CH720214A2 - Date control mechanism of a watch movement - Google Patents

Abstract

The invention relates to a date control mechanism for a watch movement comprising: – an animation cam (10) driven in rotation so as to perform one revolution per day, – a large rocker (20) movable between two successive states when the animation cam (10) makes a complete revolution, including a control state in which it is driven by the animation cam (10) and bears against it, and a rest state in which it is driven by a large rocker spring (20), – a control mobile (40) intended to be driven by at least one step by the large rocker (20) when it occupies the control state, said mobile control (40) being intended to be connected to a display of a time value.

Description

Technical field of the invention

[0001] The invention relates to the field of complications of watch movements, and in particular date mechanisms.

[0002] More particularly, the invention relates to a mechanism for controlling the date of a watch movement.

Technology background

[0003] Among complicated watches, watches whose watch movement allows the display of a date, among other mechanisms, can present a large amount of information.

[0004] In particular, thanks to a date control mechanism, these watch movements allow for example the display of the date, for example by separating the display of the units digit and the tens digit, of the day of the week, of the month, of the leap year. Furthermore, generally these control mechanisms cooperate kinematically with correction mechanisms making it possible to correct the displayed values. Consequently, these watch movements tend to have a very large number of parts, for example of the order of several hundred, and are therefore very complex to design and manufacture.

Another disadvantage of these date control mechanisms is that they are generally specific to the information to be displayed. In other words, a date control mechanism is generally developed according to its function, for example the display of an annual calendar, without considering the possibility of reusing its design with a minimum of modification for the realization of the display other information.

[0006] There thus appears a need to benefit from a mechanism for controlling the display of a date whose design is as simple as possible while offering the possibility of displaying a maximum of information, and making it possible to be able to be used with a minimum of evolution for the display of other information.

Summary of the invention

[0007] The invention resolves the aforementioned drawbacks and concerns for this purpose a mechanism for controlling the date of a watch movement comprising: – an animation cam driven in rotation so as to make one revolution per day, – a large mobile switch between two successive states when the animation cam completes a complete revolution, including a control state in which it is driven by the animation cam and rests against it, and a rest state in which it is driven by a large rocker spring, the large rocker comprising a body extending between a first end around which it is movable in rotation and a second free end, – a control mobile intended to be driven by at least one not by the large rocker when it occupies the control state, said control mobile being intended to be connected to a display of a time value.

[0008] The large rocker comprises a support arm connected to the first end of the body by a transverse shaft and by which the large rocker rests against the animation cam during the rotation of the latter, the transverse shaft extending along a longitudinal axis coincident with the axis of rotation of the large rocker and forming a non-zero angle with the axis of rotation of the animation cam.

[0009] In particular embodiments, the invention may also include one or more of the following characteristics, taken in isolation or in all technically possible combinations.

[0010] In particular embodiments, the support arm has at one free end a roller movable in rotation by means of which it rests against the animation cam, said roller rolling against the animation cam when this is driven in rotation.

[0011] In particular embodiments, the roller has a convex cross section so that when it rests against the animation cam, the contact zone between the roller and the animation cam is materialized by a point.

[0012] In particular embodiments, the support arm is arranged so that it extends along a longitudinal axis included in a diametrical plane of the animation cam or in a plane parallel to said diametrical plane, the body of the large rocker extending in a plane parallel to the diametrical plane.

[0013] In particular embodiments, the transverse shaft comprises a rotation blocking element cooperating with the large rocker.

[0014] In particular embodiments, the transverse shaft has a pivot at each of its ends by which it is intended to be fixed in a movable manner in rotation relative to a structure of the watch movement.

[0015] In particular embodiments, the animation cam is of the radial transmission type with an external profile, the support arm resting against said external profile, the latter comprising a first portion in the form of a circular sector whose radial section is increasing, considering the direction of rotation of the animation cam, and a second portion in the form of a circular sector whose radial section is decreasing, the first portion being more extensive than the second portion.

[0016] In particular embodiments, the control wheel comprises a thirty-one wheel, a correction cam and a date wheel, all arranged coaxially and linked together in rotation. The large rocker is configured to, when in the control state, cooperate with the thirty-one wheel by means of a first pawl that the body has at its second end, or to cooperate with the correction cam of the control mobile by means of a second pawl which the body has at its second end.

