CH714178A1 - Annual calendar mechanism. - Google Patents

Abstract

The present invention relates to a date mechanism, comprising: a date wheel (10) intended to provide date information, a control wheel (12) intended to be driven by a clock movement and to drive the wheel of date (10) of at least one step per day. The control wheel (12) comprises: a first training level for driving the date wheel (10) one step at the end of each day, a second training level (12.4) for driving the date wheel (10) an additional step at the end of the last day of a 30-day month. The date wheel (10) carries: a month-end jumper (10.0), intended to cooperate with the second driving level (12.4) of the control wheel (12) at least at the end of the months of 30 days, said end-of-month jump mobile (10.0) being mounted in a satellite manner on the date wheel (10), a set of an annual cam (10.1) and a probe (10.2) arranged to angularly position the end-of-month jumper (10.0) with reference to its own axis of rotation on the date wheel (10). The invention allows bidirectional correction of an annual calendar mechanism or, according to particulate embodiments, leap or perpetual.

Description

Description

Technical Field [0001] The present invention relates to the field of watchmaking. It relates, more particularly, to a date mechanism comprising:

- a date wheel intended to provide information relating to the date,

- a control wheel intended to be driven by a watch movement and to drive the date wheel by at least one step per day.

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

STATE OF THE ART [0003] The date mechanisms are among the most appreciated horological complications, because they provide particularly useful information. However, in the particular field of mechanical watches, the date must generally be adjusted when a user puts on his watch after a certain period during which it has not been wound. Some constructions allow rapid correction, by acting directly on the date without affecting the time indication system. However, it is not always possible or desirable to have such a rapid correction system, because depending on the case, there is a risk of desynchronizing several displays.

Also, when the date is set via the hour wheel, that is to say that the hour hand must make two turns to change the date by one unit, it is particularly appreciable to be able to make the correction in both directions, in order to limit the number of turns to be performed.

However, among the date mechanisms, in particular the annual calendars which make it possible to take into account the duration of the months of 31 or 30 days, or the perpetual calendars, which also take into account the duration of the months of February from 28 or 29 days, there are few systems that allow a correction in both directions.

The present invention aims to provide a new calendar mechanism, compact and reliable, allowing bidirectional correction and applicable to an annual calendar, a leap calendar or a perpetual calendar.

Disclosure of the invention More specifically, the invention relates to a date mechanism as proposed in the claims, as well as a timepiece comprising such a date mechanism.

Brief description of the drawings [0008] Other details of the invention will appear more clearly on reading the description which follows, made with reference to the appended drawing in which:

fig. 1 and 2 are perspective views, respectively from above and from below, of a mechanism according to a preferred embodiment of the invention, fig. 3 and 4 represent this same mechanism, in plan, respectively from below and from below, when passing from the 30th of a month, to the 1st of the following month, either during a correction in advance or during a normal training by the movement, fig. 5 and 6 represent this same mechanism, in plan, respectively in view from below and from below, during the transition from the 1st of a month of March, to the 28 of the previous February, that is to say during a correction backward, fig. 7 and 8 show details of the system, in both directions of a correction, and fig. 9 shows in detail the elements relating to the taking into account of leap years.

Embodiment of the invention [0009] There is shown in FIG. 1 and in fig. 2, perspective, top and bottom views of a date mechanism according to a preferred embodiment of the invention. The date mechanism can be arranged on an assembled module plate and kinematically connected to a basic movement, or if necessary, be integrated into a movement.

The mechanism includes in particular a date wheel 10 intended to provide information relating to the date. This date wheel 10 can carry indications or a disc with the 31 numbers of the date or carry a hand intended to move opposite a graduation. The date wheel 10 typically has 31 teeth and is intended to be driven at a rate of one step per day, around midnight, except for the last day of a month of less than 31 days where, as will be detailed below. afterwards, it is intended to be driven by at least one additional step.

The date wheel 10 is intended to be driven by a control wheel 12, which it is driven by the watch movement.

The remote-controlled wheel 12 comprises first of all a power take-off member, in the form of a star 12.0 intended, in the example illustrated, to be pushed one step per day by a 24-hour wheel of the movement, not shown. Other types of training are also possible, for example by a rocker.

The star 12.0 is mounted coaxially and integral in rotation with a first drive level 12.2 to drive the date wheel 10 by one step at the end of each day. The first training level 12.2 also takes the form of a star. Preferably, the stars have the same number of branches and they are superimposed on each other, in order to favor the synchronization of the drive of the date wheel 10 with the time of movement. In this case, the stars have 7 branches each.

To allow the thicknesses of the mechanism to be reduced while controlling the interactions of the star 12.0 and that of the first drive level 12.2, with the various elements of the mechanism, the star 12.0 has shorter branches than that of the star 12.2, so that it has no interaction with the date wheel 10, even if it is situated in the same plane as the teeth of the date wheel 10.

