EP0537515A1 - Display device for a timepiece - Google Patents

Abstract

The displaying of n + m symbols is achieved by means of an upper disc (1a) arranged behind the hatch (2) of a cover plate, and of a lower disc (1b) placed behind the upper disc and containing m sectors. One of the sectors of the upper disc (1a) consists of a transparent window (4), the other n + m sectors of the two discs carrying the symbols. Gearing (11, 12a, 12b, 13a, 13b) and a control cam (20), set into motion by a drive runner (10), cause the discs to pivot, in steps of one sector starting from a position in which the window (4) is behind the hatch (2), so as firstly to advance the two discs together by one step, then the upper disc (1a) by n successive steps, finally the lower disc (1b) by m-1 successive steps so as to return to the starting position. A positioning device (30a, 30b, 31a, 31b) locks the discs (1a, 1b) when they are stationary, and frees the disc taking one step. <IMAGE>

Description

The present invention relates to a mechanical device for cyclically displaying a series of symbols, one after the other, behind the aperture of a cover plate. It relates more particularly to a device comprising two superimposed annular discs intended to display information in the window of the dial of an analog timepiece, for example the date, by means of figures having a dimension substantially greater than those of conventional calendars with a single disc. The invention also relates to a device for rapidly correcting the position of the discs.

Calendars making use, to increase the size of the figures, of two superimposed annular discs are known. For example, patent CH 660941 describes in detail, in the case of a wristwatch, an embodiment of such a calendar. In this execution, the lower disc includes 17 equal sectors, the first 16 bearing the numbers 1 to 16, while the last is empty, having no inscriptions. The upper disc has, for its part, 16 sectors, the first being a window revealing the figures of the lower disc, while the following 15 carry the numbers 17 to 31. The device further comprises a drive mechanism, arranged at inside the discs and rotating, in steps of a sector, the discs from the hour axis of the watch movement. At the start, the two discs are in an initial position in which the window and the number 1 are arranged opposite the dial window, which thus reveals the date of the first day of a month. The mechanism first drives only the lower disk for 16 successive steps. The first 15 steps, while the upper disc is at rest, thus scroll behind the window and the window, after the number 1 which was visible in the initial position, the numbers 2 to 16 one after the other. During the 16th step a wedge of the lower disc abuts against a similar wedge of the upper disc to advance the latter by one step. So at the end of the 16th and last step are next to the window, the number 17 of the upper disc directly visible, and the empty sector of the lower disc hidden by the other disc. The mechanism then drives only the upper disc 15 successive steps. The first 14 steps, while the lower disc is at rest, therefore scroll, behind the window, the numbers 18 to 31. During the 15th step the wedge already mentioned of the upper disc abuts against the wedge of the lower disc to advance it by a step. At the end of the 15th and last step, the two discs are therefore in the initial position, the window of the upper disc and the number 1 of the lower disc being arranged opposite the window. Finally, to prevent the discs from being subjected to an accidental displacement following an impact, the device comprises two conventional sautoirs, each sautoir coming to position a disc.

The cited document describes yet another embodiment in which the upper disc has two windows, the lower disc remaining unchanged. With the help of suitable shims, it is then possible to display the numbers from 1 to 31 or from 1 to 30, that is, in general, both the odd numbers and the even numbers.

The achievements disclosed by the cited document, however, have certain drawbacks. Indeed, the lower disc has an empty sector, while in the second embodiment the upper disc is further provided with a second window. The presence of the empty sector and of the second window, by reducing the space available for the figures, leads to a reduction in the size of the latter, which goes against the aim pursued by the invention. Furthermore, given the central arrangement of the drive mechanism, it is possible to give the discs a large diameter. Now the moment of inertia of a disc is believed to be the fourth power in its radius, which means that the positioning of a large disc requires significant pressure from the jumper on this disc, resulting in high friction. This friction naturally reduces the operational safety of the watch, particularly at times when the two discs are driven simultaneously.

The object of the present invention is to provide a display device with two superimposed discs which does not have these drawbacks.

• le disque supérieur est divisé en n + 1 secteurs égaux adjacents, ces secteurs étant numérotés respectivement 0', 1', ... n' de manière à passer dans l'ordre croissant derrière le guichet lorsque le disque tourne dans le sens donné, le secteur 0' comportant la fenêtre;
• le disque inférieur est divisé en m secteurs égaux adjacents, ces secteurs étant numérotés respectivement 1'', 2'' ... m'' de manière à passer dans l'ordre croissant derrière le guichet lorsque le disque tourne dans le sens donné;
• les moyens pour entraîner les disques ont pour fonction, à partir d'une position initiale dans laquelle les secteurs 0' et m'' se trouvent en regard du guichet :
  • a) d'avancer le disque supérieur de n + 1 pas successifs de un secteur pour faire défiler derrière le guichet les n secteurs 1', 2', ... n', et replacer le secteur 0' dans la position de départ après une révolution complète du disque,
  • b) de déplacer, pendant le mouvement du disque supérieur, le disque inférieur de un pas de un secteur de manière que le secteur 1'' se trouve derrière le guichet, en même temps que le secteur 0', à la fin de la révolution complète du disque supérieur,
  • c) d'avancer enfin uniquement le disque inférieur de m-1 pas successifs de un secteur pour faire défiler, derrière le guichet et la fenêtre, les secteurs 2'', 3'' ... m'' et revenir à la position initiale à la fin du dernier pas après le passage derrière, soit du guichet, soit du guichet et de la fenêtre, des n + m secteurs 1', 2' ..., n', 1'', 2'' ... m''; et en ce que
• les moyens de positionnement bloquent les disques lorsqu'ils sont au repos, et libèrent le disque exécutant un pas.

