CH706346A2 - Mechanism for providing day of month in watch, has annual wheel, where displacement of annual wheel under action of mobile corrector is transmitted to group of drive elements of movable date via kinematic connection - Google Patents

Abstract

The mechanism has a movable date (10) that is intended to be moved at a rate of 1-by-31 turn per day as per a specific force. The movable date is provided with a group of drive elements (12). An annual wheel (20) is arranged to be driven at the rate of one revolution per year via a kinematic connection (14) that is connected at the group of drive elements. The displacement of the annual wheel under the action of mobile corrector (24) is transmitted to the group of drive elements of the movable date via the kinematic connection.

Description

Technical area

The present invention relates to the field of mechanical watchmaking. It concerns, more particularly, a semi-perpetual calendar mechanism, that is to say a mechanism making the change of date at the end of each month, able to take into account the exact duration of the month. Such a mechanism does not, however, adapt to February 29 leap years. The proposed date mechanism can also evolve into a perpetual calendar mechanism, capable of adapting to leap years.

State of the art

The display of the calendar is a complication widely used in the watch industry. Most frequently, a date indicator is driven one step per day, in a 31-day cycle. It is then necessary for a user to manually correct the display for months of less than 31 days. More advanced systems, the semi-perpetual calendars mentioned above, make it possible to take into account the 30-day months, including the month of February, without, however, managing the 29 days of February in leap years. Perpetual calendar mechanisms allow the display of the date to remain accurate, without manual correction, adapting to variations in the duration of the months. This kind of complication is among the most complex.

There are known perpetual calendar mechanisms implementing a cam, which allows to take into account the different durations of the months. Flip-flops are arranged to bear on the cam and their displacement, varying according to the profile of the cam and therefore according to the duration of the month, allows to drive on a longer or shorter stroke, a mobile kinematically connected to the display of the calendar. In particular, explanations of this kind of system can be found in the book "Théorie d'horlogerie" by Reymondin et al. at the Editions of the Federation of Technical Schools, pages 205 and following.

Other systems offer to achieve such a display, with drive systems involving only cogs. This is for example the case of the mechanism described in the document WO 0 148 568 which proposes to produce an instantaneous mechanism, by implementing a wheel of the duration of the months, performing a turn in four years and comprising, for the months of less than 31 days, groups of teeth corresponding to the difference between 31 and the number of days of the targeted month (ie 1 tooth for a month of 30 days, 2 teeth for a month of 29 days, 3 teeth for a month of 28 days). Such a system is also complex and is relatively thick. In addition, the size of the teeth of the wheel of the duration of the months makes it difficult to drive the mobile display on a sufficient race.

The present invention aims to provide a perpetual calendar mechanism implementing a reduced number of parts and avoiding the use of any lever or lever in the drive of different mobiles.

Disclosure of the invention

More specifically, the invention relates to a date mechanism comprising a date mobile, intended to be driven at a rate of 1/31 turn per day by a first power take-off. This date mobile is provided with a first group of training elements. An annual mobile is arranged to be driven at a rate of one turn per year by the date mobile, via a first kinematic link connected to the first group of drive elements. This annual mobile has five active parts corresponding to the five months of less than 31 days.

A correction mobile is intended to be driven by a second PTO to which it is connected by a second kinematic link. The active parts of the annual mobile are positioned so as to be, at the end of the months of less than 31 days, in the race of the mobile corrector.

The date mechanism is arranged so that the movement of the annual mobile under the action of mobile corrector at the end of the month of less than 31 days is transmitted to the first group of drive elements of the mobile phone. date, via the first kinematic link.

[0009] PTO means an element of the mechanism by which energy is received from the base movement.

According to a preferred variant, the annual mobile comprises, at the level corresponding to the month of February, a retractable drive element arranged to be retracted the leap years, to achieve a perpetual calendar mechanism.

Brief description of the drawings

Other details of the invention will appear more clearly on reading the description which follows, made with reference to the accompanying drawings in which: <tb> fig. 1 <sep> is a plan view of a date mechanism according to the invention, <tb> fig. 2 <sep> represents, in isolation, the particular parts of a perpetual calendar mechanism, which can be implemented within the scope of the invention.

Mode (s) of realization of the invention

The date mechanism according to the invention and which will be described below, can be assembled to a movement, either in an integrated construction or in a modular construction. Since the kinematic links between the mechanism and the movement are within the abilities of those skilled in the art, they will not be described in detail in the present application.

Thus, the date mechanism according to the invention comprises a mobile date 10, typically provided to carry indications for displaying the date. In the embodiment described in FIG. 1, the date mobile 10 takes the form of a ring arranged to be driven clockwise, at the rate of 1/31 turn per day by the movement, at a first power take-off . For this purpose, it will be possible for example to provide that the date mobile 10 is integral with a drive board, not shown, provided with 31 teeth and capable of being actuated by a finger carried by a wheel 24 hours, it is ie performing a turn in 24 hours. According to the invention, the date mobile 10 is provided, on its inner periphery, with a first group of drive elements 12. Typically, the first group of drive elements comprises four recesses separating three truncated teeth and grouped on the mobile of date 10, on a sector of 4x (1/31) turns. The date mobile could also be a wheel having at its periphery the first group of training elements.

