CH716894B1 - Instant jump clockwork display mechanism. - Google Patents

Abstract

The invention relates to a timepiece display mechanism with instantaneous jump, comprising a Maltese cross mechanism with a crown (10) controlling in part of its course the pivoting of a satellite mobile (300) driven by a movement of clockwork through a cam wheel (456) arranged to move it from an armed position to an unarmed position by an instantaneous movement to rotate a satellite wheel (300), and vice versa in a slower regulated return than the instantaneous displacement, which mobile (456) comprises, coaxial, a cam (16) and a plate (15) comprising a loop (151) for driving an eccentric finger (160) of the cam (16) which controls the pivoting of a carrier (17) driving the crown (10) between two extreme cocking and disarming positions, the loop (151) allowing a free jump of the carrier (17) in the disarming direction, and a duration longer reset time.

Description

Field of the invention

[0001] The invention relates to an instantaneous jump timepiece display mechanism, arranged to be driven by a timepiece movement, and comprising a Maltese cross-type stop mechanism with a director mobile capable of controlling in part of its angular travel the pivoting of at least one mobile satellite.

The invention also relates to a timepiece, in particular a watch, comprising at least one such display mechanism.

The invention relates to the field of display mechanisms for timepieces with complications.

Background of the invention

[0004] The use of Maltese cross stop mechanisms is known to perform certain watchmaking display functions. The best known is the display of the leap year on a timepiece with a perpetual calendar.

[0005] Usually, a Maltese cross mechanism is said to be dragging. The satellite is in continuous rotation around the planet, and the rotation of the satellite on its own axis is also dragging.

[0006] Trailing displays cause uncertainty for the user, especially in the vicinity of the instant of display change, because he does not have the means to know whether the display change has been made or not.

Summary of the invention

The invention proposes to make the jump of a Maltese cross type mechanism instantaneous.

The invention also proposes to produce a display mechanism for a timepiece, in particular a watch, implementing at least one mobile satellite having a specific movement. More particularly, this specific movement comprises at least one phase of continuous movement of rotation of the mobile satellite around an element called planet, and at least one phase of punctual and instantaneous movement of rotation of the mobile satellite on itself, at a place and a specific moment.

[0009] The invention consists in making the occasional rotation of the satellite around its axis instantaneous while guaranteeing its rotation around the planet, without modifying the speed of rotation of the axis of the satellite around the planet.

To this end, the invention relates to a timepiece display mechanism according to claim 1.

[0011] The invention also relates to a timepiece, in particular a watch, comprising at least one such display mechanism.

