CH703451B1 - Calendar mechanism with bidirectional date corrector and timepiece including such a calendar mechanism. - Google Patents

Abstract

The invention relates to a date mechanism (2) comprising a twenty-four hour wheel (4) driven by a movement of a timepiece (3), a finger (5) for updating the date with pivoting date. said twenty-four hour wheel (4), and a date drive star (6). It is characterized in that it comprises a bidirectional date corrector (100) comprising a correction star (7), meshing with said date star (6) and situated between the latter and said finger (5), from which it is disengageable mounting through a disengaging mechanism (8), controlled by a control puller (1) and having a clutch position where said correction star (7) meshes with said finger (5), and a position of disengaging where it is released from said finger (5) to allow a date correction. The invention relates to a timepiece (3) comprising such a date mechanism (2).

Description

Description

Field of the invention

The invention relates to a date mechanism for a timepiece, comprising a twenty-four hour wheel driven by the movement of said timepiece, a date update finger mounted integral pivotally of said 24-hour wheel around a pivot axis, and a date drive star, with bidirectional date corrector.

The invention also relates to a timepiece comprising a date mechanism comprising a date drive star and a twenty-four hour wheel having a date update finger, and equipped with such a date date corrector mechanism.

Background of the invention

The invention relates to the field of watchmaking, and more particularly that of timepieces comprising date display mechanisms.

[0004] Date mechanisms are complex mechanisms.

The manual correction of the date is necessary, for months of less than thirty-one days, in the case of timepieces single date. This correction is generally performed, either by rotating the winding stem in a fast update position, or by actuating a dedicated pusher for this purpose.

Updating the date is not always easy, especially when the user wishes to change the date near the midnight time.

In addition, most known mechanisms do not allow the change of the date backwards.

US Patent 212 882 in the name of Baillot, exposes, as early as 1879, a date corrector mechanism with a pawl cooperating, under the action of a pusher, with the toothing of a wheel 31 days to advance this one.

[0009] Patent EP 1 1 15 041, in the name of Chopard Manufacture SA, discloses a mechanism for rapid manual correction of the date for a movement comprising a winding stem with three axial positions having a sliding pinion and a date star. . This mechanism comprises a tilting corrective lever having at one of its ends a beak cooperating with the toothing of the date star, and at the other end thereof a finger biased by a spring against a cam having at least one lift. This cam is carried by a corrective wheel driven by a kinematic connection by the sliding pinion, when the winding stem is in an intermediate axial date correction position. The lifts of the cam are pointed, so when the winding stem is out of the calendar adjustment position, the spring of return of the finger on the cam causes the return of this finger between two lifts of the cam, so that that the beak of the lever is no longer in contact with the date star. This mechanism allows the progress of the date by a rotation of any direction of the winding stem, but it does not allow the decline of the date.

A patent EP 1 660 952 in the name of Vaucher Manufacture Fleurier SA discloses a manual date corrector for single date and an automatic date corrector for perpetual calendar. This corrector comprises means for programming the correction of the display of the date according to the number of days of the current month introduced by the user or by an automatic mechanism, and means for restitution of this correction on the last day. real of the month considered. These programming means comprise a clutch movable consisting of two coaxial toothed discs drive in opposite directions, one by the thirty-one wheel, and the other by the control means which establish the number of days of the month, so that at the end of the current month the display means are automatically corrected. These two discs are coupled by a spring and a pawl system allowing independent rotation of a disc relative to the other. They still allow the second disk that is driven by the control means, on the one hand drives the other disk when it rotates in the first direction, and on the other hand does not cause this other disk when it turns in. the other direction and then just load the spring. In addition to these disks, the programming means comprise a finger fixed on the wheel of thirty-one, a rocker pivoting on the second disk and actuated by the finger on the last day of the current month, and then actuating another rocker independent of the mobile clutch. This other rocker immobilizes the second disk and releases it when it is actuated, so that, under the action of the spring, the first disk progresses rapidly to correct the date display. This complex device ensures correction in both manual and automatic, but it also does not allow to move back the date instead of moving it forward.

Similarly, patent application EP 1 538 494 is known in the name of Watch-U-License AG describing a fast date setting device, comprising a zipper driven by the winding stem and rotating a rocker carrier of a rocker gear which, in an intermediate position of the winding stem, meshes with a wheel coupled to a date corrector mobile provided with fingers capable of acting on a date indicator crown. This device requires an intermediate gear, and is one-way.

[0012] The patent EP 0 230 878 in the name of Complications SA provides a date corrector comprising a rod driving, via a train, a correction star meshing directly with a date star. This simple system is however not permanently usable because the date star is, in the vicinity of midnight, in cooperation with an elastic finger of the wheel of twenty-four hours, and any manual intervention is then detrimental to the movement. Moreover, this mechanism only makes it possible to advance the date, and not to move it back.

A more complex calendar correction mechanism perpetual calendar is presented by the patent EP 1 488 290 in the name of Manufacture Roger Dubuis SA, which is indexed to the position of an annual cam, detected by a probe, and provided for automatic operation, but not for manual correction.

However, these known mechanisms all use the kinematic chain of the winding and the sliding pinion, and the maneuver update date is day by day, is quite tedious, and causes wear of the winding mechanism and setting on time. And especially, although some allow the rotation of the winding stem in both directions to advance the date, they only allow the update in one direction of increase of the date, with of course a passage of 31 to 1, to return to a lower date than the one previously displayed.

EP 1 953 61 1 in the name of Longines Watch Company, Francillon SA, describes a bidirectional correction mechanism of a display device such as a date mechanism. This mechanism provides a reliable and effective solution to the problem of correction of the date in the direction of recoil. Two rakes tend, contrary to, to act on the display wheel of the date. The first rake is controlled by a first rocker which cooperates with a cam-limaçon integral with a date wheel, itself driven each day by a finger integral with the wheel of twenty-four hours. The second rake is controlled by a second rocker, which cooperates with a peripheral cam driven by the winding stem, and the peripheral cam is arranged to separate the first rocker cam-limaçon. Thus the date wheel can rotate in both directions. This improved mechanism however has many components, which make the cost quite high, and its size, especially at the peripheral cam, makes it difficult to adapt to all movements.

