CH702843A1 - Movement timepiece a crown of equality. - Google Patents

Abstract

The present invention relates to a timepiece movement comprising, mounted on a frame, a first energy source (9) for maintaining the oscillating movement of a mechanical oscillator comprising a resonator and an escapement, by means of a a finishing train forming between said first energy source (9) and the exhaust a first kinematic chain, said movement further comprising a regulating device (14) for controlling said exhaust. The regulating device (14) comprises a stop wheel (16) kinematically connected to said work train and intended to perform a rotational movement periodically, a control cam (24) driven in rotation and secured to a wheel control device (20), a locking device of said stop wheel (16) controlled by said cam (24) to release it periodically, and an elastic member (18) for periodically storing energy from said first source of energy (9), to restore it to said oscillator. In addition, said regulating device (14) further comprises transmission means and control means of said control wheel (20), said transmission means and said regulation means forming with the control wheel (20) a second kinematic chain not comprising said finishing train, said transmission means being arranged to supply energy to said second kinematic chain, and said regulating means being arranged to periodically release said control wheel (20) and to allow the transmission means to driving said control wheel (20) in rotation.

Description

Technical area

The present invention relates to a movement for a timepiece comprising, mounted on a frame, a first power source for sustaining the oscillating movement of a mechanical oscillator having a resonator and an exhaust, through a work train forming between said first power source and the exhaust a first drive train, said motion further comprising a control device for controlling said exhaust. For this purpose, the regulating device comprises a stop wheel connected kinematically to the work train and intended to perform a rotational movement periodically, a control cam driven in rotation and secured to a control wheel, as well as a locking device of the stop wheel controlled by said cam to release it periodically. In addition, the control device comprises an elastic member for periodically storing energy by deformation, from the first energy source of the movement, to restore it to the oscillator said elastic member being able to maintain the oscillation movement of said mechanical oscillator, through said work train, when said stop wheel is locked, and said first power source being able to recharge said elastic member, through said work train, when said stop wheel is released.

State of the art

Such movements have been known for a long time, particularly in the field of clocks, to allow the use of a spring with a large power reserve, as a source of energy, while smoothing the inevitable variations of the the force applied by this spring to the work train, these arising from the change in the state of charge of the spring during the operation of the clock.

Thus a number of mechanisms have already been proposed involving a secondary spring which is loaded from the energy of the main spring, periodically, with a sufficiently short period for the force it applies to the movement can be considered as being constant between its states of minimum load and maximum load.

This is called constant force devices, especially when the secondary spring is arranged directly at the exhaust, while it speaks of equal winding when the secondary spring is put in place at the level of the gear train finishing.

An example of equal winding is described, under the name of "GAFNER system" (named after its inventor Robert Gafner), in an article by F. Droz and J. Florès entitled "The winding of equality and the constant forces in the watch ", published in the magazine" Horlogerie Ancienne ", number 7 of the first half of 1980, published by the AFAHA (French Association of Ancient Watchmaking Enthusiasts).

This device comprises a conventional anchor escapement whose escape wheel carries a pinion arranged in engagement with a wheel of seconds. A triangular cam is integral with the shaft of the escape wheel and controls the movements of a locking lever, for locking a stop wheel coaxial with the seconds wheel by means of two vanes cooperating with a tooth of this wheel. A spiral spring-type secondary spring is connected at its central end to the stop wheel shaft and, at its outer end, to an arm of the seconds wheel. The shaft of the stop wheel further carries a pinion arranged in engagement with the gear train of the movement.

Thus, the locking lever oscillates between two extreme positions at a rate defined by the movements of the escape wheel and the shape of the cam. When it moves from one position to another, it releases the stop wheel which rotates under the effect of the force transmitted by the mainspring, via the finishing train. By turning on itself, while the seconds wheel remains fixed due to the immobility of the escape wheel at this time, the stop wheel loads the spiral spring. The latter then exerts a force on the seconds wheel for maintenance oscillator oscillations, via the escape wheel, the stop wheel is again blocked by the locking lever.