To achieve this objective, the display device according to the invention for a timepiece with analog movement, comprising an upper disc provided with a transparent window, this disc being behind a cover plate comprising a window, a lower disc disposed concentrically with the upper disc, the latter at least partially covering the lower disc, part of which is visible through the window, means for driving step by step each disc in rotation in a given direction from a mobile of the movement of the timepiece, and disc positioning means, is particularly remarkable in that:

• the upper disc is divided into n + 1 adjacent equal sectors, these sectors being numbered respectively 0 ′, 1 ′, ... n ′ so as to pass in ascending order behind the window when the disc rotates in the given direction, sector 0 'comprising the window;
• the lower disc is divided into m adjacent equal sectors, these sectors being respectively numbered 1 '', 2 '' ... m '' so as to pass in ascending order behind the window when the disc rotates in the given direction;
• the means for driving the discs have the function, from an initial position in which the sectors 0 'and m''are located opposite the window:
  • a) advance the upper disc by n + 1 successive steps of a sector to scroll behind the counter the n sectors 1 ', 2', ... n ', and replace the sector 0' in the starting position after a complete disk revolution,
  • b) to move, during the movement of the upper disc, the lower disc by one step of a sector so that sector 1 '' is behind the window, at the same time as sector 0 ', at the end of the revolution complete of the upper disc,
  • c) finally advance only the lower disc of m-1 successive steps of a sector to scroll, behind the window and the window, the sectors 2 '', 3 '' ... m '' and return to the position initial at the end of the last step after passing behind, either from the window, or from the window and window, n + m sectors 1 ', 2' ..., n ', 1'',2''.. . m ''; and in that
• the positioning means block the discs when they are at rest, and release the disc performing a step.

An advantage of the invention is that all the sectors, except that comprising the window, are used to display symbols.

Another advantage comes from the fact that in the rest position the discs are locked, which guarantees reliable positioning, while nothing hinders the movement of the disc making a step.

• la fig. 1 représente schématiquement une forme de réalisation préférée du dispositif d'affichage selon l'invention dans le cas d'un calendrier de montre, les deux disques se trouvant dans une position prise comme position initiale du dispositif;
• la fig. 2 est une vue du dispositif calendrier représenté sur la fig. 1 après 24 heures de fonctionnement;
• la fig. 3 représente le dispositif calendrier de la fig. 1 après qu'il ait effectué 15 pas;
• la fig. 4 est une vue en plan du mécanisme de correction des disques du dispositif d'affichage; et
• la fig. 5 est une vue en coupe selon l'axe V-V du dispositif d'embrayage faisant partie du mécanisme de correction représenté sur la fig. 4.

Other characteristics and advantages of the display device according to the invention will emerge from the description which follows, given with reference to the appended drawing and giving, by way of explanation but in no way limiting, an exemplary embodiment of such a device. In this drawing, where the same references relate to similar elements:

• fig. 1 schematically represents a preferred embodiment of the display device according to the invention in the case of a watch calendar, the two discs being in a position taken as the initial position of the device;
• fig. 2 is a view of the calendar device shown in FIG. 1 after 24 hours of operation;
• fig. 3 shows the calendar device of FIG. 1 after he has taken 15 steps;
• fig. 4 is a plan view of the disc correction mechanism of the display device; and
• fig. 5 is a sectional view along the axis VV of the clutch device forming part of the correction mechanism shown in FIG. 4.

The display device according to the present invention will be described in detail in the case of a calendar device for a wristwatch. This calendar device can either be part of the watch movement or be presented under the form of a module coming to be fixed on an existing movement. If the device is part of the movement, the rapid date setting of the calendar can be done by the crown of the watch by means of mechanisms known per se. On the other hand, if it is produced in the form of an independent module, this module will advantageously include a push-button date-setting mechanism, an embodiment of which will also be described.

Of course, the present calendar device could easily be adapted to display information other than the calendar of a month, for example the time.