Summary of the invention

The invention proposes to provide a solution to the problem of a date correction at any time, and in both directions, with a number of components as small as possible, and a small footprint.

For this purpose the invention relates to a date mechanism for a timepiece, comprising a twenty-four hour wheel driven by the movement of said timepiece, an update finger date integral mounted in pivoting of said twenty-four hour wheel about a pivot axis, and a date drive star, with bidirectional date corrector, characterized in that said date mechanism comprises a bidirectional date corrector mechanism controlled by a operating lever pivotally mounted around a pivot axis, for a date mechanism of a timepiece, said date mechanism comprising a twenty-four hour wheel driven by the movement of said timepiece, a date update finger mounted integral pivotally of said wheel of twenty-four hours around a pivot axis, and a star of entra date of the calendar, characterized in that said correction mechanism comprises a correction star movable pivotally about a pivot axis and located between said finger and said date drive star, and in that said correction star is arranged for meshing with said date star of training, and in that said correction star is mounted disengageable said finger under the action of a disengagement mechanism controlled by said pull tab, said disengagement mechanism having at least two positions of which at at least one first clutch position, wherein said correction star is arranged to mesh with said finger, and at least one second clutch release position where said correction star is released from said finger to allow a date correction by pivoting thereof causing the pivoting of said date star.

According to one embodiment of the invention, said disengagement mechanism comprises three positions including a first said clutch position and a third said clutch position, which surround a second said disengaged position.

According to one embodiment of the invention, said disengagement mechanism comprises means for relative displacement of said pivot axis of said correction star with respect to said pivot axis of said finger, by displacement of at least one said axes.

According to one embodiment of the invention, said relative displacement means comprise means for transforming a one-way movement applied to said operating lever in two pivoting movements in the opposite direction of a first mounted lever. pivoting relative to a pivot axis, said first rocker having first bearing means arranged to directly or indirectly control the relative displacement of the pivot axis of said correction star relative to the pivot axis of said finger.

According to one embodiment of the invention, said first support means are constituted by a first bearing surface of said first rocker arranged to bear with a hub integral with said finger, or with a hub integral with said correction star, to move said finger away from said correction star, or respectively to move said correction star away from said finger.

According to one embodiment of the invention, said first bearing surface is a first oblong slot arranged to receive and guide said hub integral with said finger, or said hub integral with said correction star.

According to another embodiment of the invention, said first support means are arranged to cooperate with complementary support means that comprises a second flip-flop which is arranged to come at a second surface. support it comprises, in support with said hub integral with said finger, or with said hub integral with said correction star, to move said finger away from said correction star, or respectively to move said correction star away from said finger.

According to one embodiment of the invention, said second bearing surface is a second oblong slot arranged to receive and guide said integral hub of said finger, or said hub integral with said correction star.

According to one embodiment of the invention, said means for transforming a one-way movement applied to said operating lever in two pivoting movements in the opposite direction of a first pivotally mounted flip-flop with respect to an axis of pivoting comprise at least, at a first edge of said first rocker, a cam arranged to cooperate with a fulcrum of said pull and developing substantially radially relative to said pivot axis, said cam having, on the same side of a radial end of said pivot axis and passing through a crawling point, on either side of said cusp, a first track and a second track arranged to generate pivoting movements in the opposite direction of said first rocker when a centripetal or centrifugal stroke, respectively, of said fulcrum of said pull-rod from said first track towards said second track, respectively from said second track to said first track, through said cusp point which is reversal of the pivoting direction of said first flip-flop.

According to another embodiment of the invention, said first latch is driven by drive means or by elastic return means.

According to another embodiment of the invention, said elastic return means are arranged to bias said cam bearing on said bearing point of said pull tab.

According to another embodiment of the invention, said fulcrum of said pull tab is constituted by a pin describing a circular rotational movement about said pivot axis of said pull tab.

According to another embodiment of the invention, said date correction mechanism comprises a plate having an oblong slot arranged to receive and guide said integral hub of said finger, or said hub integral with said correction star.

According to the embodiments of the invention, the relative mobility between the correction star and the finger is obtained, or by a mobility of the axis of rotation of the correction star, the axis of pivoting of the finger being fixed, or by a mobility of the axis of pivoting of the finger, the axis of pivoting of the star of correction being fixed, or else by a mobility of the axis of pivoting of the star correction and mobility of the pivot axis of the finger.

The invention also relates to a timepiece comprising such a date mechanism.

Brief description of the drawings

Other features and advantages of the invention will appear on reading the description which follows, with reference to the accompanying drawings in which: FIG. 1 represents, schematically and in plan view, a first embodiment of the invention, in a first position of a pull tab corresponding to a first engaged position of a correction star with a finger integral with a wheel. twenty-four hours; fig. 2 represents, in a similar manner to FIG. 1, the same mechanism in a second position of the pull tab corresponding to a date correction position, in a disengaged position of the correction star relative to the finger integral with the twenty-four hour wheel; fig. 3 represents, in a similar manner to FIG. 1, the same mechanism in a third position of the pull tab corresponding to another engaged position of the correction star with the finger integral with the wheel of twenty-four hours; fig. 4 is a diagrammatic plan view of a second embodiment of the invention, in a first position of the pull tab corresponding to a first engaged position of the correction star with the finger integral with the wheel of twenty. -four hours; fig. 5 shows, similarly to FIG. 4, the same mechanism in a second position of the zipper corresponding to the date correction position, in a disengaged position of the correction star relative to the finger integral with the wheel of twenty-four hours;