Thanks to a periodic load of the secondary spring, with a small period, the force transmitted to the escape wheel is substantially constant and ensures a good regularity of the operation of the oscillator.

Furthermore, patent FR 1 522 084 describes a time apparatus comprising a mechanical oscillator comprising a resonator and an anchor escapement, represented by reference 14. The mechanism comprises a regulating device 18 comprising a stop wheel 19 controlled by a cam 22 to actuate a locking device 20 and allow the rearming of the intermediate spring 12. Said cam 22 is integral with the shaft 23 on which is also mounted a mobile cooperating with the exhaust and with the intermediate spring 12 for supplying said exhaust 14. As stated in patent FR 1 522 084, a power source 4 drives the regulation device 18 controlled by the exhaust 14. This means that to trigger the locking device 20 by the cam 22 and allow the rearming of the intermediate spring 12, it is necessary to subtract the force from the exhaust 14. This can pro void a punctual increase in the torque applied to the exhaust, which can cause fluctuations and disrupt the operation of the exhaust.

Disclosure of the invention

The main object of the present invention is to propose an alternative to the known mechanisms of the prior art, by proposing a movement for a timepiece comprising a regulating device whose construction makes it possible to guarantee a high operating reliability by disturbing the least possible escape.

For this purpose, the present invention relates more particularly to a movement for a timepiece of the type mentioned above, characterized in that said regulating device further comprises transmission means and means for regulating said wheel. control, said transmission means and said control means forming with the control wheel a second kinematic chain not including said finishing train, said transmission means being arranged to supply power to said second kinematic chain, and said control means being arranged to periodically release said control wheel and allow the transmission means to drive said control wheel in rotation.

The second kinematic chain allows to separate the control of the control cam of the first kinematic chain comprising the exhaust, so that the control cam can be operated by taking the least possible energy to the exhaust. Thus, the use of two kinematic chains makes it possible to separate the rearming of the exhaust control device, so that the exhaust is disturbed as little as possible.

Preferably, the control means may comprise, between the exhaust and the control wheel, a multiplicative gear train arranged so that the force subtracted from the exhaust to regulate the control wheel is reduced.

Advantageously, the regulating means may comprise a whip carried by a pinion gear multiplicative and arranged to cooperate with a pinion of the exhaust.

According to an alternative embodiment, the movement may comprise a first jumping second hand arranged to cooperate with said regulating means, such as the whip.

According to other embodiments, the movement according to the invention may comprise, in the first kinematic chain, a vortex having a cage pivotally mounted on said frame of the movement and carrying the mechanical oscillator, said vortex being arranged to cooperate with the work train, and a vortex wheel integral with said cage, said vortex wheel being arranged to cooperate with said control wheel control means.

According to another variant of the invention, the movement may comprise a first differential gear cooperating with the first power source and arranged to supply energy to each of the first and second drivelines.

According to another variant of the invention, the movement may comprise a second energy source arranged to supply energy to the second kinematic chain.

According to other variants of the invention, the movement may further comprise a lightning second gear for driving a second lightning second hand, said lightning second wheel being arranged to cooperate with the exhaust. The movement may then comprise a device for stopping the second lightning second hand, arranged to allow the optional stopping of said second lightning second hand.

In this variant, the movement may comprise a third energy source arranged to provide energy to the second lightning wheel. According to another possibility, the movement of the invention may comprise a second differential gear co-operating with the second energy source and arranged to supply energy to the second kinematic chain on the one hand and to the lightning second gear train. somewhere else.