Fig. 1 shows an embodiment of the calendar device according to the invention. In this figure, the reference 1a designates an upper annular disc, similar to a conventional calendar disc, this disc covering a lower annular disc 1b. The two discs, which are identical in this case, but this is not a prerequisite, are placed concentrically with each other so as to pivot around a common center 3. Each disc is divided into 16 equal sectors and adjacent to each other, these sectors each carrying, except a sector of the disc 1a, the calendar of a month of 31 days. A dial not shown and comprising a window 2 covers the upper disk 1a so that the dates of this disk, when it pivots, appear one by one in this window. The empty sector of the upper disc 1a comprises a transparent window 4, this window, once placed opposite the window 2, making it possible to read one by one the dates of the lower disc 1b.

The two discs 1a and 1b are rotated by a drive mechanism, which will be described later, so as to rotate each disc, in steps of a sector, in a given direction, this direction being indicated by the arrow 5a for disk la, and 5b for disk 1b. The discs rotate in the same direction in the present embodiment, but they could also rotate in opposite directions without departing from the scope of the invention.

The sectors of the upper disc 1a carry the dates not shown 1 to 15, these dates being arranged so as to pass in ascending order behind the window 2 when the disc rotates in the direction 5a, the date 1 immediately succeeding window 4 Likewise, the sectors of the lower disc 1b carry the dates not shown 16 to 31, these dates passing in increasing order behind the window 2 when the disc rotates in the direction 5b. Under these conditions, it is clear that it is possible to display the dates 1 to 15 directly behind the window 2, and behind the window 2 and the window 4 the dates 16 to 31.

In order to be placed in a more general case, given that the present display device can be used to indicate information other than the calendar of a month, it will be assumed subsequently that the disc la is divided into n + 1 equal and adjacent sectors, and the disc 1b in m other equal and adjacent sectors. These sectors are referenced in ascending order, in the same way as above, from 0 'to n' for the former, and from 1 '' to m '' for the latter, sector 0 'comprising window 4, and the n + m sectors each remaining a distinctive symbol. In the case of the calendar, sectors 1 'to n' would carry the dates 1 to 15, and sectors 1 '' to m '' the dates 16 to 31.

To make appear cyclically behind window 2, in ascending order of references from an initial position, the n + 1 sectors of disc 1a, then the m sectors of disc 1b, the two discs must be moved in time adequately by the drive mechanism.

The initial position is arbitrary, and in the present embodiment it has been chosen to be that where the sectors 0 'and m' 'are both behind the window 2. If another position had been chosen as the initial position, it is obvious that after a certain number of steps the discs would necessarily be in a position corresponding to the initial position previously defined. Consequently, the display device operating cyclically, it suffices to define the sequence of movements of the disks from an initial position, the sequences for the other initial positions being easily deduced therefrom.

• d'avancer le disque 1a de n + 1 pas successifs de un secteur pour le replacer dans la position de départ après une révolution complète,
• d'avancer le disque 1b de un pas de un secteur pendant que le disque 1a fait le premier pas, et
• d'avancer uniquement le disque 1b de m-1 pas successifs de un secteur pour revenir à la fin du dernier pas à la position initiale.

In the embodiment of the display device shown in FIGS. 1, 2 and 3, the drive mechanism has the function, from the initial position shown in FIG. 1 and in which only the sector m '' is visible,

• to advance the disk 1a of n + 1 successive steps of a sector to return it to the starting position after a complete revolution,
• to advance the disc 1b by one step of a sector while the disc 1a takes the first step, and
• to advance only the disc 1b of m-1 successive steps of a sector to return to the end of the last step to the initial position.

To obtain these movements of the discs, the drive mechanism comprises a gear train, a first toothed wheel of which, referenced 10, is driven on the hour axis of the movement (not shown) of the watch, this axis passing through the center of pivoting 3 of the discs. A second toothed wheel 11 engages the wheel 10 as well as with a first 12a and a second 12b intermediate toothed wheels. Finally a first 13a and a second 13b toothed drive wheels respectively engage with the toothed wheels 12a and 12b. The ratios of the numbers of teeth of the different toothed wheels are chosen so that the second toothed wheel 11 and the drive wheels 13a and 13b make, in the case of a calendar, one revolution in 24 hours, the direction of rotation being opposite to that of clockwise in the present embodiment.

The wheel 13a pivots about an axis 14a arranged perpendicular to the plane of the discs 1a and 1b in an elongated opening 15a. This opening allows the wheel 13a to move in a substantially radial direction relative to the center 3, while remaining in engagement with the wheel. tooth 12a. Thanks to the elongated opening 15a, the wheel 13a can therefore occupy a position close to the center 3, called the passive position, or a position remote from this center, called the active position. The wheel 13a also comprises on its periphery and in the plane of the disc 1a, a plane different from that of the wheel 12a, at least one radial finger 16a. Finally a spring 17a exerts on the axis 14a a force tending to maintain the wheel 13a in the passive position.