The control wheel 12 also includes a second drive level 12.4 for driving the date wheel 10 by an additional step at the end of the last day of a month of 30 days, as well as a third level d training 12.6 to drive the date wheel 10 by three additional steps at the end of the last day of February, typically when it lasts 28 days.

More particularly, the third level 12.6 has actuation zones 12.62 located on branches, which have a shape similar to a branch of the Maltese cross. The second level 12.4 has actuation zones 12.42 interposed between the branches of the second level 12.4, advantageously in the shape of a U, opening to the outside, that is to say in the direction of the date wheel 10. For these two levels 12.4, 12.6, the actuation zones are symmetrical with respect to a radius of the control wheel 12, allowing operation in both directions of rotation, as will be understood below.

For each level 12.4, 12.6, there are 7 actuation zones, respectively 12.42 and 12.62. The spokes forming the axes of symmetry of the actuation zones 12.42 of the second level 12.4 are superimposed on the branches of the stars 12.0 and 12.2, while the rays forming the axes of symmetry of the actuation zones 12.62 of the third level 12.6 are superimposed on the bisectors angles formed by the rays of two branches of stars 12.0,12.2 juxtaposed.

As can be seen particularly in Figs. 1 and 2, the second 12.4 and third 12.6 training levels may have come in one piece, the actuation zones 12.62 of the third level 12.6 extending, in a separate plane, the actuation zones 12.42 of the second level 12.4.

The control wheel 12 thus comprises three drive levels 12.2, 12.4, 12.6 distinct, capable of cooperating with the date wheel 10, at determined times, as will appear below.

To do this, in addition to its teeth 31 intended to cooperate with the first drive level 12.2 of the control wheel 12, the date wheel 10 carries:

- a month end jump mobile 10.0, intended to cooperate the second 12.4 or the third 12.6 drive levels of the control wheel 12 at the end of the months less than 31 days, said month end jump mobile 10.0 being mounted by satellite on the date wheel 10,

- a set of an annual cam 10.1 and a feeler 10.2 arranged to angularly position the end of month jump mobile 10.0 with reference to its own axis of rotation on the date wheel 10.

The annual cam 10.1 is arranged by satellite on the date wheel 10. It is integral with a drive board 10.3, intended to be driven by cooperating with a fixed finger 14, located in the center of the wheel. date 10, and around which the date wheel 10 pivots. The drive board 10.3 typically has 12 teeth and advances by one step at each turn made by the date wheel 10, that is to say each month.

As can be seen particularly in Figs. 7 and 8, the annual cam 10.1 has a profile defining portions of different radii, corresponding to the different months. As will be understood later, the radii of said portions are determined so as to angularly position, in a synchronized manner, the end of month jump mobile 10.0 in relation to the control wheel 12. There is therefore a correspondence between the shape of the cam and the length of the months of the year, the initials of which are written in the center of their respective portions. 12 portions are thus defined, one per month, it being understood that if two consecutive months have the same number of days (July-August and December-January), the two consecutive portions of the same radius are extended.

Thus, the months of 31 days correspond to portions of the cam 10.1 having the largest radii, the months of 30 days correspond to portions of the cam 10.1 having relatively small radii, and the portion corresponding to the month of February has the smallest radius, forming a notch in the cam 10.1.

The probe 10.2 is held in contact with the profile of the cam 10.1. To allow the cam 10.1 to rotate in both directions and thus to have a bidirectional date drive, in particular in the case of correction, the variations of the cam radii are progressive. Similarly, the profile of the fixed finger 14 and that of the teeth of the drive board 10.3, are arranged so as to allow rotation of the board in both directions of rotation, depending on whether the date wheel rotates in the opposite direction. clockwise (with reference to fig. 8, which is a view from below), or clockwise (with reference to fig. 9, which is also a view from below) . The probe 10.2 is integral with a rack 10.4, engaged with a pinion 10.5 integral with an intermediate rake 10.6, which is engaged with a second pinion 10.7, integral with the end of month jumping mobile 10.0. All the elements of the kinematic connection between the probe 10.2 and the end of month jump mobile 10.0 are mounted on the date wheel

10. However, the detail of this kinematic connection is given only by way of nonlimiting example.

In an embodiment of leap calendar type, that is to say taking into account the months of 30 days and 28 days, but not 29 days, the end of month jump mobile 10.0 comprises two arms 10.01 and 10.02, of different lengths. A first arm 10.01, long, is arranged to cooperate with the second level 12.4 of the control wheel 12 at the end of the 30-day months, to cause the date wheel 10 to take an additional step (FIG. 4). A second arm 10.02, short, is arranged to cooperate with the third level 12.6 of the control wheel 12 at the end of the month of 28 days, to cause the date wheel 10 to take three additional steps. The interaction between the second arm 10.02 and the third level 12.6 is visible in fig. 6, but in the case of a correction, that is to say with the control wheel located on the upstream side, in the direction of rotation indicated by the arrow.