Brief description of the drawings

Other features and advantages of the present invention will appear more clearly on reading the following detailed description of preferred embodiments, made with reference to the accompanying drawings given by way of non-limiting examples and in which:

- figs. 1 to 2 show simplified perspective views of a part of a movement for a timepiece having a regulating device according to two first embodiments of the present invention;

[0023] - FIG. 3 shows a simplified perspective view of the wheels of another embodiment of the present invention;

[0024] - figs. 4 and 5 show simplified perspective views of a part of a timepiece movement having a regulating device according to two other embodiments of the present invention; and

[0025] - FIG. 6 shows a simplified perspective view of a part of a timepiece movement having two regulating devices according to another embodiment of the present invention.

Embodiments of the invention

Fig. 3 1 shows a part of a movement for a timepiece having a force regulating device transmitted by a first power source to a mechanical oscillator, according to a first embodiment of the present invention. As an indication, it will be noted that the top of the figures corresponds to the bridge side of the movement.

FIG. 1 simply illustrates the general principle of this control device, only the elements of the movement involved in the process of regulation being visible to facilitate understanding. In particular, it may be noted that the frame of the movement has not been shown for the sake of clarity and insofar as it can be of any known type suitable for the implementation of the present invention.

The movement comprises a conventional mechanical oscillator comprising a resonator, generally a sprung balance (not shown), associated with an escapement, here anchor, by way of nonlimiting illustration.

The exhaust comprises an anchor 1 arranged to cooperate with an escape wheel 3. An exhaust pinion 5 is integral with the escape wheel 3 and is engaged with the wheel 7a of a mobile d a finishing gear.

Said crawling gear comprises the elements between the first energy source and the exhaust for transmitting said energy to said exhaust. More particularly, the finishing gear train comprises, in addition to the wheel 7a, a pinion 7b integral with the wheel 7a, the wheels formed by the wheel / pinion assemblies 10a / 10b, 11a / 11b, and a wheel 12 meshing with the pinion 11b. , and the wheel 11 meshing with the pinion 7b.

To maintain the oscillations of the sprung balance, the movement comprises a first energy source, preferably a mainspring, whose energy is transmitted to the oscillator by means of the work train. In known manner, the mainspring is housed in a first barrel 9 comprising a drum having a peripheral toothing.

When loaded, the spring relaxes by driving the drum in a rotational movement transmitted to the gear train through its teeth. According to the configuration represented here as an indication, the pinion 10b is arranged to be in engagement with the toothing of the drum of the first barrel 9.

The work train forms a first kinematic chain between the first power source and the exhaust.

It appears from FIG. 1 a regulating device 14 is interposed between the wheel 10a and the escapement of the movement.

The control device 14 comprises in particular a stop wheel 16 coaxial with the wheel 12 of the work train and a spiral spring 18 connected at its central end to the shaft 17 of the stop wheel 16 and, for example, its outer end to the wheel 12. The shaft of the stop wheel 16 is rotatably mounted relative to the frame and further carries a pinion 19 arranged to mesh with the wheel 10a of the work train. The wheel 12 is rotatably mounted and is not integral with the shaft of the stop wheel 16. As in a traditional winding spring, the spring 18 is intended to periodically store energy by deformation, from the first energy source of the movement, to restore it to the oscillator, said spring 18 being capable of sustaining the oscillation movement of said mechanical oscillator, by means of said work train, when said wheel of stop 16 is locked, and said first power source being able to reload said spring 18, through said work train, when said stop wheel 16 is released.

The control device 14 also comprises a control wheel 20 integral with a shaft 22 of the same axis carrying a control cam 24, of triangular shape.

The control device 14 further comprises a locking lever 26 carried by a shaft (not shown) pivotally mounted on the frame of the movement. The locking lever 26 comprises, at a first of its two ends, a fork 28, between the teeth of which is arranged the control cam 24. The second end of the lever 26, separated from the first end by a middle portion 30 carrying the shaft of the lever 26, has two arms 32, 34 in the form of circular arcs extending on either side of the general direction of the middle portion 30 of the lever 26. Each of these arms comprises a tooth 36 , 37, at its end, directed substantially in the direction of the other arm. The stop wheel 16 is disposed between the two arms 32, 34 of the locking lever 26, so that its toothing is capable of cooperating with one or other of the teeth 36,37 of the arms 32,34.