[0017] In particular embodiments, the control mobile comprises a month finger linked in rotation with the thirty-one wheel and cooperating with a month display once a month.

[0018] In particular embodiments, the body comprises a day finger arranged to cooperate with a day star intended to be linked to a day display.

[0019] In particular embodiments, the control mechanism comprises a month mobile equipped with a month cam intended to pivot one step each month and whose exterior profile is formed by alternating bumps and hollows . These bumps and these hollows correspond respectively to months comprising thirty-one days and months comprising less than thirty-one days, and against which rests a support leg which the large rocker presents when the latter occupies the state of rest. The large rocker is configured so that when it occupies the control state, on the last day of a month less than thirty-one days old, after occupying a rest state in which the support leg is in support against a hollow, the second pawl cooperates with the correction cam so as to rotate the control mobile so that the display of a time value indicates a time value representative of the following month, for example the first day of the following month and/or the name of the following month.

[0020] In particular embodiments, the month mobile comprises a hollow having a greater depth than that of the other hollows and corresponding to a month of twenty-eight days. The large rocker is configured so that when it occupies the control state, on the last day of the month of February, after having occupied a state of rest in which the support tab is resting against said hollow, the second pawl cooperates with the correction cam in order to rotate the control mobile so that the display of a time value indicates a time value representative of the following month, for example the first day of the following month and/or the name of the following month.

[0021] In particular embodiments, the month mobile comprises a leap year cam coaxial with the month cam and intended to pivot by one revolution every four years. The leap year cam has an external profile comprising a radial protrusion arranged once every four years opposite the hollow so as to limit the movement of the large rocker, said large rocker being configured so that when it occupies the control state, on the last day of February in a leap year, after having occupied a rest state in which the support tab rests against the radial protuberance, the second pawl cooperates with the cam correction in order to rotate the control mobile so that the display of a time value indicates a time value representative of the following month, for example the first day of the following month and/or the name of the following month.

Brief description of the figures

[0022] Other characteristics and advantages of the invention will appear on reading the following detailed description given by way of non-limiting example, with reference to the appended drawings in which: - Figure 1 represents a perspective view of a date control mechanism for a watch movement according to a preferred embodiment of the invention; – Figure 2 shows a top view of part of the control mechanism of Figure 1; – Figure 3 shows a detailed view of a control mobile of the control mechanism of Figure 1; – Figure 4 shows a side view of the control mechanism of Figure 1 and a detailed view of a month mobile; – Figure 5 represents a perspective view of part of the control mechanism of Figure 1 and a day star.

Note that the figures are not necessarily drawn to scale for reasons of clarity.

Detailed description of the invention

[0024] The invention relates to a date control mechanism for a watch movement as partially shown in the figures comprising an animation cam 10 driven in rotation by one revolution per day, intended to move a large rocker 20 during of this rotation so that the latter controls one or more displays of a time value. In other words, the large rocker 20 is configured to act on the display(s) of a time value according to the angular position of the animation cam 10.

[0025] In particular, the animation cam 10 can be linked in rotation to a coaxial wheel 11 meshed for example by a train of the watch movement, in particular by a twenty-four hour wheel.

The large rocker 20 is movable between a first state called "control state" in which it is driven by a pulse from the animation cam 10, during its rotation, and a second state called " state of rest“ in which it tends to move under the effect of a large rocker spring 20 (not shown in the figures).

[0027] It should be noted that, depending on the current month and the current day, the angular position of the large rocker 20 in which it is located when it occupies the rest state and when it occupies the state order varies, as emerges from reading this text.

When rotating a complete revolution of the animation cam 10, the large rocker 20 successively occupies the rest state and the control state.

When it occupies the rest state, the large rocker 20 rests against a stop which can be formed by the animation cam 10, by a structural element of the watch movement or by any other element. Preferably, in the example shown in the figures, the stop is formed by a mobile of months 30 described in detail in the rest of the text.

The control mechanism according to the present invention also comprises a control mobile 40 intended to be driven by at least one step by the large rocker 20 when it occupies the control state, said control mobile 40 being connected to a display of a time value. The large rocker spring 20 is arranged so as to subject the large rocker 20 to a force tending to move it away from the control mobile 40 and to bring it closer to the animation cam 10.