Thus, depending on the radius of the portion of the cam 10.1 with which the probe 10.2 cooperates, the end-of-month jump mobile 10.0 present in the travel of the control wheel 12:

- no arms, for the months of 31 days, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven in a single step by the first level 12.2 of the control wheel 12,

- the long arm, for the months of 30 days, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven by one step by the first level 12.2 of the control wheel 12, and d '' an additional step via the second level 12.4 of the control wheel 12, or

- the short arm, for the months of February, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven by one step by the first level 12.2 of the control wheel 12, and three additional steps via the third level 12.6 of the control wheel 12.

With this construction, in the case of a leap year, it will be necessary to manually manage the adjustment at the end of February.

In an embodiment not shown allowing an annual calendar to be obtained, that is to say taking into account only the months of 30 and 31 days, the end of month jump mobile 10.0 only includes an arm, corresponding to the long arm 10.01 above, and the control wheel 12 includes only the first 12.2 and second 12.4 drive levels.

At the end of the 31-day months, as above, the month-end jumping mobile 10.0 has no arms in the travel of the control wheel 10.0, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven in a single step by the first level 12.2 of the control wheel 12.

At the end of the 30-day months, the long arm 10.01 is positioned in the travel of the control wheel 12, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven by a step through the first level 12.2 of the control wheel 12, and an additional step through the second level 12.4 of the control wheel 12.

The month of February can be treated as a month of 30 or 31 days, the display of the calendar at the end of February having to be managed manually.

In a preferred embodiment, in particular illustrated in particular in FIG. 9, the date mechanism is adapted to provide a perpetual calendar, taking into account the months of February in leap years.

To do this, the annual cam 10.1 is associated with a leap cam 10.8 arranged to take a turn in 4 years and position every 4 years, at the February notch of the cam, a portion of larger radius .

Regarding the sharing plans, the probe 10.2 is arranged to cooperate with the annual cam 10.1 and the leap cam 10.8, in order to cooperate with the latter when it takes position in the notch of February. It will be noted that over three-quarters of its perimeter, the leap cam 10.8 has a radius less than the February portion of the annual cam 10.1, so that the feeler 10.2 cooperates, in February in non-leap years, only with the annual cam 10.1.

To control the leap cam 10.8, the annual cam 10.1 is integral with a pinion 10.9, engaged with a first stage of a return mobile 10.10, which comprises a second stage also engaged with a drive board leap 10.11, integral with the leap cam 10.8, the gear ratios being determined so that the leap cam 10.8 performs one revolution in 4 years.

In this embodiment, the end of month jump mobile 10.0 comprises a third arm 10.03, of intermediate length between the long arm 10.01 and the short arm 10.02, arranged to be positioned in the travel of the control wheel 12, particularly of its third level 12.6, when the probe 10.2 is in contact with the leap cam 10.8. Typically, the third arm 10.03 is angularly offset from the second arm 10.02, being located in the same plane.

Thus, at the end of the 29-day months, the intermediate arm 10.03 is positioned in the travel of the control wheel 12, with the consequence that the date wheel 10, on the evening of the last day of the month, is driven one step through the first level 12.2 of the control wheel 12, and two additional steps through the third level 12.6 of the control wheel 12.

In order to ensure good transmission of the torque between the arm (s) of the end of month jump mobile 10.0 and the control wheel 12, the date mechanism may also include a locking system 10.12 of the jump mobile at the end of the month 10.0. This locking system 10.12 is designed to block the rotation of this mobile with reference to its axis, at least when said end-of-month jump mobile 10.0 cooperates with the control wheel 12. Thus, it is possible to mount the end of month jump mobile 10.0, in order to consume little energy to position the end of month jump mobile 10.0.

Advantageously, the locking system 10.12 comprises a locking lever 10.13, positioned by a locking cam 16, fixedly mounted in the center of the date wheel 10 which pivots with reference to it. The locking lever 10.13 comprises a feeler 10.15 held in contact with the locking cam 16, and a lug 10.14 able to cooperate with the end of month jump mobile 10.0 to block its rotation.

Thus, at the end of the month, typically from the 26th, when the end of month jump mobile 10.0 is positioned, the lug 10.14 of the locking lever 10.13 falls into the teeth of the end jump mobile of month 10.0, thus blocking its rotation on its axis, allowing a transmission of energy between the control wheel 12 and the date wheel 10.

The invention also relates to a timepiece comprising a date mechanism as described above.