According to the present invention, the control device 14 also comprises transmission means and control means of the control wheel 20, said transmission means and said control means forming with the control wheel 20 a second kinematic chain not including the finishing gear, said transmission means being arranged to supply energy to said second kinematic chain, and said regulating means being arranged to periodically release the control wheel 20 and allow the transmission means to drive the rotating control wheel 20.

More particularly, the control means comprise a multiplicative gear comprising a pinion 38 arranged to cooperate with the control wheel 20, a wheel 39 integral with said pinion 38, and a pinion 40 arranged to cooperate with the wheel 39. The means control also include a whip 42 carried by the pinion 40 multiplicative gear. The whip 42 is arranged so that its end engages in the wings of the pinion 5 of the escape wheel 3. The person skilled in the art knows how to determine the dimensions and the number of teeth of the elements of the gear train and the pinion. exhaust 5 so that the whip 42 is released every second, after a certain number of vibrations of the resonator and advances of the escape pinion 5. Released at every second, the whip 42 performs a turn on it -even. The operation of whip 42 will be described in more detail later. A first needle, of the jumping second hand type (not shown), can be provided in the second kinematic chain. Preferably, said first needle is integral with the whip 42 so that the movement of whip 42 is communicated to said first lightning second hand.

In the present invention, a lightning second hand is called a needle making one revolution per second in a jump (of the second dead type) or in several jumps, typically four or five jumps.

The transmission means arranged to supply energy to the second kinematic chain comprise a pinion 44 secured to the control wheel 20, a wheel 46 cooperating with the pinion 44 and a pinion 48 secured to the wheel 46. In this variant, the pinion 48 is arranged to be engaged with the toothing of the barrel drum of a second cylinder 50 constituting a second energy source for supplying energy to the second kinematic chain.

The operating principle of the mechanism which has just been described will now be exposed in relation to FIG. 1. Consider, as a starting hypothesis, that the spring 18 has a loaded state and thereby exerts a force on the wheel 12 of the finishing train tending to rotate it.

Most of the time, the stop wheel 16 is locked by one of the teeth of the locking lever 26, which prevents the rotation of the stop wheel 16, its shaft 17 and its pinion 19 In fig. 1, the locking lever 26 is in its first extreme position, the tooth 37 being engaged in the toothing of the stop wheel 16.

In a conventional manner in equal winding, the rotation of the wheel 12 of the crawler, under the action of the discharge of the spring 18, is retransmitted to the escape wheel 3 via successively of the pinion 11b, the wheel 11a, the pinion 7b, the wheel 7a and the pinion 5.

The wheel 12 is kinematically connected to the escape wheel 3, it can rotate only during the phases of release and impulse of the exhaust.

After a number of vibrations of the resonator, the exhaust pinion 5 has advanced enough to release the whip 42. Whip 42 being released, the rotation of the elements of the second kinematic chain is possible. Thus, the control wheel 20 can receive the energy of the second cylinder 9. For this, said second cylinder 20 rotates the pinion 48, the wheel 46, the pinion 44 and the control wheel 20 and its cam 24. On the other hand, the control wheel 20 rotates the pinion 38, the wheel 39 and the last pinion 40, which causes the whip 42 to rotate one revolution until said whip 42 engages again. in the wings of the exhaust pinion 5. Then, the whip 42 is released again, allowing the actuation of the control wheel 20, and so on.

After a certain time which is a function of the gear ratios provided between the transmission means and the control wheel 20, said control wheel 20 has made a sufficient rotation so that the control cam 24, which at the same time exerts pressure on the fork 28 of the locking lever 26, to tilt it. By tilting around its shaft, the locking lever 26 releases the stop wheel 16 due to the distance of the teeth 36, 37 from the toothing of the stop wheel 16. Then the locking lever continues to tilt, its tooth 36 approaching the stop wheel 16, until reaching its second extreme position in which the tooth 36 blocks the stop wheel 16.

