CH703330B1 - advance mechanism by periodically skipping a carousel cage. - Google Patents

Abstract

The invention relates to a periodic jump feed mechanism (100) for a carousel cage (30) carrying a wheel (42) and an exhaust pinion (41) and an anchor (50) cooperating with said wheel ( 42) and a balance-spring (80), comprising: - retaining means (70) cooperating with said cage (30) for, depending on their movement or not, allow or prohibit its pivoting; - Stop means (60) cooperating with said retaining means (70) for, depending on their position, to allow or prohibit the pivoting; It is characterized in that: - the trajectory of said retaining means (70) interferes with that of said stop means (60), which are, as well as the previous ones, external to said cage (30); Said cage (30) continuously pushes said retaining means (70) against said stop means (60), for pivoting when said stop means (60) releases said retaining means (70), and for stopping said cage (30) when they block them. The invention relates to the field of mechanical watchmaking.

Description

The invention relates to an advance mechanism by periodic jump of a pivoting cage about a cage axis, said cage carrying an escape wheel and an escape pinion and an anchor cooperating with said escapement wheel and with a sprung balance, said mechanism comprising: a motion transmission train driven by an input driving means for pivotally driving said cage and said exhaust pinion; pivoting retaining means arranged to cooperate with said cage for, as they pivot or are stopped, allow or prohibit the pivoting of said cage; pivoting stop means arranged to cooperate with said retaining means, for, according to the pivoting angular position of said pivoting stop means, allow or prohibit the pivoting of said retaining means.

The invention relates more particularly to an advance mechanism by jumping a carousel cage to second dead.

The invention also relates to a carousel comprising a carousel cage and such a mechanism.

The invention relates to the field of watchmaking.

[0005] It relates more particularly to the field of complicated watches.

The display with a jump, said dead second, or dead minute, or with any other time interval, is a complication always difficult to achieve because the known achievements cause a relatively brutal jump, which results in shocks in the mechanism, which affect the exhaust, which is not optimal for the proper functioning and longevity of the watch.

These known embodiments generally combine a mechanism with cooperation of a star and a whip, on the one hand, and a constant force device on the other hand, to moderate the effects of shock on the movement.

[0008] Thus, the Swiss patent CH 47 297 in the name of Pellaton-Schild describes, as early as 1907, a second lightning dead, with two field wheels connected to each other by a spiral spring, and one of which causes the exhaust pinion, which is coaxial and attached to a star with protruding teeth. The engine cylinder drives, through a gear, a pinion carrying a whip, which bears each time on a tooth of the star, their relative pivoting generating a position where the whip escapes the tooth, lightning, and takes one full turn before coming back to abut another tooth of the star.

[0009] Patent application document EP 1 319 997, in the name of Richemont International SA, describes a tourbillon mechanism incorporating a device with constant force.

This tourbillon mechanism comprises a pivoting cage driven by a drive wheel, the tourbillon cage is coaxial with a pivoting rocker provided with a balance spring balance and with a fixed second wheel, and is a carrier in three distinct eccentric positions, an eccentric escapement wheel, a first anchor, and a stop wheel which meshes with this fixed second wheel. The escape wheel cooperates with this first anchor provided with two pallets. Coaxial with this escapement wheel, a constant force device comprises a spiral escapement spring, integral at one end with the escape wheel, and at a second end with a force compensation disc. The latter is integral in rotation with an armature ring of the exhaust spring, and a pinion of armoring ring which is associated with it and which cooperates with the fixed second wheel.

Coaxially fixed to the escape wheel, a Reuleaux said cam of substantially triangular shape cooperates with a fork that includes a second coaxial anchor pendulum, which pivots about the axis of the tourbillon cage. This second anchor comprises a cam arranged to cooperate with a fork and a dart carried by the first anchor. The second anchor comprises two vanes arranged to cooperate with radially projecting teeth that includes the stop wheel.