As described in more detail in the remainder of the text in a preferred embodiment of the invention, the display of a time value can be formed by a date display, in particular a units display and a tens display, a display of the days of the week, months, and/or leap years.

As shown in Figure 1 in a preferred embodiment of the invention, the large rocker 20 comprises a body 200 extending between a first and a second end. The large rocker 20 is movable in rotation relative to a structure of the watch movement around an axis located at the first end of the body 200. More particularly, this axis of rotation is advantageously coincident with the longitudinal axis of a transverse shaft 210 fixed to the first end of the body 200 of the large rocker 20. In other words, the transverse shaft 210 is engaged in an opening of the body 200 and extends preferentially on either side of said body 200 , along a longitudinal axis orthogonal to a plane in which the large rocker 20 extends. The transverse shaft 210 extends along a longitudinal axis forming a non-zero angle with the axis of rotation of the animation cam 10, for example the two axes are substantially orthogonal, as visible in the figures.

Advantageously, the transverse shaft 210 comprises a rotation blocking element cooperating with the large rocker 20 in order to secure the transmission, by the transverse shaft 210, of a torque to the large rocker 20.

[0034] Such a rotation blocking element can be formed by a radial tab 211 intended to be fixed to the body 200 of the large rocker 20, as visible in Figures 1, 4 and 5. Thus, the rotation blocking of the The transverse shaft 210 relative to the large rocker 20 is ensured. In other words, this characteristic makes it possible to guarantee that no possible relative slippage can take place, for example in the event of shock to the date control mechanism. This feature also ensures compliance with assembly tolerances when assembling the date control mechanism.

[0035] Alternatively, the rotation blocking element can be formed by a portion of the transverse shaft 210 having a non-circular cross section, for example polygonal or comprising a flat surface, said portion cooperating with the opening of the body 200 comprising then a section of complementary shape.

[0036]Alternatively, the blocking element can be constituted by an adhesive, such as a glue or by a welding point or equivalent.

The transverse shaft 210 has a pivot 212 at each of its ends by which it is intended to be fixed in a movable manner in rotation relative to a structure of the watch movement.

Advantageously, the large rocker 20 comprises a support arm 220 fixed radially to the transverse shaft 210 and designed to rest against the animation cam 10 during its rotation. This support arm 220 is intended to transmit the movement of the animation cam 10 to the large rocker 20 to move it to its control state.

As visible in Figures 1 to 5, the support arm 220 has at one free end, a roller 221 movable in rotation, mounted idle, by means of which it is intended to cooperate with the animation cam 10 This roller 221 is preferably blocked in translation between a shoulder and a head of a screw 222 screwed axially to the free end of the support arm 220. In other embodiments of the invention, the roller 221 can. be blocked in translation by a pin or by any other element projecting opposite the roller.

In summary, the large rocker 20 is adapted to cooperate with the animation cam 10 via the roller 221, the latter rolling against the animation cam 10 when the latter is rotated. Advantageously, the roller 221 has a convex cross section so that when it rests against the animation cam 10, the contact zone between the roller 221 and the animation cam 10 is materialized by a point. This characteristic makes it possible to reduce friction as much as possible so as to promote rolling, and thus makes it possible to avoid any loss of energy from the animation cam 10. In addition, thanks to the shape of the cross section of the roller 221, the contact zone is always materialized by a point, whatever the angle of rotation of the animation cam 10, and consequently, whatever the angle formed between the axis of the support arm 220 and the axis of rotation of the animation cam 10.

[0041] As shown in the top view of Figure 2, the support arm 220 is preferably arranged so that it extends along a longitudinal axis included in a diametrical plane of the animation cam 10. In other examples of embodiments of the invention, the longitudinal axis of the support arm 220 extends in a plane parallel to a diametrical plane of the animation cam 10. Preferably, the body 200 of the large rocker 20 extending in a plane parallel to the plane in which the support arm 220 extends.

As visible in this figure, the animation cam 10 is advantageously of the radial transmission type with external profile 100, the support arm 220 resting by means of the roller 221 against said external profile 100. In the present text, the terms “external profile” of a cam refer to the profile of the outer periphery of the cam constituting a contact zone.

[0043] In the preferred embodiment of the invention shown in Figures 1 and 2, the external profile 100 of the animation cam 10 is spiral. The animation cam 10 advantageously comprises a first portion 101 in the form of a circular sector whose radial section is increasing, considering the direction of rotation of the animation cam 10, and a second portion 102 in the form of a circular sector whose radial section is decreasing, the first portion 101 being more extensive than the second portion 102.