Brief description of the drawings

Other characteristics and advantages of the invention will appear on reading the detailed description which follows, with reference to the appended drawings, where: FIG. 1 schematically represents the specific movement of a mobile satellite around an element called a planet; the mobile satellite is in continuous rotational movement (arrows A) around the planet, and, in at least one angular position, pivots on itself (arrow B), this pivoting possibly being partial or total depending on the arrangement of the mechanism; FIG. 2 represents, schematically, partially and in plan, part of an instantaneous jump display mechanism according to the invention, where only the constituent elements of a drive mechanism are represented, from a cog of a clock movement, of a star whose arms carry such satellite mobiles, here constituted by planet wheels, each comprising partially truncated teeth, and each arranged to slide on a cylindrical part of a guided annular crown on crown rollers, or to mesh with an external toothed part of this annular crown, according to the angular position of the satellite wheel considered; this star rotates here, without limitation, continuously on star pebbles, and rotates here clockwise; FIG. 3a is a plan view of a detail of FIG. 2 showing such a planet wheel in its sliding position on the cylindrical part of the crown; Figure 3b shows the same detail in perspective; FIG. 4 represents, in a manner similar to FIG. 2, another part of the same instantaneous jump display mechanism according to the invention, in which only the constituent elements of a drive mechanism are represented, from a gear train a clockwork movement and through a cam mobile then a driver, the crown with which the planet wheels cooperate, this drive mechanism being represented in the cocked position of the crown, the arrow indicates the direction counter-clockwise in which the crown will pivot as soon as a feeler of this driver falls following a cochlear cam that this cam mobile comprises, this pivoting movement allowing the planetary wheel to be driven in rotation which then faces the external toothed part of the crown; FIG. 5 is a detail of FIG. 4, showing the cam wheel which comprises, coaxial and superposed, a friction wheel, a plate, and a cochlear cam, the friction wheel driving the plate which comprises a loop in an adjustable manner limitation and drive of an eccentric finger that includes the cochlea cam, on which runs the feeler of the coach which is here a pivoting rake comprising a rake toothing arranged to cooperate with a crown toothing; FIG. 6 represents, similarly to FIG. 4, the same drive mechanism being represented in the disarmed position of the crown; the arrow indicates the clockwise direction, in which the crown is ready to pivot later with respect to the instant illustrated in figure 6, counter-clockwise, during the ascent of the same feeler on the highest point of the cam-snail; Figure 7 is, similarly to Figure 5, a detail of Figure 6; FIG. 8 represents, schematically, partially and in plan, the whole of this instantaneous jump display mechanism, where the star drive mechanism and the crown drive mechanism are combined, to ensure both the orbital movement of the planet wheels with respect to a plate of the movement, and the instantaneous rotational movement of each planet wheel when it comes face to face with the external toothed part of the crown and just before the moment when this crown passes by an instantaneous jump from its armed position to its disarmed position; Figures 9 to 15 represent, similarly to Figure 3, the successive stages of the kinematics of a planet wheel: figure 9 represents the approach position of the satellite wheel which is on the right of the figure, and which slides clockwise, while the satellite wheel visible on the left has just completed its rotation and also resumes a sliding stroke; the crown is in the cocked position; FIG. 10 represents the position before the jump, the satellite wheel arrives in position at six o'clock; the crown is still in the cocked position; figures 11 to 14 break down the jump: in FIG. 11, the satellite wheel is still in the six o'clock position, the crown is now rotating counterclockwise, it is going from the armed position to the disarmed position; in FIG. 12 the crown continues its counter-clockwise course and meshes with the satellite wheel, and begins to make it turn; in FIG. 13 this double synchronized movement continues; in FIG. 14, the double synchronized movement ends, the last tooth of the planet wheel leaves the external crown toothing to present the truncated part of the toothing of the planet wheel facing the cylindrical track of the crown; in FIG. 15, in its position after the jump, the satellite wheel has completed its rotation of a half-turn instantaneously on itself; the satellite wheel, driven by the star, leaves the position at six o'clock and resumes its sliding movement on the cylindrical track of the crown; the crown then returns from its disarmed position to its armed position, but this movement is carried out more slowly than the advancement of the star, so as not to interfere with the operation in progress with the satellite wheel, but with the appropriate offset to be ready to instantly jump the next satellite wheel, which will present itself an hour later in the rotating position at six o'clock in this particular and non-limiting execution; FIG. 16 represents, schematically and in plan, seen from the side of the movement opposite to that of all the preceding figures, the cam wheel set which comprises a friction wheel which is driven through a timer wheel set by the floor, and which drives by friction a trunnion of the plate, and is mounted coaxial with the plate and the cam, and whose angular adjustment relative to the plate allows precise adjustment of the moment of the jump of the crown; FIG. 17 represents the cam wheel set seen from the same side and in perspective; FIG. 18 represents the cam wheel set seen from the same side and in exploded perspective; FIG. 19 represents, schematically and in plan, a timepiece, consisting of a watch, comprising this display mechanism.

Detailed Description of Preferred Embodiments

[0013] Figure 1 exposes the general problem of the orbital movement of a mobile satellite around a fixed or mobile element called planet, where the mobile satellite is in continuous rotational movement (arrows A) around the planet, and, in at least one angular position represented here without limitation at six o'clock, performs a pivoting on itself (arrow B), the angular travel of this pivoting depending on the arrangement of the mechanism.

The invention is illustrated in a particular variant with a single point of rotation of the satellites, it is understood that a particular display mechanism may comprise several such points of rotation distributed over the periphery of the planet, depending on the application desired display.

