprises a planet carrier 9 capable of pivoting about an axis 90. The planet carrier 9 forms a cage on which one or more planet gears 11 (two planet wheels in the example illustrated in Figures 1 and 2) are mounted to pivot about an axis 50 (or axes 50), substantially perpendicular to the axis 90. A first sun gear 10 also mounted to pivot about the axis 90 comprises a first bevel gear 10b of the sun gear engaging with the planet gear (s) 11, as well as a first gear 10a of the sun gear engaging with the first wheel 4a of the first mobile wheel 4. The first differential D1 further comprises a second sun gear 12 mounted to pivot around the axis 90 and comprising a second bevel gear 12a of the sun gear meshing with the planet (s) 11 and a second gear 12b of the sun gear meshing with the third wheel 3b of the mobile 3.

The first differential D1 further comprises an output mobile, here an output shaft 15 which is integral with the planet carrier 9, intended to drive a minute hand (not shown). In variants, the output may include a mobile driving, directly or indirectly, a mobile integral with the minute hand. The first differential D1 is therefore driven in rotation at least by one or the other of the first drive train 4 and of the first finishing train RF1 (via the first wheel 4a) and of the second train of drive 2, 3 and of the second finishing gear RF2 (via the third wheel 3b). The first differential D1 must therefore be configured to drive the output shaft 15 in rotation with an angular speed of one revolution in one hour, independently of the speed of rotation of the third wheel 3b and of the first wheel 4a.

[0026] According to a first mode of operation, the second O2 regulator member is stopped. The second transmission chain formed by the second drive gear 2, 3 and the second finishing gear RF2 is immobilized under the effect of the torque delivered by the mainspring of the barrel on the barrel shaft 1d and transmitted to the second pinion 2b. The barrel shaft 1d and the second barrel teeth 1b, as well as the second sun gear 12 are immobilized. In this case, for example, an escape wheel is supported on an anchor, itself supported on limiting pins.

Under the effect of the driving torque exerted by the mainspring of the barrel, the barrel drum will drive the first pinion 4b of the first mobile 4 in rotation via the first teeth 1a. The rotation of the first pinion 4b drives the first wheel 4a in rotation. In turn, the first wheel 4a rotates the first toothed wheel 10a of the first sun gear 10 with which it meshes. The first bevel gear 10b of the first sun gear 10 rotates the planet (s) 11 which themselves are in engagement with the second bevel gear 12a of the second sun gear 12 which is stationary. In this way, the rotation of the first sun gear 10 forces the planet (s) 11 to roll on the second bevel gear 12a, stationary, driving the planet carrier 9, and thus the output shaft 15, in rotation in the same direction of rotation. rotation than the first sun gear 10. The transmission ratio of the first drive gear 4, of the first finishing gear RF1 and of the first differential D1 is such that the output shaft 15 rotates with a rotational speed of one revolution per turn. hour.

In one embodiment, the first regulator member O1 oscillates with a first frequency f1 and is suitable for the operation of a movement of a watch in normal use, when worn. The transmission ratio of the first drive gear 4 and of the first finishing gear RF1 is then adapted to the first frequency of the first regulator member O1 (given power reserve).

According to a second mode of operation, the first regulator member O1 is stopped. A first transmission chain formed by the first drive gear 4 and the first finishing gear RF1 is immobilized under the effect of the torque delivered by the mainspring of the barrel on the barrel drum 1 and transmitted to the first pinion 4b. The barrel drum 1 and the first barrel teeth 1a, as well as the first sun gear 10 are immobilized.

Under the effect of the driving torque exerted by the mainspring of the barrel, the barrel shaft will drive the second pinion 2b of the second mobile 2 in rotation via the second toothing 1b of the barrel. The rotation of the second pinion 2b drives the second wheel 2a in rotation which itself drives the third pinion 3a and the third wheel 3b in rotation. In turn, the third wheel 3b rotates the second toothed wheel 12b of the second sun gear 12 with which it meshes. The second bevel gear 12a of the second sun gear 12 rotates the planet (s) 11 which themselves engage with the first bevel gear 10b of the first sun gear 10 which is stationary. In this way, the rotation of the second sun gear 12 forces the planet (s) 11 to roll on the first bevel gear 10a, stationary, driving the planet carrier 9, and thus the output shaft 15, in rotation in the same direction of rotation. rotation than the second sun gear 12. The transmission ratio of the second drive gear 3, the second finishing gear RF2 and the first differential D1 is such that the output shaft 15 rotates with a rotational speed of one revolution per revolution. hour.