Note that in the present description, the concepts of drive elements or teeth, may designate either a projecting portion or a recessed portion, with reference to the original circle of a wheel or a ring, one or the other may be defined as the active portion of a gear.

The mechanism comprises a first kinematic link 14 arranged to be driven by the first group of drive elements 12 of the mobile date 10. This first kinematic link 14 may comprise, according to the proposed example, a first mobile in star 16, whose branches of a first plank advantageously cooperate with the first group of driving elements 12. The branches of the first plank also make it possible to ensure the positioning of the star-shaped wheel 16 by resting on the inner edge The mobile star 16 also includes a second board 16b meshing with a second mobile 18, provided to drive a first level 20a of an annual mobile 20 arranged to perform 1/12 turn while the mobile date 10 depicts an angle corresponding to one turn. It will be possible to adapt the gear ratios of the first kinematic chain 14. In the example proposed, the first level 20a of the annual wheel 20 comprises 48 teeth, engaged with the second mobile 18 of the first kinematic chain 14. Preferably, the annual mobile 20 is located in the center of the mechanism, concentrically with the date mobile 10.

In addition to the first level mentioned above, the annual mobile 20 comprises a second level 20b, integral with the first 20a and having, at its periphery, five active parts 22 corresponding to the five months of less than 31 days. The second level 20b is more particularly visible in FIG. 2. Said active parts 22 comprise a number of teeth corresponding to the difference between 31 and the number of days of the month. Thus, the active parts 22 corresponding to the months of 30 days include a tooth and the active part corresponding to a month of February of 28 days includes 3 teeth. In a version of semi-perpetual calendar, the 3 teeth of the part corresponding to the month of February, are fixed. In a perpetual calendar version which will be described in more detail below, there are two fixed teeth and a retractable tooth. The parts 22 are positioned so as to be, at the end of the months of less than 31 days, in the race of a correction mobile 24. Note that, in an undescribed variant, the annual mobile may include only one level, the active parts being made by teeth longer than the others.

The corrector mobile 24 is intended to be driven by a second kinematic link, actuated by the movement, at a second power take-off. In the example proposed, the second kinematic link is formed by a correction wheel 26 intended to be driven at the rate of two revolutions per day in the direction of clockwise and comprising a second group of drive elements 26a. typically with 5 teeth. Advantageously, the correction wheel 26 is coaxial with the annual mobile 20. It will be noted that, in the present application, the notion of kinematic connection designates a direct connection between two elements, as in the second kinematic connection, or an indirect connection. , as in the first kinematic link.

The corrector mobile 24 comprises a first level 24a intended to be in kinematic connection with the correction wheel 26. According to the example, the correction mobile 24 is driven at a rate of one turn per day. This first level 24a comprises two additional groups of drive elements (28), typically each formed of 5 teeth, separated on either side by a stopping portion 30. Like a Maltese cross , the profile of the stop portions 30 is arranged to match the profile of the correction wheel 26. The correction mobile 24 also comprises a second level 24b comprising at least one group of drive members 32 arranged to cooperate with said parts. active 22 of the annual mobile 20, once a day at the end of the months of less than 31 days. In the example, the drive unit group 32 comprises three teeth.

Thus, during a month, the rotation of one turn per day of the mobile corrector 24 does not affect the annual mobile 20, which has no active portion 22 in the race of the group drive members 32 of the second level 24b of the corrector 24. The corrector 24 will cause the annual mobile 20 at the end of the month less than 31 days, when an active part 22 will come into the race of the group of 3 teeth 32 of the second level 24b of the corrective mobile 24. The conduct of this training will be a function of the number of teeth of the part 22 concerned, allowing the mobile of date 10 to move forward so as to "catch up" with its delay and display the first day of the next month.

Then, the movement of the annual mobile 20 under the action of the corrective mobile 24 is transmitted to the mobile date 10, via the first kinematic link 14, the mobile date date of date 10 being then conducted.

In a preferred version illustrated in the figures, the mechanism according to the invention is adapted to provide a perpetual calendar mechanism. For this purpose and as shown particularly in FIG. 2, one of the teeth of the active portion 22 of the annual mobile 20, corresponding to the month of February, has a drive element, for example a retractable tooth 40, arranged to be retracted the leap years. This retractable tooth is one of the lateral teeth of the group of three corresponding to the month of February. Preferably, as the annual mobile 20 is driven clockwise, it is the upstream tooth, that is to say that which is intended to mesh first with the corrective mobile 24, which is retractable.

The retractable driving element 40 is formed by means of a movable finger 42, for example pivotally mounted on the annual mobile 20 and whose end defines the retractable tooth. The movable finger 42 is likely to evolve between a "retracted" position and an "exit" position, in which its end is respectively set back or protruding with respect to the pitch circle of the second level 20b of the annual mobile 20. The two positions are shown in the figures.