[0044] In other embodiments of the invention, the animation cam 10 can be a heart cam, or more generally, can have an external profile 100 of any shape adapted to transmit a pulse to the large rocker 20 when said animation cam 10 makes a complete revolution, so as to punctually drive the large rocker 20 into the control state.

Preferably, the animation cam 10 is rotated once a day, for example around midnight, using a dedicated mechanism, as described in patent EP3540524. During the rotational stroke of the animation cam 10, three successive times can be considered: – a first time in which the large rocker 20 is in a state of rest and rests against the stop; in the preferred embodiment of the invention, the animation cam 10 and the large rocker 20 are then not in contact with one another; – a second stage in which the animation cam 10 and the large rocker 20 come into contact with one another, the radius of the animation cam 10 facing the roller 221 gradually increasing until it reaches contact of the latter, until the large rocker 20 occupies the control state; – a third time in which, after having been in contact with the maximum radius of the animation cam 10 and having occupied the control state, the large rocker 20 crosses the second portion 102 of the external profile 100 of the animation cam 10 and performs a jump under the effect of the large rocker spring 20 until it returns to its resting state, and rests against the stop.

As shown in particular in Figure 3 in a preferred embodiment of the invention, the control wheel 40 comprises a thirty-one wheel 41, a correction cam 42, a date wheel preferably formed by a units wheel 43 and by a tens wheel 44, all arranged coaxially and linked together in rotation. The large rocker 20 is configured so that, when it occupies the control state, that is to say when changing from one day to the next, it cooperates with the thirty-one wheel 41 via of a first pawl 21 so as to drive the control mobile 40 in rotation by one step and/or it cooperates with the correction cam 42 via a second pawl 22 so as to drive the control mobile 40 rotating one or more steps.

[0047] As visible in Figures 1 and 4, the first and second pawls 21 and 22 are fixed at the level of the second end of the body 200 in a rotatable manner and are each biased by a pawl spring (not shown on the figures). Preferably, the first and second pawls 21 and 22 are fixed so as to be movable in rotation around two distinct axes of rotation.

[0048] In particular, the first pawl 21 is arranged to cooperate with the thirty-one wheel 41 when the large rocker 20 reaches the control state so as to drive the control mobile 40 in rotation by one step, then , when it moves towards the rest state, the first pawl 21 forces the pawl spring with which it is associated so as to retract under the action of a tooth of the thirty-one wheel 41 without cause said thirty-one wheel 41 to rotate.

The second pawl 22 is arranged so as to rest against the correction cam 42 continuously, whatever the state of the large rocker 20, under the effect of the pawl spring with which it is associated . The correction cam 42 includes a notch 420 with which the second pawl 22 is adapted to cooperate at the end of a month, when the large rocker 20 is in the control state, in order to drive the control mobile 40 rotating until its position corresponds to the start of the following month.

Preferably, the second pawl 22 is configured to drive the control mobile 40 by one, two or three additional steps to a driving step of the control mobile 40 caused by the first pawl 21, on the last day of operation. a month of less than thirty-one days until its position corresponds to the start of the following month, according to the angular position of the mobile of months 30, as described below.

[0051] In another exemplary embodiment, when the large rocker 20 is in the control state on the last day of a month of less than thirty-one days, only the second pawl 22 drives the control mobile 40 from at least two, three or four steps, until its position corresponds to the start of the following month, depending on the angular position of the mobile of months 30, the first pawl 21 having no connection with the control mobile 40.

The units wheel 43 and the tens wheel 44 are respectively intended to cooperate with the units and tens displays of a date display, for example in a manner known per se to those skilled in the art.

[0053] The control wheel 40 comprises, in the exemplary embodiment shown in Figures 1 and 3, a month finger 45 linked in rotation with the thirty-one wheel 41 and adapted to drive a month display. More precisely, at the end of each month, once per revolution of the control mobile 40, when the large rocker 20 is in the control state, the month finger 45 cooperates with the month display, for example by the through a cog of months.