4 fig. 6 shows, similarly to FIG. 4, the same mechanism in a third position of the pull tab corresponding to another engaged position of the correction star with the finger integral with the wheel of twenty-four hours; fig. 7 is a schematic view in plan view of a third embodiment of the invention, in a first position of the pull tab corresponding to a first engaged position of the correction star with the finger secured to the wheel of twenty. -four hours; fig. 8 represents, in a similar manner to FIG. 7, the same mechanism in a second position of the pull tab corresponding to the date correction position, in a disengaged position of the correction star relative to the finger integral with the twenty-four hour wheel; fig. 9 represents, in a similar manner to FIG. 7, the same mechanism in a third position of the pull tab corresponding to another engaged position of the correction star with the finger integral with the wheel of twenty-four hours; fig. 10 schematically and in plan view, a fourth preferred embodiment of the invention, in a first position of the pull tab corresponding to a first engaged position of the correction star with the finger secured to the wheel of FIG. twenty-four hours; fig. 11 represents, in a similar manner to FIG. 10, the same mechanism in a second position of the pull tab corresponding to the date correction position, in a disengaged position of the correction star relative to the finger integral with the twenty-four hour wheel; fig. 12 shows, similarly to FIG. 10, the same mechanism in a third position of the pull tab corresponding to another engaged position of the correction star with the finger secured to the wheel of twenty-four hours; fig. 13 is a diagrammatic, partial and perspective view from above, a timepiece having a date correction mechanism, in a fifth embodiment derived from the fourth embodiment; fig. 14 is a schematic, partial and perspective view from above, the mechanism of FIG.

13, the main support rocker on the finger being removed; fig. 15 shows schematically, partially and in perspective from below, the mechanism of FIG. 13; figs. 16 to 18 show, schematically, the kinematics of the fifth mode of FIGS. 13 to 15; fig. 19 represents, schematically, a variant of finger integral with the wheel of twenty-four hours, applicable to different embodiments.

Detailed Description of the Preferred Embodiments

The invention relates to the field of watchmaking, and more particularly that of timepieces comprising date display mechanisms. The invention proposes to provide a solution to the problem of a date correction at any time, and in both directions.

The invention thus relates to a bi-directional date correction mechanism 100 controlled by a pulling lever 1, for a date mechanism 2 of a timepiece 3. This operating puller 1, controlled by the maneuver of a rod 60, is in particular a crown zipper, more particularly the zipper of the time-setting ring and / or winding of the timepiece 3. This zipper 1 is movable pivotally mounted about an axis of pivoting 1 X.

According to the invention, this date mechanism 2 comprises, on the one hand a twenty-four hour wheel 4 driven by the movement of the timepiece 3, and on the other hand a finger 5 of day of the date. This finger 5 is pivotally mounted to the wheel of twenty-four hours around a pivot axis 5X. The date mechanism 2 further comprises a training star of the date 6.

According to the invention, the corrective mechanism 100 comprises a correction star 7 movable pivotally about a pivot axis 7X, and which is located between the finger 5 and the drive star of the date 6. This correction star 7 is arranged to mesh with the training star of the date 6, it can in particular be permanently engaged with the latter. The daily movement of the finger 5 for updating the date can be transmitted to the star of the calendar of the date 6 only through this correction star 7.

In particular to the invention, the correction star 7 is mounted disengageable finger 5 under the action of a disengaging mechanism 8.

This clutch mechanism 8 is controlled by the operating puller 1, and it comprises at least two positions, including at least a first clutch position, where the correction star 7 is arranged to mesh with the finger 5 or at least to interfere with its trajectory, since this finger 5 makes only one turn in twenty-four hours, and at least a second release position where the correction star 7 is released from the finger 5 to allow correction of date by its pivoting causing the pivoting of the drive star of the date 6.

Preferably, as shown in FIGS. 1 to 12, the clutch mechanism 8 comprises three positions, a first said clutch position and a third said clutch position, which surround a second said clutch release position.

This disengagement mechanism 8 comprises relative movement means 9 of the pivot axis 7X of the correction star 7 relative to the pivot axis 5X of the finger 5, by displacement of at least the one of said 7X or / and 5X axes.

In the preferred embodiments as shown in FIGS. 1 to 18 and which will be explained later in detail, these relative displacement means 9 comprise means 10 for transforming a one-way movement applied to said operating puller 1 in two pivoting movements in the opposite direction of a first rocker

1 1 pivotally mounted relative to a pivot axis 1 1 X. This first flip-flop 1 1 comprises first support means 12 arranged to directly or indirectly control the relative displacement of the pivot axis 7X of the correction star 7 with respect to the pivot axis 5X of the finger 5. Advantageously, the movement of the operating puller 1 is linear.

In a third advantageous embodiment as shown in FIGS. 7 to 9, the first support means

12 are constituted by a first bearing surface 13 of the first rocker January 1, which is arranged to bear with a hub 51 integral with the finger 5 to move the finger 5 of the correction star 7, or, in another embodiment, to come into abutment with a hub 71 integral with the correction star 7 to move the correction star 7 away from the finger 5.

In an advantageous embodiment, as in the example of the fourth embodiment illustrated in FIGS. 10 to 12, the first bearing surface 13 is a first oblong slot 14 arranged to receive and guide the hub 51 integral with the finger 5, or, in other embodiments, arranged to receive and guide the hub 71 secured to of the correction star 7.

In a particular embodiment, the first support means 12 are arranged to cooperate with additional support means 15 that comprises a second flip-flop 16. This second flip-flop 16 is arranged to come at the level of a second bearing surface 17 that it comprises, bearing with the hub 51 secured to the finger 5, as shown in FIGS. 4 to 6, to move the finger 5 away from the correction star 7. Or the second flip-flop 16 is arranged to come into abutment with the hub 71 integral with the correction star 7, as can be seen in FIGS. 1 to 3, to move the correction star 7 away from the finger 5.

In a particular embodiment, the second bearing surface 17 is a second oblong slot arranged in your second rocker 16 to receive and guide the hub 51 integral with the finger 5, or to receive and guide the hub 71 integral of the correction star 7.

The transformation means 10 of a one-way movement applied to the operating lever 1 in two pivoting movements in the opposite direction of a first rocker 11 pivotally mounted relative to a pivot axis 1 1 X may be realized in various ways. Preferably, these transformation means 10 comprise at least, at a first edge 19 of this first rocker 11, a cam 20. This cam 20 is arranged to cooperate with a fulcrum 21 of the operating puller 1, and it develops substantially radially relative to the pivot axis 1 1 X of the first flip-flop 1 January.