When released, the stop wheel 16 rotates under the effect of the force transmitted by the spring of the first barrel 9, via the pinion 10b, the wheel 10a of the finishing train and the pinion 19. rotation occurs during a rest phase of the exhaust, most of the time, which implies that the wheel 12 is blocked during this movement. As a result, the rotation of the stop wheel 16 makes it possible to reload the spring 18. The latter can then again exert a force on the wheel 12 allowing the maintenance of oscillations of the oscillator with a constant force, via the escape wheel, the stop wheel 16 being again blocked by the locking lever 26. The spring 18 then gradually discharges, as previously described, until the control wheel 20 and the cam 24 have made a sufficient rotation to tilt the lock lever 26 and releasing the stop wheel 16, and so on.

Unlike the existing equal winding, the control device 14 according to the invention allows to place the control wheel in a second kinematic chain, separate from the first kinematic chain comprising the finishing gear, and powered by a second energy source. Thus, the locking and unlocking functions of the control wheel are isolated in this second kinematic chain so that the energy to reset the spring 18 of the control device does not come from the kinematic chain comprising the finishing gear and managing the operation of the exhaust. As a result, the operation of the exhaust is very little disturbed. In addition, the multiplicative gearing of the control means is chosen so that the power ratio with the exhaust pinion is as low as possible. Thus, the force subtracted from the exhaust to release the whip 42 and regulate the control wheel 20 is reduced.

FIG. 2 represents another variant embodiment of the invention. In this variant, there is the first kinematic chain comprising the pinion 10b, the wheel 10a secured to the pinion 10b and meshing with the pinion 19 of the stop wheel 16, the spring 18, exerting its force on the wheel 12, the pinion 11b which meshes with the wheel 12, the wheel 11 has secured to the pinion 11b, the pinion 7b which meshes with the wheel 11a, and the wheel 7a integral with the pinion 7b and which meshes with the exhaust pinion 5, cooperating with the exhaust.

There is also the second kinematic chain comprising the transmission means consisting of the pinion 48, the wheel 46 integral with the pinion 48, the pinion 44 which meshes with the wheel 46 and which is integral with the control wheel 20, the pinion 38 which meshes with the control wheel 20, the wheel 39 integral with the pinion 38, the pinion 40 which meshes with the wheel 39 and which carries the whip 42.

We also find the locking lever 26 and the control cam 24. The operation and the advantages of the control device are identical to the variant described above.

In this variant, there is provided a first differential gear 56 comprising an input having a connection with the barrel 9, a first output having a connection with the pinion 10b of the first kinematic chain and a second output having a connection with the pinion 48 of the second driveline. Thus, in this variant, a single energy source is used, the differential gearing 56 making it possible to supply energy to each of the first and second kinematic chains.

It is obvious that other constructions are possible. It can be provided that the first output of the differential gear meshes directly with the pinion 19 of the stop wheel, and / or that the second output of the differential gear meshes directly with the pinion 44 of the control wheel 20. It is also possible to provide an intermediate wheel between the single energy source and the input of the differential gear.

FIG. 3 represents another variant embodiment of the invention. The locking lever 26, the control cam 24 and the stop wheel 16 have not been shown. As for the variant of FIG. 2, the barrel 9 is the only source of energy. The differential gear is replaced by two superimposed wheels 90, 91, integral with each other. The wheels 90, 91 are driven on a pinion 92 which meshes with a wheel 94 whose pinion 96 is in engagement with the toothing of the barrel of the barrel 9. Furthermore, the wheel 90 is arranged to cooperate with the pinion 19 of the wheel stopping, and the wheel 91 is arranged to cooperate with the pinion 48 of the second kinematic chain.