The body 200 may include a day finger 46 arranged to cooperate, when the large rocker 20 is in the control state, with a day star 460 comprising seven teeth intended to be linked to a day of the week display . Such a day finger 46, shown in Figure 5, is preferably rigidly fixed, that is to say without degree of freedom, at the level of the second end of the body 200.

[0055] Advantageously, the mobile of the months 30 is configured to constitute an end stop of the large rocker 20 when it is in the rest state. The month 30 mobile is equipped with a month 31 cam connected to the month gear in order to pivot one step at the end of each month and one complete turn in one year, upon action of the month 45 finger. The cam of the months 31 comprises an external profile whose radius is variable, formed by an alternation of bumps 32, that is to say radial protrusions, and hollows 33, that is to say radial recesses .

The large rocker 20 is intended to rest on a bump 32 or on a hollow 33 of the external profile of the cam of the months 31 by means of a support tab 23, when it occupies the rest state , so that depending on the angular position of the month cam 31, the angular position of the large rocker 20 varies. The support tab 23 is arranged between the first and the second end of the large rocker 20, as visible in Figures 1, 4 and 5, and constitutes an excrescence of the body 200 of the large rocker 20.

[0057] In particular, the bumps 32 of the external profile of the month cam 31 correspond to months of thirty-one days, as shown in the detail view of Figure 4, in the sense that the large rocker 20 is intended to rest against a bump 32 when it occupies the state of rest and the current month is a month of thirty-one days. The troughs 33 correspond to months of less than thirty-one days. Preferably, all of the recesses 33 of the external profile of the month cam 31 have the same depth and correspond to a month of thirty days, with the exception of a recess 330, corresponding to a month of twenty-eight days, that is to say in the month of February, the depth of which is greater than that of the other hollows 33. In other words, the radius of the cam of the months 31 at the level of the hollow 330 is less than the radius of the cam of months 31 at the level of the other hollows 33.

The large rocker 20 is configured so that when the support tab 23 rests against a hollow 33 or 330, on the last day of a month of less than thirty-one days, the second pawl 22 is constrained to cooperate with the notch 420 of the correction cam 42 of the control mobile 40 so as to cause it to rotate by one or more additional steps when the large rocker 20 moves towards the control state, in order to 'train the date display until the first day of the next month. In other words, the large rocker 20, the control mobile 40 and the month mobile 30 are configured so that, depending on the angular position of the month mobile 30 and according to the current date, the large rocker 20 drives the control mobile 40 one or more steps when it moves to its command state.

[0059] In the preferred embodiment of the invention, the cooperation between the notch 420 and the second pawl 22 is achieved before the first pawl 21 cooperates with the thirty-one wheel 41. In others In terms, when the large rocker 20 moves to the control state at the end of a month of less than thirty-one days, the control module 40 is rotated initially by one or several steps by the second pawl 22, then a single step by the first pawl 21.

[0060] In particular, the large rocker 20 is configured so that when it occupies the control state on the last day of a month of thirty days, after having occupied a rest state in which the support tab 23 is resting against one of the recesses 33, the second pawl 22 cooperates with the notch 420 of the correction cam 42 in order to rotate the control mobile 40 by an additional step to the driving step caused by the cooperation of the first pawl 21 with the thirty-one wheel 41. The date display thus passes from the last day of a month of thirty days to the first day of the following month when the large rocker 20 is driven into the state of order.

[0061] Furthermore, the large rocker 20 is configured so that when it occupies the control state on the last day of a month of twenty-eight days, after having occupied a rest state in which the tab of support 23 rests against the hollow 330, the second pawl 22 cooperates with the notch 420 of the correction cam 42 in order to rotate the control mobile 40 by three additional steps to the drive step caused by the cooperation of the first pawl 21 with the thirty-one wheel 41. The date display thus passes from the last day of a month of twenty-eight days to the first day of the following month when the large rocker 20 is driven into the state of order.

[0062] In another embodiment of the invention, the large rocker 20 is configured so that when it occupies the control state on the last day of a month of less than thirty-one days, after having occupied a rest state in which the support tab 23 bears against one of the recesses 33 or 330, the second pawl 22 cooperates with the notch 420 of the correction cam 42 in order to rotate the mobile of command 40 of two to four steps so that the date display goes from the last day of the month to the first day of the following month. In this exemplary embodiment, the rotation of the control mobile 40 on the last day of a month of less than thirty-one days is therefore caused solely by the second pawl 22 in order to move to the first day of the following month, the first pawl 21 then only causing the control module 40 to rotate on the last day of a month of thirty-one days.