The inner perimeter of the disc comprises, for its part, n + 1 toothed sectors 18a regularly spaced, these sectors engaging with the fingers 16a when the wheel 13a is in the active position. Under these conditions the wheel 13a drives each revolution, that is to say every 24 hours, the disc 1a with a pitch of one sector in the direction of the arrow 5a. When the wheel 13a is on the other hand in the passive position, it cannot mesh with the sector 18a and the disc 1a then remains at rest.

Similarly, the disc 1b has on its inner perimeter m toothed sectors 18b regularly spaced. Between this disc and the second toothed wheel 11, are arranged the elements bearing the references 12b to 17b. These elements will not be described because they are identical to the corresponding elements 12a to 17a which have just been mentioned.

The toothed wheels 13a and 13b are brought into the active or passive position by means of an annular cam 20 pivoting around the center 3 concentrically with the discs 1a and 1b. The inner perimeter of this cam has n + m teeth 21 regularly spaced, while the outer perimeter is divided into a first 22 and a second 23 circular control sectors, the radius of the second sector being less than the radius of the first. One sector is connected to the next by an inclined plane 24 which extends over an arc less than or equal to that separating two consecutive teeth 21. The cam 20 is rotated by means of a lug 25 secured to the toothed wheel 11, this lug coming into engagement with each revolution of the wheel, which performs one revolution in 24 hours in the case of a calendar, with one of the teeth 21 to advance the cam by one step. Finally, a jumper 26 positions the cam 20 by acting on the teeth 21 with moderate pressure since the moment of inertia of the cam is very low.

The axes 14a and 14b of the wheels 13a and 13b are pressed against the control sectors 22 and 23 of the cam 20 by the springs 17a and 17b, the radii of these sectors being chosen so as to put the wheel in active position. the axis touches the sector 22, and in the passive position if this axis touches the sector 23. The lengths of the sectors 22 and 23, as well as the angle formed by the straight lines join the center 3 to the axes 14a and 14b, are determined in function of the sequence of displacements that the disks 1a and 1b must carry out over a complete working cycle of the display device. In the case of the calendar device shown in FIGS. 1 to 3, sector 22 extends over an arc of 178 degrees, while the angle between the lines previously defined is 174 degrees.

The operation of the drive mechanism which has just been described will now be explained with reference to the calendar shown in different states in Figs. 1, 2 and 3.

Fig. 1 represents the calendar in the initial state around 12 o'clock. The sectors 0 'and m''of the disks 1a and 1b are then behind the window 2. As the sector 0' comprises the window 4, it is the sector m '', on which is written the number 31 not shown, which is visible. The cam 20 is in a position in which the axis 14a of the wheel 13a is in abutment against the end of the control sector 23, and that 14b of the wheel 13b in abutment against the end of the sector 22. The fingers 16a and 16b of these wheels are, for their part, distant from the discs 1a and 1b, while the lug 25 of the wheel 11 is about to come into contact with a tooth 21 and the cam 20. During approximately the four hours later, the lug 25 drives the cam 20 to move it by one tooth and put it in the position shown in FIG. 2. The wheels 13a and 13b are then both put in the active position, while the discs 1a and 1b have remained in the initial position. This situation lasts up to approximately 24 hours. At this time the angular position of the wheels 11, 13a and 13b, which have continued to rotate, is that shown in FIG. 3, a figure in which the disks 1a and 1b do not, however, occupy the initial position because it represents the calendar in a state that it will reach later. The lug 25 is distant from the cam 20, while the fingers 16a and 16b are about to mesh with the corresponding sectors 18a and 18b to drive, for approximately four hours, the discs 1a and 1b with a pitch of a sector respectively in the direction of arrows 5a and 5b, and move the calendar from the initial position to the next position.

This new position of the disks 1a and 1b of the calendar is shown in FIG. 2, while it is around 12 o'clock. The calendar is now in the state in which sectors 1 'and 1' 'are behind window 2, sector 1' carrying the number 1 not shown, and sector 1 '' the number 16 hidden by the disc 1a . Thus exactly 24 hours have passed between the positions of the discs 1a and 1b shown in FIGS. 1 and 2, and during this time the calendar went from thirty-one to the first of the following month.

Then the lug 25 drives, as before, the cam 20 of a tooth in about four hours. The wheel 13b then passes from the active position to the passive position, its axis leaving the end of the control sector 22 to go to bear on the start of the sector 23, while the wheel 13a remains in the active position. Around 24 hours, the wheel 13a begins to drive the disc 1a to move it one step and bring behind the window 2 the sector 2 'carrying the number 2 not shown, while the disc 1b remains at rest, the wheel 13b being in the passive position.

The disc 1a is then moved in the same manner every 24 hours around 24 hours, while the disc 1b remains at rest, until the sector n ', carrying the number 15 not shown, is behind the window 2. This calendar position is shown in fig. 3, while it is around 24 hours. The wheel 13a is always in the active position and the wheel 13b in the passive position, only the disc 1a is moved during the following four hours to bring the sector 0 'behind the window 2 and reveal the sector 1''bearing the number 16 no represented.