The energy of the barrel 9 is transmitted to the mobile consisting of the wheel 94 and the pinion 96, then the pinion 92. When the whip 42 is released, once a second, the gear wheels 46, 48, 20, 40, and 38, 39 of the second power train can rotate under the effect of the torque generated by the barrel 9, and transmitted through the workings 94, 96 and 90, 91, 92. The wheel 90 will then drive the pinion 19 this pinion being integral with the central end of the spiral spring 18, said spring 18 will be rearmed. The rest of the time, the operation of the regulating device is identical to that of the previous variants.

FIG. 4 represents another variant embodiment of the invention, comprising two energy sources, close to the variant of FIG. 1.

In this variant, there is the first kinematic chain comprising the pinion 10b cooperating with the first barrel 9, the wheel 10a secured to the pinion 10b and meshing with the pinion 19 of the stop wheel 16, the spring 18, exerting its force on the wheel 12, the pinion 11b which meshes with the wheel 12, the wheel 11a secured to the pinion 11b, the pinion 7b which meshes with the wheel 11a. In this variant, the pinion 7b is integral with a vortex wheel 58, whose operation will be described later.

There is also the second kinematic chain comprising the transmission means consisting of the pinion 48 cooperating with the second cylinder 50, the wheel 46 integral with the pinion 48, the pinion 44 which meshes with the wheel 46 and which is integral with the control wheel 20, pinion 38 which meshes with the control wheel 20, the wheel 39 integral with the pinion 38, the pinion 40 which meshes with the wheel 39 and which carries the whip 42.

We also find the locking lever 26 and the control cam 24. The operation of the control device is identical to the variant described above.

In this embodiment, the single exhaust has been replaced by a regulating member of the tourbillon type. The operation of this vortex being conventional, it will not be described here in detail.

It will suffice to indicate that the vortex comprises a cage 60, inclined relative to the plane of movement, and pivoting about an axis 62.

Inside the cage are, in a known manner, the rocker 63, the escape wheel 64, and the exhaust pinion. The latter meshes with a fixed wheel 66, having an external toothing meshing with said exhaust pinion. The vortex wheel 58 is coaxial with the fixed wheel 66 and the tourbillon cage 60. In addition, the vortex wheel 58 is integral with the shaft of the cage, and is therefore integral with the cage 60 so that the vortex wheel 58 rotates the cage 60.

Furthermore there is provided a pinion 68 pivotally mounted on the frame and arranged to mesh with the vortex wheel 58. The pinion 68 is also arranged so that the end of the whip 42 engages in the wings of said pinion 68.

The cage 60 of the vortex moves in synchronism with the movements of the escape wheel 64 mounted in said cage 60, so that the vortex wheel 58 and the pinion 68 also move in synchronism with the movements of the Exhaust wheel 64. The vortex wheel 58 and pinion 68 are equivalent to the escape wheel 3 and the escape gear 5 of the variants shown in FIGS. 1 and 2 and are therefore considered part of the exhaust. The whip 42 cooperates with the pinion 68 as the whip 42 cooperates with the escape pinion 5 of FIGS. 1 and 2, so as to regulate the control wheel 20. The advantages of the control device are the same as those described above.

The variant shown in FIG. 5 corresponds to the variant of FIG. 4 supplemented by a lightning second wheel 70, powered by a third energy source, such as the barrel 71. The lightning second wheel 70 comprises a pinion 72 meshing with the cylinder drum 71, a wheel 73 integral with the pinion 72 , a pinion 74 meshing with the wheel 73, a wheel 75 integral with the pinion 74, and a last pinion 76 meshing with the wheel 75 and bearing a second whip 77. The end of the second whip 77 engages the sprocket wings 68 of the exhaust. A blazing second hand (not shown) is integral with said second whip 77. The second whip 77 cooperates with the pinion 68 as the whip 42 cooperates with the pinion 68 or the pinion 5 of FIGS. 1 and 2. Therefore, the second whip 77, released every second, and powered by the third cylinder 71, performs a turn on itself by communicating its movement to the second lightning needle.