The cam 20 comprises, on either side of a cusp 23, and preferably on the same side of a radial 22 issuing from this pivot axis 11 X and passing through this cusp 23, a first track 24 and a second track 25. These are arranged to generate pivoting movements in the opposite direction of the first flip-flop 1 1 during a centripetal or centrifugal stroke of the fulcrum of the operating pull 1 from the first track 24 to the second track 25, respectively from the second track 25 to the first track 24, via this cusp 23, at which is reversed the pivoting direction of the first flip-flop 1 January.

The first flip-flop 1 1 is preferably arranged to be, directly or indirectly, driven by drive means 26 or by elastic return means 27, such as springs or the like. Preferably, the latter elastic return means 27 are arranged to return the cam 20 bearing on the bearing point 21 of the operating puller 1.

In a particularly economical embodiment, and as shown in FIGS. 1 to 12, the fulcrum 21 of the operating lever 1 is constituted by a first pin 28 describing a circular rotational movement about the pivot axis 1 X of the operating puller 1.

6 [0050] Advantageously, the operating pull 1 is constituted by the winding zipper and setting time of the timepiece 3.

Preferably, a plate 29, in particular an additional plate, serves as support for the entire mechanism 100. This plate 29 comprises, in some embodiments, as shown in FIGS. 1 to 9, an oblong slot 31 arranged to receive and guide the hub 51 integral with the finger 5 or the hub 41 of the twenty-four hour wheel 4 whose finger 5 is pivotally integral, or the hub 71 integral with the correction star 7.

The elastic return means 27 are advantageously constituted by a spring or a jumper 30, fixed on the plate 29, and which tends to push, directly or more generally indirectly, the correction star 7 to the finger 5 secured to the wheel of twenty-four hours 4 to put the correction star 7 bearing on the finger 5. These elastic return means 27 may consist in particular of several springs, or the like, independent of each other but all contributing to the recall the towards each other of the correction star 7 and the finger 5.

According to the embodiments of the invention, the relative mobility between the correction star 7 and the finger 5 can be obtained by a mobility of the pivot axis 7X of the correction star 7, the 5X pivot axis of the finger 5 being fixed, or by a mobility of the pivot axis 5X of the finger 5, the pivot axis 7X of the correction star 7 being fixed, or else by a mobility of the pivot axis 7X of the correction star 7 and by a mobility of the pivot axis 5X of the finger 5.

Figs. 1 to 18 illustrate five embodiments according to this principle.

A first embodiment is illustrated in FIGS. 1 to 3, and illustrates the case of the mobility of the pivot axis 7X of the correction star 7, the pivot axis 5X of the finger 5 being fixed.

The disengagement mechanism 8 includes, downstream of the zipper 1 operated by the user, a first latch 1 1 which is pivotally movable about a pivot axis 1 1X, and a second latch 16, which is pivotally movable about a pivot axis 16X and acts directly on the correction star 7.

The pivot axis 7X of the correction star 7 evolves, by a pin mounted at its hub 71, or preferably by the hub 71 itself, in an oblong slot 31 that includes the plate 29 , and which defines end positions 131 and 231 between which the correction star 7 can move.

The mobility of the correction star 7 in the oblong slot 31 is provided by the second flip-flop 16, which has a bore 32 cooperating with the hub 71 of the correction star 7, or with a pion integral with this hub 71. This oblong slot 31 extends preferably substantially perpendicular to a direction which joins the axis 6X of the date drive star 6 to the axis 7X of the correction star 7, and substantially radially by relative to the pivot axis 4X of the twenty-four hour wheel 4, which tends to move the hub 71 of the correction star 7 substantially radially relative to the finger 5. Preferably, the axis 16X pivoting of the second flip-flop 16 is adjacent, and preferably common, with a pivot axis 6X around which rotates the drive star of the date 6, which is preferably retained by a jumper 33.

The source of movement for the clutch control is provided by the operating puller 1. This pull tab 1, is actuated in the example of the figures by a pull arm 34, is pivotally movable about an axis of puller 1X, for controlling a pivoting movement of the first lever 1 1. This pull tab 1 comprises two support points, preferably made in the form of pins:

a first fulcrum 21, made in the example of the figures in the form of a first pin 28, which is arranged to bear on a first edge 19 of the first lever 1 1, ie at a first track 24, preferably substantially straight or of low curvature, either at a second groove track 25 or again at a cusp 23 located between this first track 24 and the second track 25;

- A second pull rod 36, which is arranged to cooperate with one of the notches 37A, 37B, 37C, which comprises the edge of a pull spring arm 37 fixed on the plate 29.

The pull tab 1, and therefore the first latch 1 1, occupy three positions illustrated successively in FIGS. 1 to 3.

A first position and a third clutch position of the first flip-flop 1 1 are of said normal status, that is to say, engaged, and the correction star 7 is resting on the finger 5. These two positions frame a second position, called declutching, of the first flip-flop 1 1 where the correction star 7 is released from the finger 5, thus allowing the date correction, by a wheel integral with the correction star 7 and Manipulated manually by a correction gear connected to the rod 60.

FIG. 1 illustrates the first position of the pull tab, corresponding to the depression of a crown connected to the pull tab 1. The pull tab 1 is held in position by the cooperation of its second pin 36 with a first notch 37A of the pull spring arm 37 Its first pin 28 rests on the first edge 19 of the first lever 1 1. This first lever 1 1 is pressed against the first pin 28, because it is subjected to a torsion torque exerted by the spring 30: the torque This torsion is applied by this spring 30 to the correction star 7, and tends to drive the bore 32 of the second flip-flop 16 in the clockwise direction with respect to the pivot axis 16X, as can be seen in FIG. 1.

Therefore, the second flip-flop 16 tends to pivot in the clockwise direction, and thus to press a first bearing face 38 that it has, on the opposite side to the bore 16C with respect to the axis 16X. against an additional bearing face 39

7 that has a second edge 40 of the first flip-flop 1 1, opposite its first edge 19. The second flip-flop 16 thus tends to rotate the first flip-flop 1 1 in the counter-clockwise direction, and therefore to bear on the first pin 28. This first pin 28 therefore limits the angular travel of the first flip-flop 1 1, and thus the correction star 7 remains resting on the finger 5. Preferably, the first edge 19 and the second edge 40 are substantially straight, or of small curvature, and move away from each other with increasing radius with respect to the pivot axis 1 1X of the first flip-flop 1 January.