The speed of rotation of the planet carrier 9 is always one revolution per hour, whether it is driven by the first drive gear 4 and the first finishing gear RF1 or by the second drive gear 3 and the second RF2 finishing gear.

The second mode of operation maintains the activity of a second O2 regulator organ. It is obtained by dimensioning the second gear train 2, 3, RF2, and the second regulator member O2 according to the desired objective. It is therefore possible with this arrangement to adapt the torque of the barrel 1 for various applications. For example, the second regulator member O2 can have a second frequency f2 different from the first frequency f1 of the first regulator member O1. The second frequency f2 can be lower or higher than the first frequency f1 so as to deliver a given torque to the level of the output shaft 15 for driving a specific mechanism (calendar mechanism, complications). For example, the second frequency f2 can be lower than the first frequency f1 so as to obtain a greater power reserve than that obtained in the first operating mode. It is then possible to operate the first regulator member O1 with a first high frequency f1 for running a watch when worn and to operate the second regulator member O2 with a second lower frequency f2 when the watch is not worn. , without the speed of rotation of the output shaft 15 being changed.

[0033] According to a variant, the second frequency is at least half as high as the first frequency. By way of example, the first oscillation frequency f1 may be between 2 and 7 Hz, preferably between 3 and 5 Hz and the second oscillation frequency f2 is between 0.5 and 1.5 Hz, preferably of order of 1 Hz. In this case, it will be understood that switching to the second operating mode extends the power reserve. The first operating mode is for example used when the watch comprising the mechanism 100 is worn (in particular during the day) and the second operating mode when the watch is not worn (at night and during periods of non-use or watch rest).

According to another example, the first regulator member O1 can include a Swiss lever escapement and the second regulator member O2 can include a detent escapement, the latter having a better performance but being more sensitive to shocks at range.

More generally, the first and second regulator member O1, O2 may include a mechanical oscillator such as a sprung balance type system or a tuning fork type oscillator.

The transition from the first operating mode to the second operating mode and vice versa is achieved by stopping one of the two regulator members 01, 02. The stopping of the first and second regulator organ O1, O2 will be adapted to the type of regulatory organ used. For example, in the case of a regulator of the sprung balance type, a stop-second type mechanism (or stop balance, not shown) can be used.

The transition from the first operating mode to the second operating mode and vice versa can be carried out on manual control by the user. To this end, a manual control makes it possible to control a stop device for the passage of the step from one to the other among the first and second regulating members O1, O2.

On the other hand, this arrangement is compatible with the use of several barrels in series according to the energy needs and the volumes available within a movement.

It is therefore possible, with this arrangement, to modulate and adapt the torque delivered by the mainspring of the barrel for each regulator member O1 and O2, by modifying only the speed ratios of the first and second cogs of workout 4 and 2, 3, without any other movement modification. For example, one can modify only the first drive train 4, only the second drive train 2, 3, or both drive wheels 4, 2, 3 at a time, depending on the desired applications for each mode of operation. operation.

[0040] According to a variant not forming part of the invention, the first regulator member O1 and the second regulator member O2 operate simultaneously (third operating mode). In this case, in general, the mechanism 100 is configured to further allow the simultaneous operation of the first gear train 4, RF1 and the second gear train 2, 3, RF2. The first differential D1 is then moved both by the wheel 3b (driven by the second regulator member O2) at its toothing 12b and both by the wheel 4a (driven by the first regulator member O1) at its level. toothing 10a. In this case, there is an accumulation of rotational speeds (drive speeds generated by the simultaneous rotation of the wheels 4a and 3b) within the differential gear train, so that the output shaft 15 turns twice as much. faster than in the first operating mode or the second operating mode. In this way, the mechanism 100 is continuously driven by the first regulating member O1 and / or by the second regulating member O2, without dead time.