The rocker is driven under the effect of the preload of the exhaust spring, and is returned by the spring balance spring. Depending on the number of teeth of the escape wheel, the balance carries a number of alternations, for example five with a wheel of fifteen teeth, before the stop wheel and the tourbillon cage are released by the cam Reuleaux and the second anchor focused on the pendulum. Depending on its number of teeth, the stop wheel performs a given angular deflection, for example 90 °, before being stopped again by one of the pallets of the second anchor focused on the balance. As the stopwheel and the stop gear are carried by the vortex cage, and as the stop gear meshes with the fixed seconds wheel, this pivoting of the stopwheel drives that of the tourbillon cage. . And this fact this pivoting also causes the pivoting of the arming ring which is fixed on the cage and also meshes with the seconds wheel, resulting in the re-tensioning of the spiral escapement spring, because the escape wheel is then blocked by the first anchor. By repeating this cycle, the exhaust spring is periodically extended. It thus accumulates enough energy to deliver a sufficient torque to maintain oscillations of the balance.

This compensation mechanism is intended to deliver a constant torque.

The first end of the spiral escapement spring is fixed on a first pin secured to a first spiral escapement spring ferrule connected to the escape wheel. The second end of the spiral escapement spring is fixed on a second pin integral with a second movable spiral escapement spring ferrule.

The spiral exhaust spring, once stretched, exerts a force on the first pin, and thus exerts a torque on a first arm that includes the force compensation disk that includes the constant force device. Indeed, the latter comprises a first and a second arm, arranged to bear respectively on the first and the second pin, and the bearing faces of these arms are aligned with each other but in an off-axis direction relative to the axis of the escape wheel. The second arm presses on the second pin and transmits the torque to the fixed shell spiral spring and the escape wheel. Due to the eccentric arrangement of the direction of the two arms, the lever arms of the forces exerted by and on the pins are variable depending on the angular position of the force compensation disk, which ensures a constant torque on the escape wheel, despite the loss of tension of the exhaust spring during the stop of the entire train from the spring to the stop wheel.

During each alternation of the balance wheel, the escape wheel is released from the first anchor, and pivots at an angle, under the action of the spiral spring exhaust, as the first spiral spring ferrule and the force compensation disc, while the reinforcement ring and the stop wheel are locked. At each fifth alternation, the stopwheel and the tourbillon cage are released.

This patent document EP 1 319 997 thus describes a perfectly functional system, which provides a visualization of the second at the cage of a vortex, but which remains very complex, and requires a constant force device, still complicated by a compensation mechanism. It necessarily incorporates two spiral springs, two anchors, a cam fork device, and, in addition to a high production cost due to the number and complexity of components, is relatively fragile and difficult to properly adjust.

The patent application EP 1 772 783 in the name of MONTRES BREGUET SA describes a watch movement comprising a constant-force device, and a dead-minute display on the center wheel, which is capable of causing a vortex in good conditions with the constant force device. It comprises a mobile of average, which makes a turn in several minutes, and which constitutes the input element of a device with constant force. The output element of this spiral spring device is constituted by a second wheel of average, which meshes with the pinion of seconds, which is secured to a tourbillon cage This second wheel of medium is integral with a star, which releases periodically , in this case once a minute, a stop gear meshing with the average input moving, which cooperates with the center wheel, which thus makes a jump per minute. This mechanism minimizes the transmission of shocks between the constant force device and the exhaust.

In each case, the constant force device provides an advantage, which is to ensure a relatively constant engine torque to the exhaust, but which necessarily represents a large footprint and cost.

The invention proposes to provide a more economical alternative carousel second dead, using the simplicity of star and whip devices, but reducing shocks, and requiring the least possible additional components, and in a volume on more reduced possible.

For this purpose, the invention relates to an advance mechanism by periodic jump of a pivoting cage about a cage axis, said cage carrying an escape wheel and an exhaust pinion and a anchor cooperating with said escape wheel and with a balance-balance, said mechanism comprising: <tb> - <SEP> a motion transmission train driven by an input drive means for pivotally driving said cage and said exhaust gear; <tb> - <SEP> pivoting retaining means arranged to cooperate with said cage for, depending on whether they pivot or are stopped, allow or prohibit the pivoting of said cage; <tb> - <SEP> pivoting stop means arranged to cooperate with said retaining means, for, according to the pivoting angular position of said pivoting stop means, allow or prohibit the pivoting of said retaining means; <tb> and characterized in that: <tb> - <SEP> said retaining means have a path interfering with that of said stop means, and are, as well as said stop means, external to said cage; <tb> - <SEP> said motion transmission gear meshes permanently with said exhaust pinion to rotate it about an exhaust axis carried by said cage, and tends to cause said cage to pivot about said axis cage through said exhaust shaft; <tb> - <SEP> said cage continuously pushes, under the action of said motion transmission train, said retaining means against said stop means, to rotate said cage when said stop means pivotally release said retaining means, and to stop said cage when said stop means block said retaining means.