The pivot axis 16X of the second flip-flop 16 is situated substantially between the pivot axis 1 1 X of the first flip-flop 1 1 and the pivot axis 7X of the correction star 7. The second flip-flop 16 16 comprises, on either side of its pivot axis 16X, two arms, the first arm 42 carrying the first bearing face 38, and the other second arm 43 carrying the bore 32, and these two arms 42 and 43 are on the same side relative to the pivot axis 5X of the finger 5. The hub 71 of the correction star 7 abuts on a first end 131 of the oblong slot 31 of the plate.

FIG. 2 illustrates the second disengaging position. The pull arm 34 is in an intermediate date correction position. Pulling the pull tab 1 causes the second pin 36 to pass through a second notch 37B of the pull spring arm 37. The torque exerted by it in this position is greater than that exerted indirectly by the spring 30. on the first flip-flop 1 1, and the first pin 28 remains resting on one end of the first track 24, closer to the pivot axis 11 X of the first flip-flop 1 1, at the cusp 23 of the cam 20 constituted by the first edge 19 of the first rocker 11.

The pulling of the pull tab 1 tends to rotate the first lever 1 1 clockwise, to push the first support face 38 of the second lever 16, and turn it in the counterclockwise direction . As a result, the hub 71 of the correction star 7 is driven by the bore 32 of the second flip-flop 16 towards a second end 231 of the oblong slot 31 of the plate 29, at an angle sufficient to exit the plate. reaching the finger 5, and is thus released from the finger 5. Thus, the correction star 7 can be maneuvered, both forwards and backwards, for the correction of the date display.

FIG. 3 illustrates the third position of the pull tab, corresponding to the maximum traction of a crown connected to the pull tab 1. The first lever 1 1 comprises, following the first track 24 and the cusp 23, and on the side of the pivot axis 1 1 X, a second track 25, in the form of a groove which is set back from the first track 24, that is to say re-entrant side of the complementary bearing surface 39 of the first lever 1 1 at its second edge 40. The pull tab 1 is held by the support of the second pin 36 in a third notch 37C of the pull spring arm 37.

The pull of the pull tab 1 brings the first pin 28 into the groove of the second track 25, and thereby allows a rotation of the first flip-flop 1 1 again in the counter-clockwise direction. The second flip-flop 16 pivots in the clockwise direction, and brings back the correction star 7, in its new angular position after adjustment of the date, in cooperation with the finger 5, since the hub 71 of the correction star 7 comes into abutment. on a first end 131 of the oblong slot 31 of the plate.

When we choose to use the zipper mechanism time setting of the timepiece, it is possible to perform the time setting in this position drawn from the zipper 1 and the associated crown. The timepiece is then returned to its usual position by depressing the crown in the first position of the zipper 1.

In sum, in this first embodiment, the pivot axis 5X of the finger 5 is fixed, while the pivot axis 7X of the correction star 7 is movable.

The other embodiments illustrate the case where the pivot axis 5X of the finger 5 is movable, while the pivot axis 7X of the correction star 7 is fixed. The arrangement of the zipper 1 is the same in these three particular embodiments. On the other hand, the pivot axis 7X of the correction star 7 is fixed with respect to the plate 29. Concerning the mobility of the finger 5, there are two possibilities: either the finger 5 is mobile, notably radially, with respect to the wheel of twenty-four hours 4, or it is the assembly consisting of the twenty-four hour wheel 4 and the finger 5 which is movable. This second alternative is illustrated by the following embodiments, but does not constitute a limitation of the invention.

The second embodiment is illustrated in FIGS. 4-6.

The pull tab 1 always cooperates with a first latch 1 1. However, the arrangement thereof is different from that of the first mode, and, preferably, the first track 24 and the second track 25 are substantially straight , and come closer to each other with a radius increasing with respect to the pivot axis 1 1X of the first rocker 11.

In contrast to the first embodiment, the pivot axis 7X of the correction star 7 is situated substantially between the pivot axis 1 1 X of the first flip-flop 1 1 and the pivot axis 16X of the second flip-flop. 16. The two arms, respectively first arm 42 and second arm 43, of the second flip-flop 16 are on either side of the pivot axis 5X of the finger 5.

The second flip-flop 16 is held in contact against the first flip-flop 1 1 by means of a spring, not shown in the figures.

In this second embodiment, the hub 41 to the pivot axis 4X of the twenty-four hour wheel 4 is movable in an oblong slot 31 of the plate 29, which allows it to move while remaining in touch

8 with the gear of the center wheel of the movement, which feeds it. This oblong slot 31 preferably extends substantially in the direction that joins the axis 4X of the twenty-four hour wheel 4 to the axis 7X of the correction star 7, which tends to move the hub 41, and therefore the finger 5, substantially radially to the correction star 7. Return means, such as a spring, not shown in the figures, tend to move the hub 41 away from the correction star 7, pushing back or pulling this hub 41 at the end 231 of the oblong slot 31 furthest from the correction star 7.

The second flip-flop 16 comprises, at its first arm 42, a first support surface 38, which cooperates with the first flip-flop 11 similarly to the first embodiment. It also comprises, at its second arm 43, a second bearing face 44, which pivots angularly in the same direction as the first bearing face 38, these two faces being located on the same side of the pivot axis 16X. This second bearing face 44 is facing a hub 41 that includes the twenty-four hour wheel 4, and is kept at a distance from the latter during normal operation, so as not to unnecessarily slow the movement. The twenty-four hour wheel 4 is always engaged with the center wheel of the movement, regardless of the position of its pivot axis 4X, or of a hub 41 which it comprises, with respect to the oblong slot 31 of the plate 29.