Preferably, the month wheel 30 comprises a leap year cam 34 coaxial with the month cam 31 and arranged to move in rotation relative to the latter. In particular, the leap year cam 34 is rotated by a reduction gear engaged with the month gear, at the rate of one revolution every four years.

[0064] The leap year cam 34 has an external profile of constant radial section with the exception of a single radial projection 340 arranged so as to be arranged opposite the hollow 330 corresponding to a month of twenty- eight days of the month cam 31 so as to reduce the depth of said hollow 330 and thus limit the movement of the large rocker 20 once every four years. This configuration, when the radial protrusion 340 is arranged opposite the hollow 330 corresponds to a month of twenty-nine days.

[0065] Thus, when it occupies the state of control, on the last day of a month of February during a leap year, that is to say on the twenty-ninth of February, after having occupied a state of rest in which the support tab 23 rests against the radial projection 340, in the hollow 330, the second pawl 22 cooperates with the notch 420 of the correction cam 42 in order to rotate the control mobile 40 of two additional steps to the drive step caused by the cooperation of the first pawl 21 with the thirty-one wheel 41. This rotation makes it possible to drive the date display until the first day of the month of March when the large flip-flop 20 is driven into the control state.

Alternatively, as described above in the text, the rotation of the control mobile 40 can be caused solely by the second pawl 22. In this case, the second pawl 22 drives the control mobile 40 in rotation by three steps.

[0067] Advantageously, the date control mechanism according to the invention can include a date corrector member adapted to act on the large rocker 20 so as to drive it into the control state upon request from a user, for example example to correct the date display. In particular, the date corrector member is intended to be kinematically connected to a control element, such as a pusher, capable of being activated by the user.

[0068] Preferably, the date correcting member can be formed by a date correction rocker comprising a driving arm intended to interact with the large rocker, as visible in Figure 1, and a driven arm intended to receive a force from the control element, for example via a kinematic chain whose design is within the reach of those skilled in the art. The axes of rotation of the large rocker 20 and the date correction rocker are orthogonal in the preferred embodiment of the invention.

[0069] The leading arm advantageously comprises a beveled or convex part, through which it is intended to bear against the large rocker, so as to drive it into the control state. This characteristic makes it possible to promote the sliding of the leading arm on the large rocker and thus to limit the forces involved, in particular the friction forces.

[0070] The control mechanism can, moreover, include a month correcting member (not shown in the figures), for example in the form of a month correction rocker adapted to act on the month display and on the month mobile 30 by action on the month gear, intended to be kinematically connected to a control element, for example a pusher, adapted to be activated by the user.

[0071] By way of example, the month correction member may have the form of a month correction rocker comprising a driving arm intended to interact with a wheel of the month gear and a driven arm intended to receive a force from the control element, for example via a kinematic chain whose design is within the reach of those skilled in the art.

[0072] Alternatively or additionally, the control mechanism may include a day-of-the-week corrector, for example in the form of a day-correction rocker, adapted to act on the day-of-the-week display by action on the day star 460 or on a star linked in rotation with the day star 460 upon request of a control element adapted to be actuated by the user, in a manner analogous to the corrective members previously described.

[0073] More generally, it should be noted that the modes of implementation and embodiment considered above have been described by way of non-limiting examples, and that other variants are therefore possible.

[0074] Furthermore, it goes without saying that the wheels, stars and mobiles described above are held in a stable position by jumpers or by any other means known to those skilled in the art.

Claims (13)