According to a particular characteristic of the invention, said stop means comprise a star integral with a star gear driven permanently, and in that said retaining means comprise a whip integral with a whip pinion. meshing directly or indirectly with said cage, the trajectory of said whip interfering with that of said star, to rotate said cage when said star releases said whip, and stop otherwise.

According to another particular characteristic of the invention, said star gear is permanently driven by a star train gear which is linked to said motion transmission train, directly or via said exhaust pinion. .

According to a particular characteristic of the invention, said retaining means and said stop means are arranged so as to make said cage a jump per second.

The invention relates more particularly to an advance mechanism by jumping a carousel cage to dead second.

This new achievement is distinguished by its great simplicity, the low number and low cost of additional components, and their very small footprint.

The invention also relates to a carousel comprising a carousel cage and such a mechanism.

The invention also relates to a timepiece comprising such a mechanism, or such a carousel.

Other advantages and features of the invention will appear in detail in the description which follows, with reference to the indexed figures, in which: <tb> fig. 1 <SEP> schematically shows in plan view a jump advance mechanism according to the invention, in a preferred embodiment; <tb> fig. 2 <SEP> represents, schematically, partially, and in plan view, a timepiece comprising a jump advance mechanism according to a second embodiment; <tb> fig. 3 <SEP> represents a detail of FIG. 2.

The advance mechanism 100 according to the invention is a periodic jump feed mechanism of a display means of a temporal magnitude, in particular of the second, comprising: input drive means 10, pivotally movable relative to a platen; a motion transmission train 20 driven by said input drive means 10, and whose components are pivotally movable relative to a platen; a carousel cage 30, pivotally movable relative to a plate. This cage 30 pivots about a cage axis, and carries an exhaust mechanism 40 comprising an escape wheel 42 and an escape gear 41 and an anchor 50, which cooperates with the escape wheel 42 and with a balance spring 80. Preferably, but not necessarily, the escape wheel 42 and the exhaust pinion 41 are coaxial.

The motion transmission train 20 is arranged to pivotally drive the exhaust pinion 41 permanently and the cage 30 when the latter is free to rotate.

In particular, the advance by jump is performed at this cage 30: the principle of the invention is to constrain the pivoting movement of the cage at a certain period, which is not necessarily determined by the frequency of the oscillator as is the case usually, but which is chosen at a particular rate, for example in the embodiment described below where the cage passes from second to second by marking the second.

To achieve this advance by jump, the mechanism 100 comprises: retaining means 70, preferably pivoting, arranged to cooperate with the cage 30 for, depending on whether they pivot or are stopped, allow or prohibit the pivoting of the cage 30; stop means 60, preferably pivoting, arranged to cooperate with the retaining means 70, for, depending on the position of the stop means 60, in particular the angular position of pivoting, allow or prohibit the movement of these retaining means 70 especially the pivoting movement when they are pivoting.

According to the invention, the retaining means 70 have a trajectory interfering with that of the stop means 60. The retaining means and the stop means 60 are arranged outside the cage 30, that is to say that is, they are not worn by the cage 30.

The motion transmission gear 20 meshes permanently with the exhaust pinion 41 to rotate about an exhaust axis carried by the cage 30, and it tends to drive the cage 30 pivoting around the shaft axis via the exhaust axis.

In a particular way to the invention, the cage 30 continuously pushes, under the action of the motion transmission train 20, the retaining means 70 against the stop means 60, to rotate the cage 30 when the stop means 60 release, in particular pivotally, the retaining means 70, and to stop the cage 30 when the stop means 60 block these retaining means 70.