FIG. 4 illustrates the first depressed position of the pull tab 1, which is held in position by the cooperation of its second pin 36 with a first notch 37A of the pull spring arm 37. Its first pin 28 bears on the first track 24 of the first flip-flop 1 1. This first flip-flop 1 1 is pressed against this first pin 28, because it is subjected to a torsion torque exerted by the spring which plates the second flip-flop 16 against it: the torsion torque is applied by this spring on the second flip-flop 16, and tends to press the second bearing face 44, that includes the second arm 43 of the second flip-flop 16, on the hub 41 of the twenty-four hour wheel 4, pushing this hub 41 to a first end 131 of the oblong slot 31 on the side of the correction star 7, and therefore tends to push the finger 5 in cooperation with the correction star 7. The finger 5 can not therefore avoid the training of the star d e correction 7 through the second flip-flop 16, maintained in contact against the first flip-flop 1 1 through the spring.

FIG. 5 illustrates the second disengaging position. The pull arm 34 is in an intermediate date correction position. Pulling the pull tab 1 causes the second pin 36 to pass through a second notch 37B of the pull-spring arm 37. The torque exerted by it in this position is greater than that exerted indirectly by the spring which pushes the second flip-flop 16 towards the first flip-flop 1 1, and the first peg 28 is in abutment with the cusp 23. The pull of the pull-piece 1 thus tends to pivot the first flip-flop 1 1, to push back the first face support 38 of the second flip-flop 16, and rotate it in the counter-clockwise direction.

Therefore, the second bearing surface 44, which includes the second arm 43 of the second flip-flop 16, pivots, and allows the hub 41 of the twenty-four hour wheel 4, which tends to be distant from the correction star 7 by a return spring not shown in the figures, to move in the oblong slot 31 on the side opposite to the correction star 7, in a path sufficient to escape thereto, to reach the second end of the light 31 the position shown in FIG. 5. Thus, the correction star 7 can be maneuvered, both forwards and backwards, for the correction of the display of the date.

The advantage is that the twenty-four hour wheel 4 returns to the same place after the correction, without loss of reference.

FIG. 6 illustrates the third position of the pull tab, corresponding to the maximum traction of a crown connected to the pull tab 1, which is maintained by the support of the second pin 36 in a third notch 37C of the pull spring arm 37. The pull of the pull tab 1 brings the first pin 28 into the groove of the second track 25. This movement therefore makes it possible to rotate the first lever 1 1 again in the counter-clockwise direction. The second flip-flop 16 pivots in the clockwise direction, and brings back the second support face 44, which the second arm 43 of the second flip-flop 16, has on the hub 41 of the twenty-four hour wheel 4, and in abutment on the first end 131 of the light 31, and therefore tends to push the finger 5 in cooperation with the correction star 7. The finger 5 can not therefore avoid the drive of the correction star 7.

The third embodiment is illustrated in FIGS. 7 to 9. In this embodiment, the combination of the first flip-flop 1 1 and the second flip-flop 16 is replaced by a first single flip-flop January 1, which has, on the same side of its pivot axis 1 1 X located from preferably at one of its ends, a first arm 46 and a second arm 47. The first flip-flop 1 1 is held in contact against the pull tab 1 by biasing means which tend to rotate it in a counterclockwise direction. These return means are applied at a driving point 48 of the first latch 1 1. They may consist of a spring, not shown in the figures, or by an intermediate latch itself having a spring such as visible in another fifth embodiment in FIGS. 13 to 15, or whatever.

The pivot axis 4X of the twenty-four hour wheel 4 is, as in the second embodiment, movable in an oblong slot 31 of the plate 29, which allows it to move while remaining in contact with the gear of the center wheel of the movement, which feeds it. This oblong slot 31 preferably extends substantially in the direction that joins the axis 4X of the twenty-four hour wheel 4 to the axis 7X of the correction star 7, which tends to move the hub 41, and therefore the finger 5, substantially radially to the correction star 7. The

9 movements of the pull tab 1, and the cooperation of the second pin 36, in the different positions, with the notches 37A, 37B, 37C, of the pull spring arm 37, are similar to the other embodiments.

FIG. 7 illustrates the first position of the pull tab, corresponding to the depression of the pull tab 1. The pull tab 1 is held in position by the cooperation of its second pin 36 with a first notch 37A of the pull spring arm 37, not shown on this Fig. Its first pin 28 is supported on the first edge 19, which is located at the first arm 46, on the first track 24. This position of the first lever 1 1 allows a second bearing surface 50 that includes the second arm 47 to bear on the hub 41 of the twenty-four hour wheel 4, to maintain it at a first end 131 of the oblong slot 31 on the side of the correction star 7, and thus to engage the finger 5 with the correction star 7.

FIG. 8 illustrates the second disengaging position. The pull arm 34 is in an intermediate date correction position. The pulling of the pull tab 1 causes the passage of the second pin 36 on a second notch 37B of the pull spring arm 37, not shown in this figure. The torque exerted by the latter, in this position, is greater than that exercised, indirectly, the biasing means which push the first latch 11 towards the pull tab 1, and the first pin 28 remains in abutment at the cusp 23 The pull of the pull rod 1 thus tends to pivot the first rocker January 1, to push back the second bearing surface 50 of the second arm 47, away from the correction star 7. Thus, the hub 41 of the twenty-four hour wheel 4, which tends to be removed from the correction star 7 by a return spring not shown in the figures, can move in the oblong slot 31 on the side opposite to the star of correction 7, in a sufficient stroke to escape thereto, to reach the position at the second end 231 of the oblong slot 31 shown in FIG. 8. Thus, the correction star 7 can be maneuvered, both forwards and backwards, for the correction of the display of the date.

FIG. 9 illustrates the third position of the pull tab, corresponding to the maximum traction of a crown connected to the pull tab 1, which is maintained by the support of the second pin 36 in a third notch 37C of the pull spring arm 37. The pull of the pull tab 1 brings the first pin 28 into the groove of the second track 25. As a result, this movement allows rotation in the opposite direction of the first lever 1 1, which brings back the second bearing surface 50 of the second arm 47 resting on the hub 41 of the twenty-four hour wheel 4, by pushing it at the first end 131 of the oblong slot 31 closest to the correction star 7, and therefore tends to push the finger 5 7. The finger 5 can not therefore avoid the training of the correction star 7.