If we want to be able to use this third mode of operation and keep a speed of rotation of the output shaft 15 identical to that of the first and second modes of operation, the mechanism 100 is also equipped, optionally, a speed reduction module which is engaged on the output shaft 15 during this third operating mode, and which is disengaged from the output shaft 15 for the first and second operating modes. It is therefore a matter of using a gearbox actuated manually (or automatically) and mounted on the output shaft 15 to make it possible to reduce the speed of rotation of the output shaft 15 and in particular to divide this speed by two.

Note that if the first differential D1 has been shown so far in the form of a mechanical differential, and in particular with a bevel gear train, other configurations are possible. In particular, according to a configuration not shown, the first differential D1 can be a flat differential gear.

It goes without saying that the present invention is not limited to the embodiment which has just been described and that various modifications and simple variants can be envisaged by those skilled in the art without departing from the scope of the present invention .

[0044] FIG. 3 diagrammatically and more generally represents a possible configuration of the mechanism 100 according to the invention. The first transmission chain comprises the first drive train (represented by the symbol RV1) and the first finishing train RF1, between the barrel drum (represented by the symbol T) and the first regulator member O1. The first finishing gear RF1 kinematically connects the first drive gear RV1 to the first regulator member O1. The barrel itself is represented by the symbol B. The second transmission chain includes the second drive gear (represented by the symbol RV2) and the second finishing gear RF2, between the barrel shaft (represented by the symbol A) and the second O2 regulator. The second finishing gear RF2 kinematically connects the second drive gear RV2 to the second regulator member O2. The first drive train RV1 and the second drive train RV2 engage with the first differential D1. In particular, the first drive train RV1 engages with the first differential D1 through a first input (which comprises the first toothed wheel 10a in the example of Figures 1 and 2).

The output shaft (represented by the symbol S) of the first differential D1 is intended to drive a minute hand. A time-setting device MH acting on the output shaft S as well as a device R for winding the barrel B are also represented in FIG. 3.

In the first mode of operation, the barrel B drives the first gear train RV1, RF1 and the first regulator member O1 having a first frequency f1, and the second gear train RV2, RF2 and the second regulator member O2 are stationary. In the second operating mode, the barrel B drives the second gear train RV2, RF2 and the second regulator member O2 having a second frequency f2, and the first gear train RV1, RF1 and the first regulator member O1 are stationary . Switching from one mode to another is obtained instantaneously or almost instantaneously.

As discussed above, the first operating mode can correspond to a transmission of energy for the operation of a time display in a watch movement. The barrel B and the speed ratios of the first drive train RV1 and of the first finishing train RF1 are then dimensioned as a function of the characteristics of the oscillator and of the escapement of the first regulator member O1 for a given power reserve.

The second operating mode can be configured to deliver a given torque to the output shaft S for driving a specific mechanism by adapting the second regulator member O2 accordingly. It is thus possible to obtain a power reserve different from that of the first mode for the same output shaft S which can also be used to cause calendar complications whatever the chosen operating mode.

The proposed solution is compatible with the use of several barrels in series according to the energy needs and the volumes available within the movement.

[0050] FIG. 4 shows another possible configuration of the mechanism 100 according to the invention. In this alternative configuration, the first drive gear RV1 and the first finishing gear RF1 are not connected in series as in the example of FIG. 3 but in parallel with the barrel B. For example, each of the first gear d The drive RV1 and of the first finishing gear RF1 engages with the drum T of the barrel. Similarly, the second drive gear RV2 and the second finishing gear RF2 are connected in parallel with the barrel B, more particularly, each of the second drive gear RV2 and the second finishing gear RF2 engages with the barrel shaft A. The mechanism 100 can also include any combination of the configurations shown in Figures 3 and 4.

FIG. 5 schematically shows yet another possible configuration of the mechanism 100 according to the invention. The first transmission chain comprises the following kinematic sequence: the first drive train RV1, the first differential D1, the first finishing train RF1 and the first regulator member O1. The second transmission chain comprises the following kinematic sequence: the second drive train RV2 the first differential D1, the second finishing train RF2 and the second regulator member O2. The barrel B engages with the first transmission chain or the second transmission chain via a second differential D2. Similar to the configurations of Figures 3 and 4, the first drive train RV1 and the second drive train RV2 engage with the first differential D1. The first differential D1 engages with the output shaft S. The time setting device MH acting on the output shaft S as well as the winding device R of the barrel B are also represented in FIG. 5.