From the initial position the disc 1a has thus advanced by n + 1 step, and therefore accomplished a complete revolution after having displayed the dates 1 to 15, while the disc 1b has advanced only by one step, at the same time as the first step of disc 1a.

The cam 20 being in the position shown in FIG. 3, the axes of the wheels 13a and 13b are supported respectively on the end of the control sectors 22 and 23. The cam 20 is then driven around 12 o'clock in one step, which has the effect of passing the wheel 13a in the passive position, and the wheel 13b in the active position. Under these conditions, around 24 hours, while the disc 1a is at rest, the disc 1b is advanced by one step to bring, behind the window 2 and the window 4, the sector 2 '' bearing the number 17 not shown. The disc 1b is then moved in the same way every 24 hours until the sector m '', bearing the number 31 not shown, is brought behind the window 2 after a complete revolution of the disc. The two discs 1a and 1b are then found in the initial position shown in FIG. 1, position marking the start of a new cycle.

From the description which has just been made, it follows that the cam 20 is driven every 24 hours by one step around 12 o'clock, while the discs 1a and 1b are optionally driven, depending on the active or passive position of the toothed wheels 13a and 13b, by one step every 24 hours towards 24 hours, the duration of each rotation of the cam or discs being in the present case of the order of four hours. Starting from the initial position shown in fig. 1, the discs 1a and 1b are first driven together by one step, then the disc 1a is driven alone by n steps, finally the disc 1b is driven alone by m-1 step, the two discs then finding themselves in the position initial.

It is obvious that, without departing from the scope of the present invention, the instant when the cam 20 takes a step, and the duration of the rotation of this cam and of the discs 1a and 1b to take a step, could be different from those described. Likewise, the first step of disc 1b after the initial position, could not coincide with the first step of disc 1a, but take place at any time during the time interval when this last disc displays the dates 1 to 15 In fact, the position and the rotation of the disc 1b can be arbitrary as long as the sector 0 ′ of the disc 1a is not opposite the window 2.

When the fingers 16a and 16b are not in engagement with the corresponding toothed sectors 18a and 18b, the discs 1a and 1b are free and could pivot under the effect of an angular acceleration which cannot fail to occur when the watch is scope. To avoid such unwanted rotations the discs could be positioned using conventional necklaces, but this solution has drawbacks which have already been pointed out. For this reason, in the present embodiment, use is made of a positioning device which blocks the discs when they are at rest, and frees them when they have to advance one step.

To this end, one end of an elastic jumper 30a comes to bear, with low pressure, against a tooth of one of the sectors 18a of the disc 1a. This jumper is arranged so as to allow the disc to pivot practically without resistance in the direction of arrow 5a, and to prevent it from rotating in the opposite direction by coming to butt against the tooth. Such a jumper is therefore called one-way jumper, or non-return jumper. A rigid lever 31a, pivoting in the plane of the disc 1a, is also arranged near the toothed wheel 13a so that one of its ends comes to bear against a tooth of another sector 18a of this disc for the prevent from turning in the opposite direction to arrow 5a. A spring 32a maintains the lever in this position by acting on its other end. Under these conditions the disc 1a is blocked in the two directions of rotation, as shown in FIGS. 1 and 2.

In order to allow the disc 1a to take a step in the direction of the arrow 5a at the desired time, the wheel 13a has a finger 33a which comes, around 24 hours and only when this wheel is in the active position, in contact with the other end of the lever 31a. Under the action of the finger 33a the lever 31a then swings so that its end moves away from the tooth that it touched, this at the moment when the fingers 16a are about to mesh with a sector 18a to drive the disc 1a with a step, as can be seen in FIG. 3.

The disc 1b also includes positioning members, referenced 30b and 31b, but which will not be described since they are similar to the members 30a and 31a already mentioned. In fig. 3 the wheel 13b is in the passive position. As a result, the finger 33b does not touch the lever 31b, which, under these conditions, blocks the disc 1b while the disc 1a is free to pivot.

A mechanism for rapid correction of the position of the discs 1a and 1b, and therefore of the date in the present case, will now be described with reference to FIGS. 4 and 5. This mechanism can advantageously be part of the display device when the latter is in the form of a module.

In a preferred embodiment, the disc correction mechanism, shown in plan in FIG. 4, essentially comprises a control mechanism 35 responding to the action of a pusher 36 accessible from outside the watch, and a clutch mechanism 37 having the function of either driving normally the intermediate toothed wheels 12a and 12b and the cam 20 from the toothed wheel 10, or to drive these mobiles in an accelerated manner in response to a pressure on the pusher.