A stop device 80 is provided to allow the optional stop of said lightning second hand. More particularly, the stop device 80 comprises a stop 82 integral with the pinion 76. The stop 82 is arranged to cooperate with a hook 84 provided on a rocker 86 that can be actuated by a pusher (not shown). Thus, when the flip-flop 86 has been actuated, the stop 82 comes to rest against the hook 84 during the rotation of the second whip 77, so that said second whip 77 and the lightning second hand which it carries are blocked. in rotation.

It is obvious that such a lightning second wheel can also be used in the single escapement variants, such as those shown in Figs. 1 and 2. In this case, the second whip 77 is arranged so that its end engages in the wings of the exhaust pinion 5.

According to another variant not shown, the third cylinder 71 can be removed, and the movement then comprises a differential gear (not shown) comprising an input having a connection with the cylinder 50, a first output having a connection with the pinion 48 of the second kinematic chain and a second output having a connection with the gear 72 of the lightning second wheel. Thus, in this variant, a single source of energy is used, the differential gearing making it possible to supply energy to the second kinematic chain and to the lightning second gear train.

According to another variant shown in FIG. 6, the movement comprises a second regulating device, of the equal winding type, provided on the second kinematic chain. For this purpose, a second cam 100 is arranged coaxially with the cam 24, as well as a stop wheel 102 coaxial with the pinion 48, a spiral spring 104, connected at its central end to the wheel shaft of FIG. stop 102 and its outer end to the wheel 46. A locking lever 106 is also provided to cooperate on the one hand with the cam 100 and on the other hand with the stop wheel 102. The operation of this second device of regulation, present on the second kinematic chain, is identical to that of the control device 14 of the first kinematic chain and described above.

This control device provided on the second kinematic chain makes it possible to make the force, at the whip 42 and therefore on the exhaust pinion 5, as constant as possible.

The variant of FIG. 1is inspired by the variant shown in FIG. 1, but it is obvious that a regulating device of the equal winding type can be provided in a similar manner on the second kinematic chain of all the other embodiments.

The foregoing description corresponds to preferred embodiments of the invention described in a non-limiting manner. In particular, the shapes shown and described for the various constituent elements of the movement for a timepiece are not limiting. By way of example, the shape of the control cam can be modified without departing from the scope of the present invention. Moreover, the vortex can be inclined as the represented variant or plane. Similarly, the axes of the various elements of the workings used are not necessarily perpendicular to the plans of the frame, but can be inclined. For example, the axes of the various elements of the workings used may be parallel to the plans of the frame, so that the wheels are no longer parallel but perpendicular to the plans of the frame.

It is obvious that for all the variants of the invention, the work train is formed differently and may include a different arrangement and number of mobiles. Thus, for example, for the variants of FIGS. 1 to 3, and 6, the wheel 12 can be in direct contact with the exhaust pinion 5, the mobiles 11a, 11b and 7a, 7b being removed.

On the other hand, especially in the variants comprising two energy sources, it is preferable to add the mechanisms generating other information on the second kinematic chain. These mechanisms can be triggering mechanisms of ringing, mechanisms of activation of a time base (date, counters), etc. Some of these mechanisms, by their operation, strongly disrupt the regulation of energy. These mechanisms taking their energy from the second kinematic chain, the energy at the first kinematic chain is not decreased. Thus, one can keep a large power reserve for the gear train, without disturbing it, the energy of the first cylinder being solely dedicated to the maintenance of the regulating member.

However, it is possible to provide, on the first kinematic chain of each of the variants shown, needles for displaying information, which are neither greedy energy disruptive nit.