Two embodiments are illustrated by the figures. The preferred embodiment corresponds to FIG. 1, the following numerical examples relating to the number of teeth of the components of the gear train are a non-limiting example of embodiment. In the same way the mechanism according to the invention, which is described here for the display by leap of a second dead, is applicable to the display of another dead magnitude, minute or other, the calculation of different gears and wheels being carried out accordingly.

The input drive means 10 is conventionally arranged to receive energy in the form of a torque transmitted by energy storage means such as barrel, weight, or the like. In the preferred embodiment as visible in FIG. 1, this input drive means 10 is a wheel of medium 11, which performs one revolution per hour, and comprises N1 teeth, for example here 96 teeth. This medium wheel 11 rotates continuously, as long as the energy storage means are able to deliver energy to the mechanism.

The motion transmission train 20 is of very variable composition. It comprises here a pinion of average 21 and a wheel of average 22, respectively of N2 and N3 teeth, in Example 8 and 90 teeth. The average gear 21 meshes with the medium wheel 11.

The average wheel 22 meshes with a star drive mobile 61, at a star drive intermediate gear 62 having N4 teeth coupled to an intermediate star drive wheel 63 having N5 teeth, which respectively have here N4 = 8 and N5 = 80 teeth, so that the intermediate star-drive wheel 63 drives a star gear 64 of N6 teeth, here N6 = 15 teeth, so as to perform a star revolution 65 (N1xN3xN5) / (N2xN4xN15x60) = (96x90x809 / (8x8x15x60) = 5 seconds This star gear 64 comprises N15 teeth, and carries a retaining star 65 including wing wings 66, here N15 = 15 and NE = 5, and a given point is reached by a wing with a period T = NEx (N1xN3xN5) / (N2xN4xN15x60x60) = 1 second in this case.This retaining star 65 thus rotates continuously under the action of the drive means input 10 and the motion transmission train 20.

Moreover, the average wheel 22 having N3 teeth, here N3 = 90, meshes with a second gear 23, having N8 teeth, here N8 = 10 teeth. This second gear 23 is secured to a second wheel 24 having N9 teeth. This second wheel 24 meshes conventionally with an exhaust pinion 41 having N10 teeth. In the present example, the second pinion 23 has N8 = 10 teeth, and the second wheel 24 has N9 = 105 teeth, while the exhaust pinion 41 has N10 = 7 teeth and is connected to an escape wheel 42 which comprises N11 = 15 teeth and which is arranged to cooperate with a pivoting anchor 50 which cooperates with a balance spring 80.

The cage 30 is preferably a carousel cage, as visible in the figures, and has a toothing 31 with N7 teeth, and is pivotable about a cage axis. This cage 30 comprises a point of attachment of a first end of a balance spring balance 82 whose other end is fixed to a rocker 81 pivotally movable, preferably around this shaft axis, in the latter case the cage 30 is thus mounted coaxial with the sprung balance 80 which is constituted by the balance 81 and the spiral balance spring 82.

This cage 30 carries: the escape mechanism 40 comprising an escapement wheel 42 pivoting about an escape axis parallel to this cage axis, preferably eccentrically in a preferred embodiment as visible in the figures; an anchor 50 pivoting about an anchor axis parallel to this cage axis and arranged to cooperate with the escape wheel 42, preferably eccentrically in a preferred embodiment as visible in the figures.

It is understood that, under the action of the input drive means 10 here constituted by the medium wheel 11, and the motion transmission train 20, here by the average gear 21, the wheel of mean 22, the second gear 23 and the second wheel 24, the exhaust pinion 41 is permanently driven by the second wheel 24. This second wheel 24 exerts on the exhaust pinion a torque that tends to both, on the one hand to rotate the exhaust pinion 41 on itself, to regulate, by means of the escape wheel 42 and the anchor 50, the oscillation of the sprung balance 80, and secondly to rotate the axis of this exhaust pinion 41 about the pivot axis of the second wheel 24.

The pivot axis of the second wheel 24 is coincident with the pivot axis of the cage 30 which carries the pivot axis of the exhaust pinion 41. The pivoting of the second wheel 24 tends therefore always to cause a pivoting of the cage 30 in the same direction as that of the second wheel 24, here in the clockwise direction. Therefore, if an obstacle prevents the pivoting of the cage 30, only the pivoting movement of the exhaust pinion 41 about its axis takes place, the regulation of the oscillator is never interrupted. If we release the pivoting of the cage 30 by removing the obstacle, both the cage 30 pivots in the same direction as the second wheel 24, and the exhaust pinion 41 pivots about its axis in the same way as in the previous case.