The pusher 36 acts on a correcting lever 38 so as to rotate it around a shaft 39, from a first position or rest position, to a second position or end of stroke position shown in dotted lines in FIG. 4. The lever 38 is held in the rest position, when no pressure is exerted on the pusher 36, by a spring 40 integral with the lever and whose free end bears against a wall 41 of the cage, not shown , of the correction mechanism. This wall has a boss 42 causing a hard point at the start of the stroke of the lever 38. To pass this hard point and set the lever in motion, an initial pressure must be applied to this pusher 36, this pressure being chosen so as to separate any risk of accidental or incomplete disc correction.

The lever 38 acts on a movable member 43, in the form of a plate, to rotate it around the pivot center 3 of the discs 1a and 1b, but a different pivot center could also be suitable. To this end, the mobile 43 has an axis 44 which is housed in an elongated opening 45 of the lever 38. Passing from the rest position to the end-of-travel position, the lever 38 then makes the member 43 pivot. about 80 degrees.

On the axis 44 further pivots a pawl 46, one end of which carries a tooth 47 directed towards the pivot center 3. In the rest position of the lever 38, the other end of the pawl 46 bears against a wall 48 of the cage of the correction mechanism so as to place the pawl in a position where the tooth 47 is distant from the center 3. When the lever 38 begins to pivot in response to the action of the pusher 36, the pawl 46 leaves this position and turns in the sense who brings the tooth 47 closer to the center 3 under the effect of an elastic blade 49, integral with the member 43 and pressing on the end of the pawl.

The control mechanism 35 also includes a control gear 50 pivoting concentrically with the movable member 43, ie around the center 3 in the present case. This wheel has an external toothing 51 which cooperates with the pawl 46 and the clutch mechanism 37. When the correcting lever 38 is in the rest position, the tooth 47 of the pawl is located outside the toothing 51. On the other hand, as soon as the lever 38 leaves the rest position to reach the end-of-travel position, the pawl 46 rocks under the effect of the elastic blade 49 and the tooth 47 enters the toothing 51. The toothed wheel 50 is then driven in rotation on the same angle as the movable member 43 by the correcting lever 38. This rotation of the wheel 50 accomplished, the pawl 46 slides on the teeth 51 during the return of the lever 38 to the rest position.

The clutch mechanism 37, which is shown in section along the broken axis VV in FIG. 5, takes the place of the second toothed wheel 11 to establish a connection between, on the one hand, the toothed wheels 11 and 50, and, on the other hand, the rest of the display device. Toothing 51 meshes for this purpose with a pinion 55 secured to a shaft 56 pivoting in openings of the clockwork movement or of the cage of the correction mechanism not shown. On the pinion 55 is fixed an upper toothed wheel 57 which has two diametrically opposite openings 58 and 59 (fig. 4), and a external teeth 60 engaging, in place of the toothed wheel 11, with the intermediate wheels 12a and 12b of the display device. On the shaft 56 is further driven a mobile 61 having the same lug 25 as that of the wheel 11. This mobile also has a central cylindrical bearing and a radial bearing serving as a support for a lower toothed wheel 62. This wheel, which can pivot freely on the mobile 61, comprises two diametrically opposite openings 63 and 64 (FIG. 4), and an external toothing 65 engaging the first toothed wheel 10.

Finally between the upper and lower toothed wheels 57 and 62 is a clutch disc 66 in which are cut four flexible blades 67, 68, 69 and 70 (fig. 4), diametrically opposite two by two. The blades 68 and 70 are arranged and folded so as, on the one hand, to penetrate into the openings 63 and 64, and, on the other hand, to bear against the edges of these openings so that the wheel 62, driven by the wheel 10, in turn drives the disc 66. Similarly the blades 67 and 69 are folded so as to penetrate into the openings 58 and 59 so that the disc 66 can drive the wheel 57, while allowing the latter to turn in the same direction as wheel 62, but faster, thanks to the flexibility of the blades. The wheels 57 and 62 with the disc 66 therefore form a one-way clutch. So that the blades of the disc 66 do not penetrate into the corresponding openings of the wheels 57 and 62, to make the clutch active, only once per complete revolution of the wheel 57 relative to the wheel 62, the openings in each wheel , as well as the corresponding blades, are arranged at distances different from tree 56 (fig. 4). In this case, the openings 59, 63 and the blades 69, 68 are located closer to the center of rotation of the wheels 57 and 62, than the openings 58, 64 and the blades 67, 70.

Under these conditions, apart from the actions for correcting the disks 1a, 1b by the pusher 36, the toothed wheel 10 drives the wheels 12a and 12b and the cam 20 by means of the clutch mechanism which has just been described, of the same way as it did via the toothed wheel 11.

On the other hand, during an action for correcting the disks 1a and 1b, while the lever 38 passes from the rest position to the end-of-travel position, the wheel 50 drives in rapid rotation, in the same direction as the wheel 62, the pinion 55, the wheel 57 and the mobile 61 with the lug 25, the wheel 57 sliding on the clutch disc 66 so as to leave the wheel 62 at rest. The ratio of the number of teeth of the wheel 50 and the pinion 55 is determined so that the pinion performs, in the present embodiment, a complete revolution with each corrective action to advance the display device by one step, either from one calendar to the next calendar in the case of a calendar.