Figure 6 illustrates an embodiment of the mechanism according to the configuration of Figure 5. In particular, the second differential D2 comprises a first planet carrier 190 which can rotate about an axis 191, on which is mounted a wheel satellite 192 of one or more satellites 193, each being guided in rotation on the planet carrier 190 about an axis of satellite 194. An upper wheel 196 meshes with the planet or satellites 193 via an upper bevel wheel 195 pivotally mounted around the axis 191. A lower wheel 197 meshes with the planet (s) 193 via a lower bevel wheel 198 pivoting on the axis 191.

The mechanism also comprises a first differential D1 comprising a second satellite carrier 200 mounted to pivot about a satellite door axis 201, on which is also pivotally mounted one or more satellites 203 guided in rotation about a satellite axis 204, substantially perpendicular to the axis 201. An upper wheel 206 meshes with the planet (s) 203 by means of a second conical toothed wheel 205 mounted to pivot around the axis 201. A lower wheel 208 is integral with an intermediate wheel 207 and a first bevel toothed wheel 209 pivotably mounted on the axis 201, the first bevel toothed wheel 209 meshing with the planet (s) 203.

In the configuration of Figure 6, the first drive train RV1 comprises the upper wheel 196 and the upper wheel 206. The first finishing train RF1 driving the first regulator member O1 engages with the upper wheel 206. The second drive gear RV2 comprises the lower wheel 197 and the intermediate wheel 207. The second finishing gear RF2 driving the second regulator member O2 engages the lower wheel 208. The first barrel teeth 1a (not shown in the figure). figure 6) engages with the teeth of the planet wheel 192.

The operation of the mechanism according to the embodiment of Figure 6 is described here. When the second regulator member O2 is blocked (first operating mode), the torque delivered by the barrel 1 immobilizes the second finishing gear RF2 (in the case of a sprung balance member, the escape wheel comes to rest on anchor). The lower wheel 197 and the intermediate wheel 207 are then stationary. The torque of the barrel 1 will rotate the first planet carrier 190 which drives the planet (s) 193 in rolling on the lower bevel wheel 198 and drives the upper bevel wheel 195 in rotation. The upper bevel wheel 195 transmits the movement to the second bevel gear 205 of the first differential D1 via the upper wheel 196. On the one hand, the second bevel gear 205 transmits energy to the first regulator member O1 via the first finishing gear RF1. On the other hand, the second bevel gear 205 drives the planet (s) 203 in rolling on the stationary first bevel gear 209, thus driving the second planet carrier 200 in rotation in the same direction of rotation as the second bevel gear 205. The speed ratio between the speed of the second planet carrier 200 and the speed of the first planet carrier 190 is 1 (to the nearest sign). The speed of rotation of the second planet carrier 200 is one revolution per hour, imposed by the first regulator member O1 and the first finishing gear RF1.

When the first regulator member O1 is blocked (second mode of operation), the torque delivered by the barrel 1 immobilizes the first finishing gear RF1 as well as the upper wheel 196 and the upper wheel 206. The torque of the barrel drives in rotation the first planet carrier 190 which drives the planet (s) 193 in rolling on the stationary upper bevel wheel 195, the planet (s) 193 driving the lower bevel wheel 198 in rotation. The rotation of the lower bevel wheel 198 drives the lower wheel 197 which drives the first differential D1 in rotation by means of the first bevel gear 209. The second bevel gear 205 will, on the one hand, transmit energy. to the first regulator member O1 via the first finishing gear RF1 and, on the other hand, forcing the planet (s) 203 to roll on the first bevel gear 209, stationary, thus driving the second planet carrier 200 in rotation in the same direction of rotation as the second bevel gear 205. The overall speed ratio between the speed of the second planet carrier 200 and the speed of the first planet carrier 190 is equal to the speed ratio of the second drive train RV2 (at the sign near). The speed of rotation of the second planet carrier 200 is one revolution per hour, imposed by the second regulator member O2 and the second finishing gear RF2.

The mechanism according to the embodiment of FIG. 6 therefore makes it possible to modulate the torque delivered by the barrel 1 for the second operating mode, by modifying only the speed ratio of the second gear train RV2, without any other modification of the mechanism. This amounts to changing the gear consisting of the lower wheel 197 and the first bevel toothed wheel 209 in order to obtain a reduction or multiplier speed ratio, depending on the desired application for this second operating mode.