The invention relates to a timepiece display mechanism 100 with instantaneous jump. This display mechanism 100 is arranged to be driven by a clock movement, and includes a stop mechanism of the so-called "Maltese cross" type with a director mobile 200 able to control, in at least part of its angular stroke, the pivoting of at least one mobile satellite 300.

[0016] According to the invention, this director wheel set 200 comprises a ring gear 10, which is arranged to be driven indirectly in pivoting from a drive wheel set or a roadway 12 that includes a clockwork movement, through a cam wheel set 456.

[0017] This cam wheel set 456 is arranged to move the ring gear 10 from an armed position to a disarmed position by instantaneous movement in a first direction to cause a satellite wheel set 300 to pivot around a satellite axis, and to to pass the crown 10 from the disarmed position to the armed position by a regulated displacement slower than the instantaneous displacement during a return movement in a second direction opposite to the first direction.

The mobile cam 456 comprises, mounted coaxially, at least one plate 15 and one cam 16. The plate 15 is driven indirectly by the roadway 12, and comprises a loop 151, arranged for the stroke limitation and for the drive in abutment position at one end of the loop, of an eccentric finger 160 that comprises the cam 16. The evolving profile 161 of the cam 16 controls the pivoting of a driver 17, which is arranged to drive the crown 10 between two extreme positions of arming and disarming. The loop 151 thus allows, on the one hand a free jump of the trainer 17 which interacts with the cam 16 in the direction of the disarmament, and on the other hand a longer duration of rearmament related to the relative course of the finger 160 and of the loop 151. The usefulness of the loop-finger system is to have an instantaneous fall of the feeler, which when it falls touches the smallest radius of the cam.

[0019] More particularly, the director mobile 200 comprises a first alternation of first sliding zones and first drive zones, and the satellite mobile 300 comprises a second alternation of second clearance zones and second drive zones. The second clearance zones are arranged to slide each in turn on one of the first sliding zones of the director mobile during part of the angular travel of the director mobile 200 corresponding to a rest position of the satellite mobile 300. And the first zones of drive of the director mobile 200 are arranged to, in certain portions of the angular stroke of the director mobile 200, cooperate with the second drive zones that the mobile satellite 300 comprises to drive the mobile satellite 300 in pivoting until the return to cooperation of a second clearance zone with a first sliding zone in a new rest position of the mobile satellite 300.

[0020] More particularly, the driver 17 is a pivoting rake, which is returned by a rake spring 18, and which comprises a rake toothing 170 which is arranged to cooperate with an internal crown toothing 107 that comprises the crown 10 This pivoting rake includes a feeler 171, which is arranged to follow the profile of the cam 16.

[0021] More particularly, the cam 16 is a snail cam with an evolving external profile 161 in a snail shape and a front 162 allowing jumping. And the combination of the loop 151 and the finger 160 allows and limits the return of the probe 171 on the largest radius of the cam 16.

[0022] In a particular embodiment, this snail-shaped external profile 161 grows over the first 180° of the cam, and is followed by a concentric part with zero evolution over the rest of the angular stroke; thus the ring gear, in the armed position, can wait for the arrival of the satellite. Preferably the ascent ramp is not too fast, so as to avoid any interference with the satellite which has just jumped.

Advantageously, the front 162 has a slope which allows the reversibility of the mechanism, which is useful during an adjustment such as a time setting, which may require a backward movement.

[0024] More particularly, the cam wheel set 456 further comprises, mounted coaxially with the plate 15 and the cam 16, a friction wheel 14 which is driven directly or indirectly (for example through a timer wheel set 13) by the floor 12, and which is arranged to drive a journal 152 of the plate 15 by friction, and whose angular adjustment relative to the plate allows precise adjustment of the instant of the jump of the crown 10.

More particularly, the crown 10 is annular and pivots, guided by crown rollers 19 eccentric with respect to its pivot axis. This roller guidance is naturally not exclusive, it is a particular and non-limiting case of a guidance system.

More specifically, the display mechanism 100 comprises a carrier star 4 of each mobile satellite 300, which is pivotally mounted, in continuous pivoting in a single direction of pivoting, and driven by a mobile of the clockwork movement. This continuous movement of the star is a particular, non-limiting case: it is understood that, for example during a setting of the time or the like, the rotation may not be continuous; the same is true for the direction of rotation, which can also be reversed, in particular in the same example of a time-setting.