On the other hand, in the variants where a single source of energy is used, this energy source may be a single cylinder or a group of cylinders kinematically connected permanently. The energy can be taken on the one hand on the shaft, for the first kinematic chain, and on the other hand on the barrel drum, for the second kinematic chain. It is then possible to insert a system of maintenance of the driving force during reassembly, as described in the book "Theory

[0078] General Watchmaking ", Léopold Defossez, Tome I, pages 142-143. This Harrison force retention principle prevents the gear train from stopping by neutralizing the force.

Moreover, it is obvious that the whip 42 can be replaced by an equivalent mechanism, such as a solid star of the exhaust pinion cooperating with a small integral star of the last element of the multiplicative gear, the small star being arranged to rotate rapidly to reduce its influence on the exhaust.

Claims (11)

A timepiece movement comprising, mounted on a frame, a first energy source (9) for maintaining the oscillating motion of a mechanical oscillator having a resonator and an exhaust, by means of a gear train finishing forming between said first power source (9) and the exhaust a first kinematic chain, said movement further comprising a regulating device (14) for controlling said exhaust and, comprising a stop wheel (16) kinematically connected to said finishing gear train and intended to perform a rotational movement periodically, a control cam (24) driven in rotation and integral with a control wheel (20), a device for locking said stop wheel (16) controlled by said cam (24) to release it periodically, an elastic member (18) for periodically storing energy from said first energy source (9), to restore it to said oscillator, said elastic member (18) being capable of sustaining the oscillation movement said mechanical oscillator, through said work train, when said stop wheel (16) is locked, and said first power source (9) being able to recharge said elastic member (18), through said gear finishing, when said stop wheel (16) is released, characterized in that said control device (14) further comprises transmission means and control means of said control wheel (20), said transmission means and said control means forming with the control wheel (20). a second kinematic chain not including said finishing train, said transmission means being arranged to supply energy to said second kinematic chain, and said regulating means being arranged to periodically release said control wheel (20) and to allow the transmission means driving said control wheel (20) in rotation. 2. Movement according to claim 1, characterized in that the regulating means comprise, between the exhaust and the control wheel (20), a multiplicative wheel arranged so that the force subtracted from the exhaust to regulate the wheel of control (20) is reduced. 3. Movement according to claim 2, characterized in that the regulating means comprise a whip (42) carried by a pinion (40) of the multiplicative gear train and arranged to cooperate with a pinion (5) of the exhaust. 4. Movement according to claims 2 or 3, characterized in that it comprises a first second lightning needle arranged to cooperate with said control means. 5. Movement according to any one of the preceding claims, characterized in that it comprises, in the first kinematic chain, a vortex having a cage (60) pivotally mounted on said frame of the movement and carrying the mechanical oscillator, said vortex being arranged to cooperate with the work train, and a vortex wheel (58) integral with said cage (60), said vortex wheel (58) being arranged to cooperate with said control wheel control means (20); ). 6. Movement according to any one of the preceding claims, characterized in that it comprises a first differential gear (56) cooperating with the first energy source (9) and arranged to supply energy to each of the first and second kinematic chains. 7. Movement according to any one of claims 1 to 5, characterized in that it comprises a second energy source (50) arranged to supply energy to the second kinematic chain. 8. Movement according to any one of the preceding claims, characterized in that it further comprises a gear train (70) second lightning to drive a second lightning second hand, said wheel (70) second lightning being arranged to cooperate with the exhaust. 9. Movement according to claim 8, characterized in that it comprises a stop device (80) of the second lightning second hand, arranged to allow the optional stop of said second lightning second hand. 10. Movement according to any one of claims 8 and 9, characterized in that it comprises a third energy source (71) arranged to provide energy to the wheel (70) second lightning. 11. Movement according to claims 7 to 10, characterized in that it comprises a second differential gear cooperating with the second energy source (50) and arranged to supply energy to the second kinematic chain on the one hand and to the gear (70) second lightning on the other hand.