FIG. 7 illustrates an embodiment of the mechanism according to the configuration of FIG. 5. In particular, the second differential D2 comprises a first planet carrier 300 capable of rotating about an axis 301. The first barrel teeth 1a comes from meshed with a toothing of the planet carrier 300. One or more planet wheels 303, each guided in rotation on the planet carrier 300 about an axis of the planet carrier 304. A pinion 302, integral and coaxial with a wheel 305, is mounted to pivot on the axis 301 and meshes with the planet or satellites 303. An upper ring gear 306 is mounted to pivot on the axis 301. The upper ring gear 306 has an internal toothing 306 'meshing with the planet or satellites 303. The upper ring gear 306 has also an external toothing 306 ".

The first differential D1 comprises a second planet carrier 400 capable of rotating about an axis 401 of the planet carrier, on which pivots one or more planet wheels 403 mounted around a satellite axis 404 (substantially parallel to the axis 401 ). A pinion 402 is mounted to pivot on the axis 401 and meshes with the planet or satellites 403. An upper pinion 405 and an upper wheel 406 are mounted on the pinion 402. A crown 407, mounted to pivot around the axis 401, has an internal toothing 407 'and an external toothing 407 ". The internal toothing 407' meshes with the planet (s) 403. The first drive gear RV1 comprises the upper ring gear 306, the upper pinion 405 and the upper wheel 406 with which the first finishing gear RF1 engages. The second drive gear RV2 comprises wheel 305, the second planet carrier 400 and ring gear 407, the second finishing gear RF1 engaging the external teeth 407 "of ring gear 407 .

In the first mode of operation, the second O2 regulator member is blocked. The second finishing gear RF2 as well as the crown gear 407 are stationary. The torque of barrel 1 rotates the first planet carrier 300. At the second differential D2, no element is blocked and the power of the barrel can be transmitted to the first differential D1 via the wheel 305 and the external teeth 306 "of the upper ring gear 306 of the second differential D2 to the second planet carrier 400 and to the upper pinion 405.

The speed of rotation of the second planet carrier 400 is one revolution per hour, imposed by the first regulator member O1 and the first finishing gear RF1.

In the second mode of operation, the first regulator member O1 is blocked and the first finishing gear RF1 as well as the upper pinion 405, the upper wheel 406, the pinion 402 and the upper ring gear 306 are stationary. The torque of the barrel 1 rotates the first planet carrier 300 which forces the planet or satellites 303 to roll on the internal teeth 306 ', thus causing the pinion 302 to rotate. The movement is transmitted to the second planet carrier 400 of the first differential D1 via the wheel 305. In its movement, the second planet carrier 400 will force the planet (s) 403 to roll on the pinion 402, immobile, thus causing the crown 407 rotating in the same direction of rotation as the second planet carrier 400. The crown 407, via its external teeth 407 ", will transmit energy to the second regulator member O2 via the second gear train. RF2 finishing.

The speed of rotation of the second planet carrier 400 is one revolution per hour, imposed by the second regulator member O2 and the second finishing gear RF2.

The speed ratio between the speed of the crown 407 and the speed of the first planet carrier 300 is equal to the overall speed ratio of the second differential D2 in the second operating mode, times the speed of the second drive gear RV2 , times the overall speed ratio of the first differential D1 in the second operating mode. The speed of the second finishing gear RF2 can therefore be dimensioned as a function of the speed of the second drive gear RV2 and the overall speed ratio of the first differential D1 in the second operating mode.

The arrangement of the mechanism according to the embodiment of Figure 7 makes it possible to modulate the torque delivered by the barrel 1, for the second operating mode, by modifying the speed ratio of the second differential D2, and / or the gear ratio of the RV2 drive train. This amounts to changing the planet or satellites 303, the pinion 302, possibly the internal toothing 306 'of the upper ring gear 306, and / or the wheels 305 and 400 to obtain a speed ratio according to the desired application for this second mode of operation. The arrangement of the mechanism according to the embodiment of FIG. 7 offers the advantage of having no play at the level of the display of the minutes which is produced by a shaft 408, on the axis 401 and integral with the second door. satellite 400.