The retaining means 70, preferably pivoting, are arranged to cooperate with the cage 30 for, depending on whether they are in motion or are at a standstill, allow or prohibit the pivoting of the cage 30; in the present embodiment, they comprise a retaining mobile 77. This retaining mobile 77 comprises a wheel or a pinion meshing with the toothing 31 that includes the cage 30.

The stop means 60, preferably pivoting, are arranged to cooperate with these retaining means 70, for, depending on the angular position of pivoting of these stop means 60 when they are pivoting, allow or prohibit the pivoting of the retaining means 70. Preferably, these stop means 60 comprise a retaining star 65, integral with a star pinion 64, as described above, permanently pivoted and each tooth 66 is arranged to cooperate with this whip 76, and stop and periodically release the whip 76, according to the angular position of the retaining star 65. This drive star pinion 64 can be performed, preferably as visible in the this exemplary embodiment, by the transmission train 20, directly or via the exhaust pinion 41.

The pivoting retaining means 70 are constituted, in the example of the figures, by a whipstock 74 having a whip gear 75 comprising N14 teeth, and which carries at least one whip 76, pivotally movable around the lug. the axis of the whipstock 74, and arranged to cooperate with a retaining star 65. The trajectory of the whip 76 interferes with that of the star 65, to rotate the cage 30 when the star 65 releases the whip 76, and the stop otherwise. The whip gear 75 meshes directly or indirectly with the toothing 31 of the cage 30.

In certain positions, such as that shown in FIG. 1, the whip 76 is kept under tension, resting on a flange 66 of the retaining star 65, until it reaches an angular position allowing the release of the whip 76, or the whip arm if the whip 76 is multi-arm, double arm or star for example.

Preferably, as visible in FIG. 1, the retaining device 77 comprises an inverting mobile 71 in engagement with the toothing 31 on the one hand, this inverting mobile 71 consisting of an inverter pinion 72 meshing with the wheel 31, and an inverter wheel 73 integral with this inverter pinion 72, and with the whipstock 74 on the other hand. The whipless gear 75 meshes with the reversing wheel 73. The whip gear 75 then co-operates with the toothing 31 of the cage 30 via the inverting mobile 71.

In the example of FIG. 1, when the whip 76 is released by the tooth 66 of the star 65 which held it at a standstill, that is to say every second in the case in point, it authorizes the pivoting of the whipstock 74 here by one complete revolution, until the whip 76 returns to abutment on another wing of the retaining star 65. If the whip 76 is multi-armed, the pivoting amplitude is reduced accordingly, for example a half turn if the whip 76 has two opposite arms as in the example of FIG. 3.

In the present application, which attempts to visualize a dead size, in particular a dead second, at the level of the movement of the cage 30, it is preferable to perform a complete turn of the whipstock 74 to use, in a preferred embodiment as shown in FIG. 1, an inverter mobile 72 adapted to the desired display direction, and a certain damping shock, through the interposition of a gear reducer. In the present example, the whip gear 75 comprises N14 = 10 teeth, cooperating with an inverter wheel 73 of N13 = 30 teeth connected to an inverter gear 72 of N12 = 9 teeth. This reversing gear 72 meshes directly with the cage 30, and for each turn of the whipstock 74, it lets 3 teeth of the toothing 31 of the cage 30 which have N7 = 180 therein, the cage 30 then 60 jumps per minute. The inverting mobile 72 makes it possible to rotate the whipstock 74 in the same direction as the cage 30.

This design is advantageous because it makes it easy to choose the size that you want to display with a jump, whether it is for example the fifth of a second, the ten seconds, the minute, or other, by a simple judicious calculation of the gear train. It also allows a derivative design with a cage turn in a duration other than a minute, for example in thirty seconds.