Preferably, the pivot axes of the crown 10 and the star 4 coincide; more particularly, they are coaxial with the main pivot axis D of the hour wheel 1 or the roadway 12 of the clock movement.

[0028] In a variant, each mobile satellite 300 is mounted loosely pivoting on an arm 7 or the periphery of the star 4.

In another variant, each mobile satellite 300 is pivotally mounted with friction in a housing that includes an arm 7 or the periphery of the star 4.

In particular, each satellite mobile 300, in particular a satellite wheel 8, is mounted at the end 71 of an arm 7, which includes the star 4, and which, in a particular variant, is flexible. This end 71 of arm 7 may also include a bearing for guiding another mobile meshing with the planet wheel 8. The planet wheel 8 may include a planet hub 80, guided in a bore of the end 71 of arm 7 , or in a friction clamp that this end 71 of arm 7 comprises, formed by a complementary flexible arm 72. The planet wheel 8 can also comprise at least one flange 83 for axial limitation with respect to the end 71 of arm 7.

In the particular variant illustrated by the figures, each mobile satellite 300 comprises a truncated toothing comprising teeth 81, 811, 812, 813, 814, 815, 816, which are arranged to cooperate with an external toothed part 108 that comprises crown 10, in particular crown teeth 1802, 1804, which crown 10 comprises for their relative drive. The crown 10 has clearances 1801, 1803, 1805 between its structure and the teeth 1802 and 1804. And each satellite mobile 300 has cleared areas 82, 821, 822, which constitute second clearance areas, allowing the sliding of the satellite mobile 300 on a cylindrical bearing surface 9 smooth that includes the crown 10. In the example illustrated by the figures, the sliding takes place at the level of the teeth 811, 816, on the one hand, and 813 and 814 on the other hand, of the mobile satellite 300, which are collateral to each second clearing zone.

In the example illustrated by the figures, the mobile satellites 300 each comprise two second clearance zones 821, 822, which allow a 180° rotation of the satellite. It is understood that other executions are possible, for example three second free zones for a rotation of 120°, or other; in the same way, these second cleared zones are not necessarily equidistant.

In another variant not shown, each mobile satellite 300 is a Maltese cross with branches each comprising a cylindrical hollow profile constituting a second clearance zone, which is arranged to slide on a cylindrical surface 9 that comprises the crown 10 The branches of this Maltese cross are conventionally separated by recesses, which are arranged to cooperate with a finger, or a tooth, or the like, protruding from the crown 10 for their relative drive in pivoting.

In yet another variant, not shown, the mechanism comprises a Maltese cross which operates on an internal toothing.

In a particular variant embodiment, the display mechanism 100 is a moon phase or moon age display.

In another particular embodiment variant, the display mechanism 100 is a day/night display.

In another particular variant embodiment, the display mechanism 100 is an AM/PM display.

In another particular embodiment variant, the display mechanism 100 is a universal time display.

In another particular embodiment variant, the display mechanism 100 is a calendar, date, day, or month, or leap year display.

The invention also relates to a timepiece 1000 comprising a timepiece movement, which is arranged to drive at least one such display mechanism 100. According to the invention, this display mechanism 100 comprises a drive distinct from the director mobile 200 according to a back and forth pivoting with a limited angular stroke, and from the continuous pivoting in one direction of a carrier star 4 of each satellite mobile 300.

More specifically, this timepiece 1000 is a watch.

The figures illustrate a particular, non-limiting variant of the invention, and provide details of its operation.

The display mechanism 100 is here composed of two subsystems, which are combined with each other: a first mechanism concerns the drive of the star wheel 4, which carries the satellite wheel 300, or the satellite wheels 3000 in the present case: this mechanism is arranged to carry out an information pick-up on the cog of a movement of mechanical or electro-mechanical clockwork, to achieve a reduction in the speed of rotation by gear train, transmission and rotational guidance; - A second mechanism concerns the drive of the crown 10, which carries the fixed tooth of the Maltese cross type; this mechanism is arranged to take information from the cog of a mechanical or electro-mechanical movement, to authorize adjustment by the use of a friction system, to trigger a jump by the use of a mechanism with cam, transmission and rotation guidance.