In general, several types of gear trains can be used to produce the second differential D2 and / or the first differential D1 and satisfy this arrangement, whether it is bevel or plane gears, of basic ratio equal to 1 or -1 (usual case of differentials), or other values by suitably adapting the ratios as well as the inputs / outputs of these differentials. It is also possible to envisage having, for a constructive solution, a second differential D2 different from the first differential D1, and therefore any combination of differentials D1 and D2 making it possible to achieve this adaptation of the motive power.

[0067] FIG. 8 schematically represents yet another possible configuration of the mechanism 100 according to the invention. This configuration is the same as that of FIG. 5 except that it does not include the second differential D2 and that the barrel B engages directly with the first transmission chain RV1-D1-RF1-O1 or with the second chain of transmission RV2-D1-RF2-O2.

FIG. 9 illustrates an exemplary embodiment of the mechanism according to the configuration of FIG. 8. The mechanism comprises a first differential D1 comprising a planet carrier 500 which can rotate about an axis 501, on which one or more satellites can pivot. 503 guided in rotation about a satellite axis 505. The satellite carrier 500 supports the minute hand (not shown) and therefore performs one revolution in one hour. A first sun gear 502 which can rotate about the axis 501 meshes, on the one hand, with the planet or satellites 503 by means of a lower toothing 502 "and, on the other hand, with the barrel drum 1 by the through the first barrel toothing 1a and an upper toothing 502 '. A second sun gear 504 which can rotate about the axis 501, meshes, on the one hand, with the planet or satellites 503 by means of a wheel upper toothed 504 'and, on the other hand, with a wheel 606 of a sun gear 600 through a lower toothing 504 ". In this configuration, the first sun gear 502 forms the first drive gear RV1.

The second drive train RV2 comprises a planet carrier 604 mounted to pivot about an axis 601 and on which can pivot one or more satellites 603 guided in rotation about a satellite axis 604 '. The planet carrier 604 has a toothed wheel 604 "meshing with a wheel 605. A sun gear 600 capable of rotating around the axis 601 meshes, on the one hand, with the planet (s) 603 by means of an upper toothed wheel 602 and, on the other hand, with the second sun gear 504 of the first differential D1 by means of a lower toothed wheel 606. A sun gear 607 is mounted to pivot about the axis 601 and meshes with the planet (s) 603 by the intermediate of an internal toothing 608 which is integral with the barrel shaft 609.

In the first mode of operation, the second regulator member O2 is blocked. Under the effect of the torque delivered by the barrel spring on the barrel 609, transmitted to the lower toothed wheel 606 by means of the train formed of the internal teeth 608, of the planet or satellites 603 and of the upper toothed wheel 602, then at the upper toothed wheel 504 ', the second finishing gear RF2 will come to a stop. The barrel shaft 609 is then stationary. Under the effect of the driving torque exerted by the barrel spring, the drum 1 will rotate the first sun gear 502. The first sun gear 502, on the one hand, transmits energy to the first regulator member O1 via the first finishing gear RF1 and, on the other hand, forcing the planet (s) 503 to roll on the upper toothed wheel 504 ', stationary, thus causing the planet carrier 500 to rotate in the same direction of rotation as the first sun gear 502. The speed of rotation of the planet carrier 500 is one revolution per hour, imposed by the first regulator member O1 and the first finishing gear RF1. The speed ratio of the first drive gear RV1 is none other than the gear ratio between the first barrel teeth 1a and the upper teeth 502 '.

In the second mode of operation, the first regulator member O1 is blocked and the first finishing gear RF1 as well as the first sun gear 502 and the barrel drum 1 are stationary. The motor torque is then delivered by the barrel shaft 609, by rotating in the opposite direction of the drum 1. The gear train formed by the internal toothing 608, the planet (s) 603 and the upper toothed wheel 602 corresponds to a train ordinary since the satellite carrier 604 is blocked. This gear train achieves a first gear ratio RV2a. The torque is then transmitted to the second sun gear 504 by the lower toothed wheel 606 by performing a second speed ratio RV2b. The overall speed ratio of the second RV2 drive train is therefore: RV2 = RV2a × RV2b (equation 1).

The direction of rotation of the planet or satellites 603, of the upper toothed wheel 602 of the barrel shaft 609 as well as of the first and second planetary wheels 502, 504 is indicated by the arrows in solid lines.