In order for the operation of the correction mechanism to be reliable, the pinion 55 must in fact, at each press on the pusher 36, rotate 360 degrees plus a safety angle taking into account the clearances and the manufacturing tolerances. This safety angle, typically about 10 degrees, is not critical, but if it is too large the display device may move two steps forward, the step it will normally take later, plus the correction step.

Of course the display device and the correction mechanism which have just been described can undergo further modifications than those already mentioned and come in other variants, obvious to those skilled in the art, without departing from the scope. of the present invention.

Claims (12)

Display device for a timepiece with analog movement, comprising an upper disc (1a) provided with a transparent window, said disc being behind a cover plate comprising a window (2), a lower disc (1b) arranged concentrically with the upper disc, said upper disc at least partially covering the lower disc, a part of which is visible through said window, means for driving step by step each disc in rotation around a pivot center (3) in a given direction from a moving part of the movement of the timepiece, and means for positioning said discs, characterized in that: - the upper disc (1a) is divided into n + 1 adjacent equal sectors, said sectors being numbered respectively 0 ', 1', ... n 'so as to pass in ascending order behind the window (2) when the disk rotates in said given direction, sector 0 'comprising said window; - the lower disc (1b) is divided into m adjacent equal sectors, said sectors being respectively numbered 1 '', 2 '' ... m '' so as to pass in ascending order behind the window (2) when the disc rotates in said given direction; - Said means (10, 11, 12a, 12b, 13a, 13b) for driving the discs (1a, 1b) have the function, from an initial position in which the sectors 0 'and m''are located opposite from the counter: a) to advance the upper disc (1a) by n + 1 successive steps of a sector to scroll behind the window (2) the n sectors 1 ', 2', ... n ', and replace the sector 0' in the starting position after a complete revolution of the disc, b) to move, during the movement of the upper disc, the lower disc (1b) by one step of a sector so that the sector 1 '' is behind the window (2), at the same time as the sector 0 ', at the end of the complete revolution of the upper disc, c) finally advance only the lower disk (1b) of m-1 successive steps of a sector to scroll, behind the window (2) and the window, the sectors 2 '', 3 '', 4 ''. .. me '' and go back to the initial position at the end of the last step, after passing behind either the wicket, the wicket and the window, of the n + m sectors 1 ', 2' ... n ', 1'',2''. ... m ''; and in that - Said positioning means (30a, 30b, 31a, 31b) block the discs (1a, 1b) when they are at rest, and release the disc executing a step. Display device according to claim 1, characterized in that said means for driving said discs comprise: - a gear train comprising, a) a first toothed wheel (10) driven on an axis movable in rotation of the movement of the timepiece, b) a second toothed wheel (11) engaging the first toothed wheel, c) a first (12a) and a second (12b) intermediate toothed wheel, each coming into engagement with said second wheel (11), d) a first (13a) and a second (13b) toothed drive wheel respectively engaging the first (12a) and the second (12b) intermediate wheel and each comprising at least one finger (16a, 16b), said drive wheels being further free to move in the direction of the pivot center (3) of the discs to occupy an active position or a passive position, e) n + 1 toothed sectors (18a) on the inside perimeter of the upper disc (1a), regularly spaced apart and each comprising at least one tooth, the finger (16a) of the first drive wheel (13a) engaging a tooth of one of said toothed sectors to advance the upper disc by one sector each revolution of the first drive wheel when said wheel is in the active position, and leaving the upper disc stationary when said first drive wheel is in the passive position, f) m toothed sectors (18b) on the inner perimeter of the lower disc (1b), regularly spaced and each comprising at least one tooth, the finger (16b) of the second drive wheel (13b) engaging a tooth of one of said toothed sectors for advancing the lower disc by one step of a sector at each revolution of the second drive wheel when said wheel is in the active position, and leaving the lower disc stationary when said second wheel drive is in passive position; and - a control device (20, 22, 23), activated by said movement and having the function of placing the first (13a) and the second (13b) toothed drive wheel in active or passive position depending on whether the upper disc and the lower disc must either take a step or remain stationary. Display device according to claim 2, characterized in that said control device comprises an annular cam (20), pivoting concentrically with the upper (1a) and lower (1b) discs and comprising: - n + m teeth (21) regularly spaced on the inner perimeter and engaging with a lug (25) disposed on the second toothed wheel (11) so that each revolution of said wheel the disc advances by one tooth , and - A control track (22, 23) cooperating with the drive gear wheels to place said wheels, according to the angular orientation of the cam, in the active position or in the passive position; said control track (22, 23) being arranged so that: a) the first (13a) and second (13b) drive gear wheels are in the active position during the initial position of the upper (1a) and lower (1b) discs to advance the two discs during the first step, b) the first drive wheel (13a) is in the active position and the second drive