1. Date control mechanism of a watch movement comprising: – an animation cam (10) rotated so as to perform one revolution per day, – a large rocker (20) movable between two successive states when the animation cam (10) makes a complete revolution, including a control state in which it is driven by the animation cam (10) and is supported against this, and a state of rest in which it is driven by a large rocker spring (20), the large rocker (20) comprising a body (200) extending between a first end around which it is movable in rotation and a second free end, – a control mobile (40) intended to be driven by at least one step by the large rocker (20) when it occupies the control state, said control mobile (40) being intended to be connected to a display of a temporal value; the date control mechanism being characterized in that the large rocker (20) comprises a support arm (220) connected to the first end of the body (200) by a transverse shaft (210) and by which the large rocker ( 20) rests against the animation cam (10) during the rotation of the latter, the transverse shaft (210) extending along a longitudinal axis coinciding with the axis of rotation of the large rocker (20) and forming a non-zero angle with the axis of rotation of the animation cam (10). 2. Control mechanism according to claim 1, in which the support arm (220) has at one free end a roller (221) movable in rotation by means of which it rests in support against the animation cam (10) , said roller (221) rolling against the animation cam (10) when the latter is rotated. 3. Control mechanism according to claim 2, in which the roller (221) has a convex cross section so that when it rests against the animation cam (10), the contact zone between the roller (221 ) and the animation cam (10) is represented by a point. 4. Control mechanism according to claim 1 to 3, in which the support arm (220) is arranged so that it extends along a longitudinal axis included in a diametrical plane of the animation cam (10) or in a plane parallel to said diametrical plane, the body (200) of the large rocker (20) extending in a plane parallel to the diametrical plane. 5. Control mechanism according to one of claims 1 to 4, wherein the transverse shaft (210) comprises a rotation blocking element (211) cooperating with the large rocker (20). 6. Control mechanism according to one of claims 1 to 5, in which the transverse shaft (210) has a pivot (212) at each of its ends by which it is intended to be fixed in a movable manner in rotation relative to to a structure of the watch movement. 7. Control mechanism according to one of claims 1 to 6, in which the animation cam (10) is of the radial transmission type with external profile (100), the support arm (220) resting against said profile exterior (100), the latter comprising a first portion in the form of a circular sector whose radial section is increasing, considering the direction of rotation of the animation cam (10), and a second portion in the form of a circular sector whose radial section is decreasing, the first portion being more extensive than the second portion. 8. Control mechanism according to one of claims 1 to 7, in which the control wheel (40) comprises a thirty-one wheel (41), a correction cam (42) and a date wheel (43, 44), all arranged coaxially and linked together in rotation, the large rocker (20) being configured to, when it occupies the control state, cooperate with the thirty-one wheel (41) by means of a first pawl (21) that the body (200) comprises at its second end, and/or to cooperate with the correction cam (42) of the control mobile (40) by means of a second pawl (22) that the body (200) comprises at its second end. 9. Control mechanism according to claim 8, in which the control mobile (40) comprises a month finger (45) linked in rotation with the thirty-one wheel (41), cooperating with a month display once per month. 10. Control mechanism according to claim 8 or 9, wherein the body (200) comprises a day finger (46) arranged to cooperate with a day star (460) intended to be linked to a day display. 11. Control mechanism according to one of claims 8 to 10, comprising a month mobile (30) provided with a month cam (31) intended to pivot by one step each month and whose external profile is formed by an alternation of bumps (32) and hollows (33, 330), corresponding respectively to months comprising thirty-one days and months comprising less than thirty-one days, and against which rests a support tab (23) which presents the large rocker (20) when the latter occupies the rest state, the large rocker (20) being configured so that when it occupies the control state, the last day of a month less than thirty and one day, after having occupied a state of rest in which the support tab (23) rests against a hollow (33; 330), the second pawl (22) cooperates with the correction cam (42) so as to rotating the control mobile (40) so that the display of a time value indicates a time value representative of the following month. 12. Control mechanism according to claim 11, in which the month mobile (30) comprises a hollow (330) having a greater depth than that of the other hollows (33) and corresponding to a month of twenty-eight days, said large rocker (20) being configured so that when it occupies the control state, on the last day of the month of February, after having occupied a rest state in which the support tab (23) rests against said hollow (330), the second pawl (22) cooperates with the correction cam (42) in order to rotate the control mobile (40) so that the display of a time value indicates a time value representative of the following month. 13. Control mechanism according to claim 12, in which the month mobile (30) comprises a leap year cam (34) coaxial with the month cam (31) and intended to pivot by one turn every four years, said leap year cam (34) having an external profile comprising a radial protrusion (340) arranged once every four years opposite the hollow (330) so as to limit the movement of the large rocker (20) , said large rocker (20) being configured so that when it occupies the control state, on the last day of February in a leap year, after having occupied a rest state in which the support tab ( 23) rests against the radial projection (340), the second pawl (22) cooperates with the correction cam (42) in order to rotate the control mobile (40) so that the display a time value indicates a time value representative of the following month.