The position of the movable finger 42 is defined by a satellite cam 44 pivotally mounted on the annual mobile 20 and arranged to cooperate with a group of fixed drive elements of a fixed wheel 46. The satellite cam 44 is Maltese cross type and comprises 8 parts, 444a of which define stop portions whose profile is arranged to match the profile of the fixed wheel 46. The other 4 teeth 44b, called positioning teeth, are arranged to position the element. retractable drive 40.

The fixed wheel 46 comprises, to achieve the group of drive elements, 3 teeth and cooperates, each turn of the annual mobile 20, that is to say once a year, with the satellite cam 44 At each revolution of the annual mobile 20, the satellite cam 44 rotates a quarter of a turn so that the movable finger 42 is pressed on one of the 4 teeth 44b positioning. For this purpose, an elastic member may be provided to exert a force tending to press the movable finger 42 against the satellite cam 44. Three of the 4 teeth 44b of positioning are of the same length and define the "output" position of the finger, for non-leap years. The other positioning tooth is truncated and defines the "retracted" position of the movable finger 42, for leap years. It can be provided that the truncated tooth has a concave end defining a bearing surface. If necessary, the teeth 44a forming the stop portions may also participate in the positioning of the movable finger 42.

It will be noted that the retractable tooth 40 could also be made by means of known systems of the Maltese cross type and applied in other perpetual calendar mechanisms.

Such a retractable drive element system can be perfectly adapted to an embodiment in which the annual mobile has only one level, as mentioned above.

Thus is obtained a semi-perpetual or perpetual calendar mechanism particularly simple, effective and reliable, using two PTOs since the movement. If necessary, it will be easily possible to provide a correction system acting directly on the drive plate of the mobile date 10. The stop portions make it possible to ensure that the various elements remain indexed with respect to each other. They could be replaced by positioning using jumpers.

Claims (13)

1. Date mechanism comprising: - a date mobile (10), intended to be driven at a rate of 1/31 turn per day by a first power take-off, said date mobile (10) being provided with a first group of driving elements ( 12) - an annual mobile (20) arranged to be driven at a rate of one revolution per year by the date mobile, via a first kinematic link connected to the first group of drive elements, said annual mobile (20) being provided with five active parts (22) corresponding to five months of less than 31 days, A corrective mobile (24) intended to be driven by a second power take-off to which it is connected by a second kinematic link, said active parts (22) of the annual mobile being positioned so as to be at the end of the months less than 31 days, in the race of the mobile corrector (24), said date mechanism being arranged in such a way that the movement of the annual mobile (20) under the action of the corrector (24) at the end of the months of less than 31 days is transmitted to the first group of training elements the date mobile (10) via the first kinematic link. 2. Date mechanism according to claim 1, characterized in that the annual mobile (20) describes an angle corresponding to 1/12 turn while the date mobile (10) describes an angle corresponding to 1 turn. 3. date mechanism according to one of the preceding claims, characterized in that the second kinematic link comprises a correction wheel (26) to be driven at a rate of two revolutions per day and comprising a second group of elements of drive (26a). 4. date mechanism according to one of the preceding claims, characterized in that the corrector mobile (24) comprises a first level (24a) intended to be kinematically connected to the correction wheel (26) and in that said mobile corrector (24) is able to train, once a day, the annual mobile (20) at the end of the months of less than 31 days. 5. Date mechanism according to claim 4, characterized in that the first level of said corrector (24) comprises two additional groups of drive elements (28) separated on each side by a stop portion ( 30) whose profile is arranged to match the profile of the correction wheel (26). 6. Date mechanism according to one of the preceding claims 4 and 5, characterized in that the corrective mobile (24) comprises a group of drive members (32) arranged to cooperate with said portions (22). 7. Date mechanism according to claim 6 and according to one of claims 4 and 5, characterized in that the group of drive members is disposed on a second level of the correction mobile. 8. date mechanism according to one of the preceding claims, characterized in that the drive elements (12) of said first group are grouped on said date mobile (10), on a sector corresponding to 4x (1/31) tower. 9. Date mechanism according to one of the preceding claims, characterized in that the date mobile (10) carries indications for displaying the date. 10. Date mechanism according to one of the preceding claims, characterized in that the correction wheel (26) is coaxial with the annual mobile (20). 11. Date mechanism according to one of the preceding claims, characterized in that the annual mobile (20) comprises, at the portion corresponding to the month of February, a retractable drive member (40) arranged to be retracted the leap years. 12. Date mechanism according to claim 11, characterized in that the retractable drive element (40) is produced by means of a movable finger (42) whose position is defined by a mounted satellite cam (44). pivoting on the annual mobile (20) and arranged to cooperate with a group of fixed drive elements of a fixed wheel (46). 13. Date mechanism according to claim 12, characterized in that the satellite cam (44) comprises 8 parts, 4 (44a) of which define stop portions whose profiles are arranged to match the profile of the fixed wheel (46). and 4 (44b) provide positioning of the retractable drive member (40).