wheel (13b) in the passive position during the following n steps to advance only n steps of the upper disc (1a), and what c) the first drive wheel (13a) is in the passive position and the second drive wheel (13b) in the active position during the following m-1 steps to advance the lower disc (1b only) ) and return to the initial position. Display device according to claim 3, characterized in that each of the drive gear wheels (13a; 13b) has an axis (14a; 14b) which is disposed in an elongated opening (15a; 15b), said opening being oriented so as to allow each of said wheels to occupy a distant position or a position close to the pivot center (3) of the upper and lower discs, and in that the control track is formed by the outer perimeter of the cam (20) against which the axes of the wheels drive are supported by a spring (17a; 17b), said perimeter comprising a first (22) and a second (23) circular control sector, the radius of said second sector (23) being smaller than that of the first sector ( 22), said sectors being arranged so that, depending on whether the axis of a drive wheel bears against the first or second sector, said wheel is respectively in the active position or in the passive position. Display device according to claim 3 or 4, characterized in that it further comprises a jumper (26) for angularly positioning the cam (20) coming to cooperate with the teeth (21) arranged on its internal perimeter. Display device according to one of the preceding claims, characterized in that said means for positioning the upper (1a) and lower (1b) discs comprise, in relation to each of said discs: - a jumper (30a; 30b) with unidirectional action freely allowing the disc to pivot in said given direction, and preventing it from pivoting in the opposite direction by pressing against a tooth of one of said toothed sectors (18a; 18b); and - a rocking lever (31a; 31b), which, when it is arranged in a first position by means of an elastic member (32a; 32b), prevents the disc (1a; 1b) from pivoting in said given direction by taking pressing against a tooth of one of said toothed sectors (18a; 18b), and, when the lever is disposed in a second position by a finger (33a; 33b) of the corresponding drive wheel (13a; 13b), but only when said wheel is in the active position, it is moved away from the disc (1a; 1b) to release the teeth from the toothed sectors (18a; 18b) and allow said disc to take a step. Display device according to one of claims 2 to 6, characterized in that said first toothed wheel (10) is driven on the hour axis of the movement. Display device according to one of the preceding claims, characterized in that the upper (1a) and lower (1b) discs each have sixteen sectors, the sectors 1 'to 15' respectively bearing the numbers 1 to 15, and the sectors 1 '', 2 '', 3 '' ... 16 '' respectively the numbers 16, 17, 18 ... 31 to allow the indication of the successive dates of a month of 31 days. Display device according to one of the claims previous, characterized in that it further comprises means for rapid correction of the position of said discs (1a, 1b). Display device according to claim 9, characterized in that said correction means comprise: - a control mechanism (35) responding to the action of an external pusher (36); and - a unidirectional rotary clutch mechanism (37) replacing said second toothed wheel (11) and having the function of rotating said first (12a) and second (12b) intermediate toothed wheels as well as said cam (20), or normally by said first toothed wheel (10), or accelerated by said control mechanism (35) by the angle necessary so that, depending on the position of said discs (1a, 1b), one or both discs perform a not. Display device according to claim 10, characterized in that said control mechanism (35) comprises: - a correcting lever (38), said pusher (36) acting on one end of said lever to rotate it around a shaft (39) from a rest position to an end of travel position; - a control wheel (50) provided with a peripheral toothing (51); and - a pawl (46) with unidirectional action cooperating with said toothing (51) of the control wheel (50) and the other end of said corrector lever (38) for rotating said control wheel by a given angle when said lever moves from the rest position to the end position, and moving away from said toothing (51) when said lever (38) is in the rest position. Display device according to claims 10 and 11, characterized in that said clutch mechanism (37) comprises: - a toothed pinion (55) fixed on a shaft (56) and meshing with the toothing (51) of said control wheel (50); - A mobile (61) integral with the shaft (56) of said pinion (55) and comprising said lug (25) intended to drive said cam (20); - an upper toothed wheel (57) integral with said pinion (55) and comprising an axial opening (58; 59) and a peripheral toothing (60), said peripheral toothing coming into engagement with said first (12a) and second (12b) wheels intermediate teeth; - a lower toothed wheel (62) pivoting freely on said mobile (61) and comprising an axial opening (63; 64) and a peripheral toothing (65), said peripheral toothing coming into engagement with said first toothed wheel (10); and - a clutch disc (66) pivoting freely between said upper (57) and lower (62) wheels and comprising two flexible blades (67, 68; 69, 70), one of said blades (67; 69) penetrating into the opening (58; 59) of the upper wheel (57) and the other blade (68; 70) penetrating into the opening (63; 64) of the lower wheel (62) so that the lower wheel drives, via the clutch disc (66), the upper wheel while allowing said upper wheel to rotate accelerated, in the same direction as the lower wheel, during the rapid correction of the position of said discs (1a, 1b).

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