The number of revolutions per second ωE performed by the star 65 is the result of the calculation relating to the gear train 20 and the star driver 61:

ΩE = Ω x (N1xN3xN5) / (N2xN4xN15x60x60), where Ω is the angular speed in revolution per hour of the wheel of high average 11, Ω = 1 in the case in point; in the example presented it is: ωE = 1x (96x90x80) / (8x8x15x60) = 0.20 turn per second. The star 65 here comprises NE = 5 wings, a given point is reached by a wing 66 of the star 65 with a period T: T = ωE x NE = (N1xN3xN5) / (N2xN4xN15x60) x NE = 0.20x5 = 1 second.

The number of teeth of the toothing 31 released during each turn of the whip is equal here, for a single-arm whip, to: N14xN12 / N13 = 10x9 / 3 = 3. The examples of gear shown here correspond to a frequency of the oscillator of 3 Hz, with a cage 30 equipped with a gear 31 of 180 teeth, and rotating in one minute. Naturally we can define other gears to have a toothing 31 of 60 or 120 teeth, or to change the slewing speed of the cage. Similarly, it is possible to modify the number of arms of the whip 76, the above calculation being presented for the example of a single arm, and therefore of a complete turn of whip between two consecutive teeth of the star. , thus a whip with n arms, for example n = 2 as visible in FIG. 3, would pass only a corresponding portion 1 / n turn of the whip gear 75, and therefore (N14xN12) / (nxN13) teeth of the toothing 31. In this example of FIG. 1, each turn of the whipstock 74 thus passes N14xN12 / N13 = 3 teeth of the toothing 31 of the cage 30, it then performs N7 / (N14xN12 / N13) = 60 jumps per revolution.

The cage 30 rotates at the speed: ΩC = (N14xN12 / N13) x 60 / (TxN7) revolutions per minute, in this example of whip 76 with a single arm. Here, she does one lap per minute.

Figs. 2 and 3 illustrate a second embodiment, without an inverting gear, and with a whip having two whip arms, the whipstock 74 then makes a U-turn before a whip arm returns to bear on a flange 66 of the star 65. FIG. 3 illustrates the very small dimension of the star 65 and the whipstock 74 relative to the gear train and to the cage 30.

In this example of FIG. 3, the transmission train 20 is identical to that of FIG. 1, as well as the exhaust mechanism 40. The whip 76 has n = 2 arms. On the other hand, this variant embodiment does not comprise an inverting mobile 71, the whipstock 74 comes directly meshing with the toothing 31 of the cage 30. The whip gear 75 here comprises N1 4 = 6 teeth. Each passage of a tooth 66 of the star allows the whip gear 75 to make 1 / n = 1/2 turn, which releases N14x 1 / n = 6x1 / 2 = 3 teeth of the toothing 61. The cage 30 therefore performs N7 / (N14x1 / n) = 180/3 = 60 jumps per turn. The period T is identical to that of FIG. 1. The cage 30 rotates at speed QC = (N14x1 / n) x 60 / (TxN7) = 3x60 / (1x180) = 1 revolution per minute.

The invention relates more particularly to a mechanism 100 advance by jumping a carousel cage to second dead.

The invention also relates to a carousel comprising a carousel cage 10 and such a mechanism 100.

The invention also relates to a timepiece comprising such a mechanism 100, or such a carousel.

Claims (12)