Thus, thanks to the configuration of the driven elements and the driving elements, as well as the cams and feelers, the date system according to the invention makes it possible to operate by rotating the control wheel in both directions, either under the action of movement, either under the action of a corrector kinematically connected to the control wheel. This corrector can act via the hour wheel, or be a rapid corrector, acting directly on the control wheel, typically the star 12.0 for example.

Thus, a particularly reliable and compact date mechanism is proposed, which can be actuated in both directions by a correction system. Those skilled in the art can directly adapt it to make a simple calendar, a leap calendar or an annual calendar. The example described above, with reference to the figures, has been given by way of nonlimiting illustration of the invention, the scope of which is defined by the claims.

Claims (14)

claims 1. Date mechanism including - a date wheel (10) intended to provide information relating to the date, - a control wheel (12) intended to be driven by a watch movement and to drive the date wheel (10) by at least one step per day, in which the control wheel (12) comprises: - a first level of training (12.2) to drive the date wheel (10) one step at the end of each day, - a second drive level (12.4) for driving the date wheel (10) by an additional step at the end of the last day of a month of 30 days, and in which the date wheel (10) carries: - a month-end jumping mobile (10.0), intended to cooperate with the second drive level (12.4) of the control wheel (12) at least at the end of the 30-day months, said jumping mobile end of month (10.0) being mounted by satellite on the date wheel (10), - a set of an annual cam (10.1) and a feeler (10.2) arranged to angularly position the end of month jump mobile (10.0) with reference to its own axis of rotation on the date wheel (10) . 2. Date mechanism according to claim 1, characterized in that the annual cam (10.1) is integral with a drive board (10.3), intended to be driven by cooperating with a finger (14) fixed in the center of the date wheel (10). 3. Date mechanism according to one of claims 1 and 2, characterized in that the annual cam (10.1) has a profile defining portions of different radii, said probe (10.2) being held in contact with the profile of the annual cam (10.1), the radii of said portions being determined so as to angularly position in synchronized fashion the end of month jump mobile (10.0) in relation to the control wheel (12). 4. Date mechanism according to one of the preceding claims, characterized in that the feeler (10.2) is secured to a rack (10.4), engaged with a pinion (10.5) secured to an intermediate rake (10.6), which is engaged with a second pinion (10.7) secured to the end of month jump mobile (10.0). 5. Date mechanism according to one of the preceding claims, characterized in that the control wheel (12) has a third drive level (12.6) for driving the date wheel (10) by three additional steps at the end from the last day of a 28-day month. 6. Date mechanism according to claim 5, characterized in that the end of month jump mobile (10.0) comprises at least two arms (10.01, 10.02) of different lengths, intended to cooperate respectively with the second drive level (12.4) and with the third training level (12.6). 7. Date mechanism according to one of claims 5 and 6, characterized in that the third drive level (12.6) has actuation zones (12.62) located on branches, the second level (12.4) having actuation zones (12.42) inserted between the branches of the third level (12.6), said actuation zones (12.42, 12.62) being symmetrical with respect to a radius of the control wheel (12), allowing actuation of the mobile the end of month jump in both directions of rotation. 8. Date mechanism according to claim 7, characterized in that said branches have a shape similar to a Maltese cross branch, and the actuation zones (12.42) of the second level (12.4) are U-shaped, s opening onto the outside. 9. Date mechanism according to one of claims 5 to 8, characterized in that the annual cam (10.1) is associated with a leap cam (10.8) arranged to make a turn in 4 years and position every 4 years, at the level of the February notch of the cam, a cam portion of radius larger than the February portion of the annual cam (10.1), and in that the probe (10.2) is arranged to cooperate with one or the 'other of the annual cam (10.1) and the leap cam (10.8), depending on whether the leap cam (10.8) protrudes radially from the annual cam (10.1). 10. Date mechanism according to claim 9, characterized in that the annual cam (10.1) is integral with a pinion (10.9), engaged with a first stage of a return mobile (10.10), which comprises a second stage also engaged with a leap training board (10.11), integral with the leap cam (10.8), the gear ratios being determined so that the leap cam (10.8) makes a revolution in 4 years. 11. Date mechanism according to one of claims 9 and 10, characterized in that the end of month jump mobile (10.0) has three arms. 12. Date mechanism according to one of the preceding claims, characterized in that the date wheel (10) further carries a locking system (10.12) of the end-of-month jump mobile (10.0), arranged to block the rotation of the latter with reference to its axis, at least when said end of month jump mobile (10.0) cooperates with the control wheel (12). 13. Date mechanism according to claim (12), characterized in that the locking system (10.12) comprises a locking lever (10.13), positioned by a locking cam (16), fixedly mounted in the center of the wheel. date (10) which pivots with reference to it, the locking lever (10.13) comprising a lug (10.14) capable of cooperating with the end of month jump mobile (10.0) to block its rotation. 14. Timepiece comprising a date mechanism according to one of the preceding claims.