In the variant of Figure 9, the reassembly is performed by acting on the planet carrier 604 via the wheel 605. The gear train formed by the internal teeth 608, the planet or satellites 603 and the upper toothed wheel 602 is in this case used as a power distributor differential gear.

In the case where the first and the second regulator members O1 and O2 are stopped. The drum 1 and the sun gear 600 are therefore also stationary. By rotating the planet carrier 604 anti-clockwise, the planet (s) 603 will roll on the upper toothed wheel 602 clockwise and therefore drive the barrel shaft 609 clockwise corresponding to the winding direction. The directions of rotation of the wheel 605, the toothed wheel 604 "and the barrel shaft 609 are indicated by the dashed arrows. The first and second planets 502, 504 rotate in the same direction as in the second mode of operation. operation.

The cog of the first mode of operation is always under the action of a torque exerted by the drum and there is no play in the chain B - RV1 - D1 - RF1. The same is true of the train of the second operating mode due to the toothing forces at the level of the planet (s) 603 and of the upper toothed wheel 602.

The blocking of the planet carrier 604 can be achieved in different ways, for example by a one-way gear (for example the wheel 605 and the toothed wheel 604 "), by pawl (not shown), or even by other means appropriate.

The mechanism according to the configuration of Figure 9 makes it possible to modulate the torque delivered by the barrel 1, for the second operating mode, by modifying only the speed ratio of the second drive train RV2, without any other modification of the mechanism. This amounts to changing either the speed ratio of the train formed by the lower toothed wheel 606 and the lower toothed wheel of the second sun gear 504 "(RV2b), or that of the train formed by the internal toothing 608, of the planet (s) 603 , and the upper toothed wheel 602 (RV2a), ie the two trains in order to obtain a speed ratio according to the desired application for this second operating mode.

There is always a driving torque exerted on the lower toothed wheel 606 whatever the envisaged operating mode, that is to say the first or the second operating mode or during reassembly.

Compared to the configuration of Figures 6 or 7, the transmission of energy to the first and second regulators O1, O2 is more "direct". In fact, in the first and second operating modes, the gear trains are ordinary (fixed axes of rotation). The first differential D1 is only used to rebuild the minute and the train placed under the barrel 1 is only used in differential mode during reassembly.

In the configuration of FIG. 9, the differential D1 can be a flat differential gear. This configuration can also be adapted in order to put the RV2 train next to the barrel to reduce its thickness.

Reference numbers used in figures

O1 first regulator member O2 second regulator member f1 first frequency f2 second frequency D1 first differential D2 differential MH time setting device R winding RV1 first drive train RF1 first finishing train RV2 second drive train RF2 second finishing gear T barrel drum 1, B barrel 1a first barrel teeth 1b second barrel teeth 1c winding teeth 1d, A barrel shaft 2 second mobile 2a second wheel 2b second pinion 3 third mobile 3a third pinion 3b third wheel 4 first mobile 4a first wheel 4b first pinion 9 planet carrier 10 first sun gear 10a first gear of sun gear 10b first bevel gear of sun gear 11 planet 12 second sun gear 12a second bevel gear of sun gear 12b second gear of sun gear 15, 5 gear shaft output 20 axis of rotation of mobile 2 30 axis of rotation of mobile 3 40 axis of rotation of mobile 4 50 axis d e satellite rotation 90 satellite carrier axis 111 barrel rotation axis 190 first satellite carrier 191 axis 192 satellite wheel 193 satellite 194 satellite axis 195 upper bevel wheel 196 upper wheel 197 lower wheel 198 lower bevel wheel 200 second planet carrier 201 satellite door axle 203 satellite 204 satellite axle 205 second bevel gear 206 upper wheel 207 intermediate wheel 208 lower wheel 209 first bevel gear 300 first planet carrier 301 axle 302 pinion 303 satellite 304 satellite axle 305 wheel 306 upper crown 306 ' internal toothing 306 "external toothing 400 second planet gear 401 planet carrier pin 402 pinion 403 planet gear 404 planet gear 405 upper pinion 406 upper wheel 407 crown wheel 407 'internal toothing 407" outside toothing 408 shaft 500 planet carrier 501 pin 502 first planet gear 502 'upper teeth of the first sun gear 502 "lower teeth of the first p planet gear 503 planet gear 504 second planet gear 504 'upper toothed wheel of second planet gear 504 "bottom toothed wheel of second planet gear 505 planet gear 600 planet gear 602 top toothed wheel 603 planet gear 604 planet carrier 604' planet gear 604" toothed wheel 605 wheel 606 wheel lower gear 607 planetary 608 internal gear 609 barrel shaft