1. mechanism for advancing by periodic jump (100) of a cage (30) pivoting about a shaft axis, said cage carrying an escape wheel (42) and an exhaust pinion (41) as well as an anchor (50) cooperating with said escape wheel (42) and with a balance spring (80), said mechanism (100) comprising: <tb> - <SEP> a motion transmission train (20) driven by an input drive means (10) for pivotally driving said cage (30) and said exhaust gear (41); <tb> - <SEP> pivoting retaining means (70) arranged to cooperate with said cage (30) for, as they pivot or are stopped, allow or prohibit the pivoting of said cage (30); <tb> - <SEP> pivoting stop means (60) arranged to cooperate with said retaining means (70), for, according to the pivoting angular position of said pivoting stop means (60), allow or prohibit the pivoting said holding means (70); <tb> and characterized in that: <tb> - <SEP> said retaining means (70) have a trajectory interfering with that of said stop means (60), and are, as well as said stop means (60), external to said cage (30) . 2. Mechanism (100) according to claim 1, characterized in that said stop means (60) comprise a star (65) integral with a star gear (64) permanently driven, and in that said means retaining means comprise a whip (76) integral with a whip gear (75) meshing directly or indirectly with said cage (30), the trajectory of said whip (76) interfering with that of said star (65), for pivoting said cage (30) when said star (65) releases said whip (76), and stop it otherwise. 3. Mechanism (100) according to claim 2, characterized in that said pinion star (64) is permanently driven by a star drive train which is connected to said motion transmission train (20), directly or by via said exhaust pinion (41). 4. Mechanism (100) according to one of the preceding claims, characterized in that said retaining means (70) and said stop means (60) are arranged to make said cage (30) a jump by second. 5. Mechanism (100) according to one of the preceding claims, characterized in that said cage (30) is coaxial with said sprung balance (80). 6. Mechanism (100) according to one of the preceding claims, characterized in that said escape wheel (42) and said exhaust pinion (41) are coaxial. 7. Mechanism (100) according to one of the preceding claims, characterized in that said escape wheel (42) and said exhaust pinion (41) are eccentric with respect to said cage (30). 8. Mechanism (100) according to one of the preceding claims, characterized in that said retaining means (70) comprise a whip gear (75) carrying a whip (76) arranged to cooperate with said stop means (60) and of interfering trajectory with said stop means (60), said whip gear (75) cooperating with a toothing (31) that comprises said cage (30), via an inverting mobile (71). ). 9. Mechanism (100) according to one of the preceding claims, characterized in that said input drive means (10) comprises a wheel of medium (11), which has an angular speed of Ω turn per hour and comprises N1 teeth, and in that said motion transmission train (20) comprises an average gear (21) and an average wheel (22), respectively of N2 teeth and N3 teeth, said average gear (21) meshing with said medium wheel (11), said average wheel (22) meshing with a star drive intermediate gear (62) having N4 teeth coupled to an intermediate star drive wheel (63) having N5 teeth, so said star drive intermediate wheel (63) drives a star gear (64) of N15 teeth, said star gear (64) carrying a retaining star (65) having NE wings (66), a given point being then reached by a wing (66) of the star (65) with a period T = Ω x NE x (N1xN3xN5) / (N2xN4xN15x60x60) seconds, and said average wheel (22) still meshing with a second gear (23), having N8 teeth, which is secured to a wheel of second (24) ) having N9 teeth, which meshes with said exhaust gear (41) having N10 teeth, which is connected to said exhaust wheel (42) which comprises N11 teeth and which is arranged to cooperate with said pivoting anchor (50) which cooperates with said balance (81), a whip gear (75) having N14 teeth, cooperating with an inverter gear (73) of N13 teeth connected to an inverter gear (72) of N12 teeth, which for each turn of said whip gear (75) carrying a whip (76) to a single arm, passes N14xN12 / N13 teeth of a toothing (31) of the cage (30) which has N7 teeth, said cage (30) then making N7 / (N14xN12 / N13) jumps per revolution and rotating at speed: ΩC = (N14xN12 / N13) x 60 / (TxN7) revolutions per minute. 10. Mechanism according to claim 9, characterized in that Ω = 1, N1 = 96, N2 = 8, N3 = 90, N4 = 8, N5 = 50, N15 = 5, NE = 5, N8 = 10, N9 = 105, N10 = 7, N11 = 15, N14 = 10, N13 = 30, N12 = 9, N7 = 180, N15 = 5, T = 1x5x (96x90x80) / (8x8x15x60x60) = 1 second, N14xN12 / N3 = 10x9 / 3-3 teeth, said mechanism (100), for each turn of said whip gear (75) carrying a whip (76) to a single arm, passing N14xN12 / N13 = 10x9 / 3 = 3 teeth of said toothing ( 31), said cage (30) then making N7 / (N14xN12 / N13) = 60 jumps per turn and rotating at a speed: ΩC = (N14xN12 / N13) x 60 / (TxN7) = 1 turn per minute, the frequency of the oscillator being 3 Hz. Carousel comprising a carousel cage (30) and a mechanism (100) according to one of claims 1 to 10. 12. Timepiece comprising a mechanism (100) according to one of claims 1 to 10, or a carousel according to claim 11.