The subsystem relating to the drive of the star 4, illustrated by Figure 2, aims to rotate at constant speed the mobile satellites 300, here satellite wheels 8, around a plate 5.

To achieve this movement, the information is taken from the center of a watch movement, in particular but not limited to an hour wheel 1 comprising a toothing 11, this information is transmitted by a gear train, comprising in particular a gear wheel 2 comprising teeth 21 and 22, and a driving gear 3, up to star 4, via its internal toothing 43. Star 4 pivots around plate 5 thanks to star rollers 6 guiding a bore 46 of the star 4, and performs one revolution in twelve hours clockwise in the particular case illustrated. Naturally, this revolution in twelve hours is a particular construction illustrated by the figures, and other period values can be chosen for other applications, without departing from the invention. More particularly, the star 4 comprises an internal toothing 43 at the level of an annular rim which pivots, guided by star rollers 6 eccentric with respect to the pivot axis of the star 4. Guide by rollers n It is only a particular case illustrated by the figures, one can imagine other modes of guidance, such as a rotary guidance by rolling, or other. This toothing 43 cooperates with the toothing 32 of the driving gear 3.

[0046] The star 4 here comprises twelve arms 7, these are more particularly but not limited to flexible arms, these arms 7 allow a pivot to be made with each planet wheel 8. The planet wheels 8 are driven in rotation around the plate 5 by the star 4, and they are angularly guided most of the time by the crown 10, by sliding of the toothing of the planet gears 8 against the outer cylindrical surface 9 of the crown 10.

Each satellite wheel 8 performs a complete rotation around the plate 5 in twelve hours, and without turning on itself.

The purpose of the subsystem relating to the drive of crown 10 is to manage the movement and the angular position of crown 10.

The crown 10 passes from the armed position to disarmed by a rapid instantaneous displacement, then returns to the armed position by a slow regulated displacement. More specifically, the climb when returning to the armed position is progressive at the beginning, and zero at the end.

[0050] To achieve these different movements of the crown 10, the information is, in particular and not limited to, taken from the center of the clock movement on a roadway 12, and is transmitted by a timer mobile 13 to a mobile cam 456. This cam wheel 456 comprises a friction wheel 14, which thus has a constant speed of rotation, and completes one revolution in one hour clockwise (in the figures SAM = clockwise ).

[0051] The mobile cam 456 comprises three stages: the friction wheel 14, a plate 15, and a cam 16 which carries an eccentric finger 160. This cam 16 has the function of maneuvering a coach, here a pivoting rake 17, to move the crown 10 in one direction or the other. The friction wheel 14 drives the plate 15 via the friction exerted for example on a shaft bearing 152 of the plate 15 by flexible blades that the friction wheel 14 comprises and which delimit a slot 140. The plate 15 drives the finger 160 of the cam 16 via a loop 151 that this plate 5 comprises, in particular a loop in the form of an arc of a circle concentric with this plate 15.

[0052] The friction allows the precise adjustment of the moment of the jump of the crown 10, and the braid 151 allows a free jump of the rake 17 which interacts with the cam 16.

The rake 17, constrained by a rake spring 18, takes the information on the periphery of the cam 16, and transmits it to the crown 10 by meshing of the internal toothing 107 of the crown 10 with the toothing of rake 170. More particularly, crown 10 pivots around plate 5 thanks to crown rollers 19 which guide a crown bore 119.

The crown 10 therefore performs an instantaneous jump from its armed position to its disarmed position (in the SIAM figures: anti-clockwise direction), to then return slowly in the opposite direction (in the SAM figures: clockwise direction). hands of a watch) in the armed position, and this cycle is repeated periodically, for example every hour in the mechanism illustrated by the figures; naturally this periodicity depends on the type of display, and the period would be different for a display of the age of the moon, for example.

[0055] Figure 4 shows the crown drive system in the armed position, the rake 17 includes a feeler 171 which is supported on a beak that includes the cam 16 on its largest radius, at the limit between a cochlea 161 and a front 162, in particular a substantially straight front, intended to cause the jump.