The fourth embodiment is illustrated in FIGS. 10 to 12. As for the third embodiment, the combination of the first flip-flop 1 1 and the second flip-flop 16 is replaced by a first single flip-flop 11, which comprises, on the same side of its pivot axis 1 1 X located preferably at one of its ends, a first arm 46 and a second arm 47. The first lever 1 1 is held in contact against the pull tab 1 by biasing means which tend to rotate it in a counterclockwise direction. These return means are applied at a driving point 48 of the first lever 1 1. They may consist of a spring, not shown in the figures, or by an intermediate rocker itself comprising a spring, or other .

The pivot axis 4X of the twenty-four hour wheel 4 is movable both in an oblong slot 31 of the plate 29, which allows it to move while remaining in contact with the gear of the movement center wheel, which feeds, similarly to that of the second and third modes described above, and in a first oblong slot 14, which is formed at the second arm 47 of the first flip-flop 1 January. This first oblong slot 14 extends in a direction oblique with respect to the direction of the oblong slot 31 of the plate 29. Any substantially tangential movement of the second arm 47 relative to the correction star 7 then drives the hub 41 so as to substantially radial with respect to the correction star 7. The movements of the pull tab 1, and the cooperation of the second pin 36, in the different positions, with the notches 37A, 37B, 37C, of the pull-spring arm 37, are similar to the other embodiments.

FIG. 10 illustrates the first position of the pull tab, corresponding to the depression of the pull tab 1. The pull tab 1 is held in position by the cooperation of its second pin 36 with a first notch 37A of the pull spring arm 37, not shown on this Fig. Its first pin 28 bears on the first edge 19, which is located at the first arm 46, on the first track 24. This position of the first rocker 11 tends to rotate it, and to pull the second arm 47, by causing the hub 41 of the twenty-four hour wheel 4 to occupy a first holding position at a first end 14 of the first oblong slot 14 and at a first end 131 of the oblong slot 31, in a position where the finger 5 can mesh with the correction star 7.

FIG. 1 1 illustrates the second declutching position. The pull arm 34 is in an intermediate date correction position. The pulling of the pull tab 1 causes the passage of the second pin 36 on a second notch 37B of the pull spring arm 37, not shown in this figure. The torque exerted by the latter, in this position, is greater than that exercised, indirectly, the biasing means which push the first lever 1 1 towards the pull tab 1, and the first pin 28 remains in support at the cusp 23. This position of the first lever 1 1 tends to rotate, and to push the second arm 47, forcing the hub 41 of the twenty-four hour wheel 4 to occupy a second holding position at a second end 214 of the first oblong slot 14 and at a second end 231 of the oblong slot 31, in a position where the pin 5 is clear of the correction star 7.

10

Claims (16)