Claims (15)

1. Mechanism (100) for a watch movement, comprising: a source of energy (1), a first drive train (RV1) connecting the energy source (1) to a first regulator member (O1), a second drive train (RV2) connecting the energy source (1) to a second regulator member (O2), the second regulator member (O2) having an operation different from the first regulator member (O1), an output mobile (S) serving to drive the time display, able to be kinematically connected to both the first drive train (RV1) and the second drive train (RV2), the mechanism (100) being arranged so that the time display is driven alternately, and at the same speed, by the operation of the first regulating member (O1) or by the operation of the second regulating member (O2) and in in which the first regulator (O1) has a first frequency (f1) and the second regulator (O2) has a second frequency (f2) different from the first frequency (f1). 2. Mechanism (100) according to the preceding claim, in which the energy source (1) cooperates directly with the first drive train (RV1) and with the second drive train (RV2). 3. Mechanism (100) according to one of the preceding claims, comprising a first differential (D1), the first drive train (RV1) and the second drive train (RV2) being kinematically connected to the output mobile (S) via the first differential (D1). 4. Mechanism (100) according to claims 1 and 3, comprising a second differential (D2), the energy source (1) cooperating with the first drive train (RV1) and with the second drive train (RV2) via the second differential (D2). 5. Mechanism (100) according to one of the preceding claims, wherein said energy source comprises a barrel provided with a drum (1) and a barrel shaft (1d) between which is mounted a mainspring, the drum (1) having a first toothing (1a). 6. Mechanism (100) according to one of the preceding claims, wherein the first drive gear (RV1) cooperates with the drum (1) via the first toothing (1a) and the second drive gear (RV2) cooperates with the barrel shaft (1d). 7. Mechanism (100) according to claim 6, in which the barrel shaft (1d) is integral with, or made integral with, a second toothing (1b), and in which the second drive gear (RV2) cooperates with the second toothing (1b). 8. Mechanism (100) according to one of the preceding claims, comprising a first finishing gear (RF1) kinematically connecting the first drive gear (RV1) to the first regulator member (O1) and a second finishing gear (RF2) kinematically connecting the second drive gear (RV2) to the second member regulator (O2). 9. Mechanism (100) according to one of the preceding claims, further comprising a blocking device making it possible to simultaneously stop the operation of one of the first and second regulating member (01, 02) and to release the operation of the other among the first and second regulating member (O1, O2 ). 10. Mechanism (100) according to claim 9, in which the first differential (D1) is configured to allow the operation of one of the first and the second drive train (RV1, RV2) while the other of the first and the second drive train (RV1 , RV2) is stopped. 11. Mechanism (100) according to one of claims 3 to 10, wherein the first differential (D1) comprises one or more planet gears (11, 203) and a sun gear (10, 200) comprising a first bevel gear (10b, 205) cooperating with the first drive gear (RV1) and a second conical toothed wheel (12b, 209) cooperating with the second drive gear (RV2). 12. Mechanism (100) according to claim 11, wherein said one or more planet gears (11, 203) is pivotally mounted about a planet axis (50, 204) and the first and second bevel gears (10b, 12b) are pivotably mounted about a planet axle. satellite carrier (90, 201) substantially perpendicular to the satellite axis (50, 204). 13. Mechanism (100) according to one of claims 3 to 10, wherein the first differential (D1) comprises one or more planet wheels (403) mounted to pivot about a planet wheel axis (404) and a ring gear (407) pivotally mounted about a planet carrier axis (401) substantially parallel to the satellite axis (404); the first differential (D1) further comprising an upper wheel (406) pivotally mounted on the planet carrier axle (401). 14. Mechanism (100) according to claims 8 and 13, wherein the first finishing gear (RF1) cooperates with the upper wheel (406) and the second finishing gear (RF2) cooperates with the ring gear (407). 15. Mechanism according to one of claims 1 to 14, in which the first regulating member (O1) and the second regulating member (O2) are mechanical oscillators comprising a balance and a spiral spring.