[0056] Figure 6 shows the crown drive system in the disarmed position; the feeler 171 rests on the smallest radius of the cochlea 161, just after having crossed the front 162.

FIG. 8 illustrates the complete instantaneous jump Maltese cross mechanism according to the invention, which combines the two subsystems set out above. The planet wheels 8 are driven by the arms 7 of the star wheel 4, and rotate at constant speed around the plate 5. When a planet wheel 8 arrives in position at six o'clock, the crown 10 imposes a half turn on it on itself instantly. As a reminder, the planet wheel 8 is in constant rotation around the plate 5 by the star 4, and it is angularly guided by the plate 5.

The sequences of the instantaneous jump of the satellite wheels 8 are as follows: approach position, as seen in Figure 9: the satellite wheel 8 is driven by the star wheel 4, and is guided in sliding by the crown 10, which is in the armed position; position before jump, as seen in Figure 10: the satellite wheel 8 is in the six o'clock position of a timepiece, in particular a watch, this particular position being in no way limiting; crown 10 guides satellite wheel 8; crown 10 is still in the cocked position; jump, broken down in Figures 11 to 14, which show the permutation of recesses 821 and 822 during the turnaround maneuver, and in that order; the satellite wheel 8 is still in the six o'clock position, the crown 10 is now rotating, it passes from the armed position to the disarmed position, and comes, during its run, to mesh with the satellite wheel 8 to impart a half -round ; the satellite wheel 8 has performed an instantaneous U-turn on itself; the tooth 811 has passed into the first recess 1801 of the crown 10, then the second tooth 812 into the second recess 1803 after the first crown tooth 1802, then the third tooth 813 into the third recess 1805 after the second crown tooth 1804 , leaving the second mobile recess 822 to come progressively towards the cylindrical bearing surface 9, that is to say that the lateral flanks of the teeth 813 and 814 come to slide on this bearing surface 9; position after the jump, as seen in figure 15: the satellite wheel 8 is guided by the crown 10, and, driven by the star wheel 4, it leaves the position at six o'clock, and is guided by its teeth 813 and 814 , which frame its second recess 822, on the cylindrical bearing surface 9 of the crown 10. The crown 10 then returns from its disarmed position to its armed position, but this movement is carried out more slowly than the advancement of the star 4, for not to interfere with the operation in progress with the satellite wheel 8, but with the appropriate delay to be ready to instantly jump the next satellite wheel, which will appear one hour later.

The invention has substantial advantages. Above all, it makes it possible to perform the instantaneous jump of a Maltese cross mechanism. Performing such an instantaneous jump directly impacts the display, and ensures reading security for the user. The indicator passes from one position to another frankly, without intermediate position; for example the AM/PM change at twelve o'clock. Thus the user perceives information whose clear reading is precise and unambiguous.

The mechanism according to the invention tolerates backward adjustment, for example when setting the time or similar, with a fault in synchronization of the moment of the jump,

Claims (17)