FIG. 12 illustrates the third position of the pull tab, corresponding to the maximum traction of a crown connected to the pull tab 1, which is maintained by the support of the second pin 36 in a third notch 37C of the pull spring arm 37. The pull of the pull tab 1 brings the first pin 28 into the groove of the second track 25. This movement therefore allows a rotation in the opposite direction of the first lever 1 1, which brings the second arm 47 into traction by forcing the hub 41 of the 24-hour wheel 4 to occupy a first holding position at a first end 1 14 of the first oblong slot 14 and at a first end 131 of the oblong slot 31, in a position where the finger 5 can meshing with the correction star 7. The invention therefore relates to a date mechanism 2 comprising a drive star of the date 6 and a twenty-four hour wheel 4 comprising a date update finger 5, and equipped with such a corrector mechanism bidirectional date 100. The invention also relates to a timepiece 3 comprising a date mechanism 2 comprising a date drive star 6 and a twenty-four hour wheel 4 having a date update finger 5, and equipped with such a bidirectional date corrector mechanism 100. Figs. 13 to 15 illustrate a timepiece 3 having a date corrector mechanism 100, in a fifth embodiment derived from the fourth embodiment. The transmission of movement to the hub 51 of the finger 5 is by a first flip-flop January 1, which comprises a second arm 47 arranged as that of the fourth mode illustrated in FIGS. 10 to 12, with a light 14. This first flip-flop 1 1 differs from that of the fourth mode, in that it does not comprise directly, at its first arm 46, a first edge equipped with a cam 9. The disengagement mechanism uses a control rocker 52, which comprises a spring 53 tending to push it towards the pull tab 1, and which has, facing the latter, such an edge 19 provided with a cam 20 having, as before, a first track and a second track separated by a cusp. This control lever 52 cooperates with the pull tab 1 and the pull spring arm 37 in the same way as in the other four previous embodiments. The relative displacement means 9 of the pivot axis 7X of the correction star 7 relative to the pivot axis 5X of the finger 5, are then constituted by the motion transformation means 10 here more specifically. constituted by the control lever and the pull tab 1 on the one hand, and by the first rocker 11, which is driven by the control rocker at its drive point 48, on the other hand. These figs. 13 to 15 still illustrate a variant applicable to all the other embodiments, in which the finger 5 does not cooperate directly with the correction star 7 which cooperates with the star 6 training date, but with a star 7A coaxial and integral in pivoting of this correction star 7. Figs. 14 and 15 show the gear between the rod 60 and the correction pinion 70, and the complete chain to the center wheel. The kinematics of the fifth embodiment is shown in FIGS. 16 to 18, on which are visible the elastic return means 27 of the correction star 7, in the form of a jumper 30. The latch 52 is shown with its spring 53, which cooperates with a stop 27A visible on the fig. 15. This spring, associated with a pivot pin 54 of transmission between the first flip-flop 1 January 1 and the control rocker 52, allows to maintain or resiliently recall it in the position shown in FIG. 16. FIG. 19 shows a variant 55 of finger 5 integral with the wheel of twenty-four hours, which is applicable to the various embodiments above. This finger 55 is an elastic finger, preferably in the form of a circular sector. It comprises a bearing face 55 intended to cooperate with the correction star 7, and which extends at the end of a peripheral spring arm 57. This arm 57 also has a stop face 59 recessed, which is arranged to cooperate, in stroke limitation, with a stop 58 installed on the twenty-four hour wheel 4. The advantage of this variant is to allow, if necessary, a corrective action performed in the opposite direction, without deterioration of the mechanism: when back back the end of the support surface 55 can move substantially radially from the correction star 7, by bending the spring arm 57. With the finger 5 of the variants presented above, the arming mechanism is performed between the fixed finger and the jumper 30 of the correction star 7. In this variant of the spring finger 55, the arming is progressive, and balanced between the spring 57 and the jumper 30 of the correction star 7. This provision allows to accumulate more energy, for a longer period. claims 1. Time mechanism (2) for a timepiece (3), comprising a twenty-four hour wheel (4) driven by the movement of said timepiece (3), a finger (5) for setting day of the date mounted integral pivotally of said twenty-four hour wheel (4) about a pivot axis (5X), and a date drive star (6), characterized in that said date mechanism ( 2) comprises a bidirectional date corrector mechanism (100) controlled by an operating puller (1) pivotally mounted about a pivot axis (1 X), and in that said corrector mechanism (100) comprises a correction star (7) movable pivotally about a pivot axis (7X) and located between said finger (5) and said date drive star (6), and in that 11 that said correction star (7) is arranged to mesh with said date drive star (6), and in that said correction star (7) is mounted disengageable said finger (5) under the action of a clutch mechanism (8) controlled by said operating lever (1), said clutch mechanism (8) having at least two positions including at least a first clutch position, wherein said correction star (7) is arranged for meshing with said finger (5), and at least a second disengaging position where said correction star (7) is released from said finger (5) to allow a date correction by its pivoting causing the pivoting of said drive star of the date (6). 2. date mechanism (2) according to claim 1, characterized in that said disengaging mechanism (8) comprises three positions, a first said clutch position and a third said clutch position, which surround a second said position declutching. 3. date mechanism (2) according to claim 1 or 2, characterized in that said disengaging mechanism (8) comprises relative displacement means (9) of said pivot axis (7X) of said correction star (7). with respect to said pivot axis (5X) of said finger (5) by displacement of at least one of said axes (7X, 5X). 4. date mechanism (2) according to claim 3, characterized in that said relative displacement means (9) comprise means for transforming (10) a movement of one direction applied to said operating puller (1) in two pivoting movements in the opposite direction of a first rocker (1 1) pivotally mounted relative to a pivot axis (11 X), said first rocker (1 1) having first bearing means (12) arranged to directly or indirectly controlling the relative displacement of said pivot axis (7X) of said correction star (7) with respect to said pivot axis (5X) of said finger (5). 5. date mechanism (2) according to claim 4, characterized in that said first support means (12) are constituted by a first bearing surface (13) of said first rocker (1 1) arranged to come into support with a hub (51) secured to said finger (5), or with a hub (71) integral with said correction star (7), to move said finger (5) away from said correction star (7), or respectively to moving said correction star (7) away from said finger (5). 6. date mechanism (2) according to claim 5, characterized in that said first bearing surface (13) is a first oblong slot (14) arranged to receive and guide said hub (51) integral with said finger (5). , or said hub (71) integral with said correction star (7). 7. date mechanism (2) according to claim 5 or 6, characterized in that said first support means (12) are arranged to cooperate with complementary support means (15) that comprises a second rocker (16) which is arranged to come, at a second bearing surface (17) that it comprises, in abutment with said hub (51) integral with said finger (5), or with said hub (71) integral with said star correction device (7), to move said finger (5) away from said correction star (7), or respectively to move said correction star (7) away from said finger (5). 8. date mechanism (2) according to claim 7, characterized in that said second bearing surface (17) is a second oblong slot arranged to receive and guide said hub (51) integral with said finger (5), or said hub (71) integral with said correction star (7). 9. date mechanism (2) according to claim 4, characterized in that said means for transforming (10) a movement of one direction applied to said operating lever (1) in two movements of rotation in the opposite direction of a first rocker (1 1) pivotally mounted relative to a pivot axis (11 X) comprise at least, at a first edge (19) of said first rocker (1 1), a cam (20) arranged to cooperate with a fulcrum (21) of said maneuvering rod (1) and developing substantially radially relative to said pivot axis (11 X) of said first rocker (1 1), said cam (20) having the same side of a radial (22) issuing from said pivot axis (11 X) of said first rocker (1 1) and passing through a cusp (23), on either side of said cusp (23) , a first track (24) and a second track (25) arranged to generate pivoting movements of e opposite direction of said first flip-flop (11) during a centripetal or centrifugal stroke, respectively, of said fulcrum of said operating lever (1) from said first track (24) to said second track (25), respectively from said second track (25) to said first track (24), through said cusp (23) which is reversal of the pivoting direction of said first flip-flop (1 1). 10. Date mechanism (2) according to claim 4, characterized in that said first flip-flop (1 1) is driven by drive means (26) or by elastic return means (27). 1 1. date mechanism (2) according to claims 9 and 10, characterized in that said elastic return means (27) are arranged to bias said cam (20) bearing on said fulcrum (21) of said operating zipper (1). 12. date mechanism (2) according to claim 9, characterized in that said fulcrum (21) of said operating puller (1) is constituted by a first pin (28) describing a circular rotation movement around said pivot axis (1 X) of said operating puller (1). 12 13. Date mechanism (2) according to claim 5, characterized in that it comprises a plate (29) having an oblong slot (31) arranged to receive and guide said hub (51) integral with said finger (5), or said hub (71) integral with said correction star (7). 14. Date mechanism (2) according to one of claims 1 to 13, characterized in that said operating pull (1) is constituted by the winding pull and setting time of said timepiece ( 3). 15. Date mechanism (2) according to one of claims 1 to 13, characterized in that said finger (5) is constituted by a spring-finger (55) which is an elastic finger, having a bearing face ( 55) arranged to cooperate with said correction star (7), and which extends at the end of a peripheral spring arm (57) which has a recessed abutment face (59) arranged to cooperate, stroke limitation, with a stop (58) installed on said twenty-four hour wheel (4), the end of said bearing face (55) being movable substantially radially with respect to said correction star (7), by deflection of said spring arm (57), in the case of a maneuver in the opposite direction. 16. Timepiece (3) comprising a date mechanism (2) according to one of claims 1 to 15. 13