1. Instantaneous jump timepiece display mechanism (100), arranged to be driven by a timepiece movement, and comprising a Maltese cross-type stop mechanism comprising a director wheel set (200) capable of controlling in a part of its angular stroke the pivoting of at least one satellite mobile (300), characterized in that the said steering mobile (200) comprises a ring gear (10) arranged to be driven indirectly in pivoting from a roadway (12) that comprises the clock movement through a cam wheel set (456) with which the display mechanism (100) is fitted, said cam wheel set (456) being arranged to move said crown (10) from one position armed to an unarmed position by an instantaneous displacement of said crown (10) in a first direction to make the satellite mobile (300) pivot around a satellite axis, and to move said crown (10) from said unarmed position to said armed position by a regular displacement width of said crown (10) slower than said instantaneous movement during a return movement in a second direction opposite to said first direction, and in that said cam wheel set (456) comprises, mounted coaxially, a plate (15) and a cam (16), said plate (15) being driven indirectly by said roadway (12) and comprising a loop (151) for driving an eccentric finger (160) which comprises said cam (16) whose profile controls the pivoting of a driver (17) arranged to drive said crown (10) between the cocked and uncocked positions, said loop (151) allowing on the one hand a free jump of said driver (17) which interacts with said cam (16 ) in the disarming direction, and on the other hand a longer rearmament duration linked to the relative path of said finger (160) and of said loop (151), each satellite mobile (300) comprising a truncated toothing comprising teeth (811 , 812, 813, 814, 815, 816) arranged to cooperate with crown teeth (1802 , 1804) that comprises the crown (10) for their relative drive, and open areas (821, 822) arranged to slide on a cylindrical surface (9) that comprises said crown (10). 2. Display mechanism (100) according to claim 1, characterized in that said director mobile (200) comprises a first alternation of first sliding zones and first drive zones, and said satellite mobile (300) comprises a second alternation of second clearance zones formed by clearance zones (821, 822) and second drive zones, said second clearance zones being arranged to slide each in turn on one of said first sliding zones of said steering wheel set during a part of the angular travel of said steering mobile (200) corresponding to a rest position of said satellite mobile (300), and said first driving zones of said steering mobile (200) being arranged for, in certain portions of the angular travel of said mobile director (200), cooperating with said second drive zones that said mobile satellite (300) comprises to pivotally drive said mobile its tellite (300) until the re-engagement of a said second release zone with a said first sliding zone in a new rest position of said mobile satellite (300). 3. Display mechanism (100) according to claim 1 or 2, characterized in that said driver (17) is a pivoting rake recalled by a rake spring (18) and comprising a rake toothing (170) arranged to cooperate with an internal crown toothing (107) that said crown (10) comprises, and comprising a feeler (171) arranged to follow the profile of said cam (16). 4. Display mechanism (100) according to one of claims 1 to 3, characterized in that said movable cam (456) further comprises, mounted coaxially with said plate (15) and said cam (16), a wheel (14) driven directly or indirectly by said roadway (12) and arranged to drive said plate (15) by friction, and the angular adjustment of which relative to said plate allows precise adjustment of the instant of the jump of said crown (10). 5. Display mechanism (100) according to one of claims 1 to 4, characterized in that said crown (10) is annular and pivots guided by crown rollers (19) eccentric with respect to its pivot axis. 6. Display mechanism (100) according to one of claims 1 to 5, characterized in that said display mechanism (100) comprises a star (4) carrying each said mobile satellite (300), and pivotally mounted coaxially with said crown (10), in continuous pivoting in a single direction of pivoting, driven by a wheel set of said clockwork movement. 7. Display mechanism (100) according to claim 6, characterized in that said star (4) has internal teeth (43) at an annular rim. 8. Display mechanism (100) according to claim 6 or 7, characterized in that each said mobile satellite (300) is mounted freely pivoting on an arm (7) or the periphery of said star (4). 9. Display mechanism (100) according to claim 6 or 7, characterized in that each said mobile satellite (300) is pivotally mounted with friction in a housing that includes an arm (7) or the periphery of said star (4 ). 10. Display mechanism (100) according to one of claims 6 to 9, characterized in that each said mobile satellite (300) is mounted at the end of an arm (7) which is flexible and which comprises said star (4). 11. Display mechanism (100) according to one of claims 1 to 10, characterized in that said display mechanism (100) is a moon phase or moon age display. 12. Display mechanism (100) according to one of claims 1 to 10, characterized in that said display mechanism (100) is a day/night display. 13. Display mechanism (100) according to one of claims 1 to 10, characterized in that said display mechanism (100) is an AM/PM display. 14. Display mechanism (100) according to one of claims 1 to 10, characterized in that said display mechanism (100) is a universal time display. 15. Display mechanism (100) according to one of claims 1 to 10, characterized in that said display mechanism (100) is a date, day, or month, or leap year display. 16. Timepiece (1000) comprising a timepiece movement arranged to drive at least one display mechanism (100) according to one of claims 1 to 15, characterized in that said display mechanism (100) comprises a separate drive of said director mobile (200) according to a reciprocating pivoting with a limited angular travel, and continuous pivoting in one direction of a star wheel (4) carrying each said satellite mobile (300). 17. Timepiece (1000) according to claim 16, characterized in that said timepiece (1000) is a watch.