CH715119A1 - Perpetual calendar mechanism for a timepiece. - Google Patents

Abstract

The invention relates to a perpetual calendar mechanism (1) for a timepiece comprising: a calendar mobile (3) arranged to be driven step by step at the rate of one step per day by means of an actuator (9a) corresponding; characterized in that said mechanism (1) further comprises: a synchronization wheel (13) in kinematic connection with said date mobile (3); a first subsystem (15), a second subsystem (17) and a third subsystem (19) arranged laterally with respect to each other and substantially in the same plane, each subsystem (15, 17, 19) comprising a correction wheel (15a) in kinematic connection with said synchronization wheel (13) and each carrying a respective retractable tooth, as well as a respective control cam arranged to bring said respective retractable tooth into an active position in which it is capable of being driven by a respective actuator (23a, 23b, 23c) at the end of a month, in which: the control cam of the first subsystem (15) is arranged to bring said respective retractable tooth into his active position at the end of each month having less than 31 days; the control cam of the second subsystem (17) is arranged to bring said respective retractable tooth into its active position at the end of each month of February; and the control cam of the third subsystem (19) is arranged to bring said respective retractable tooth into its active position at the end of each month of February having only 28 days.

Description

Description

Technical Field [0001] The present invention relates to the field of watchmaking. More particularly, it relates to a perpetual calendar mechanism for a timepiece.

State of the art Document EP 2 490 084 describes a perpetual calendar mechanism which ensures the advance of a calendar mobile by the appropriate number of steps at the end of each month, including that of February depending on the cycle four-year simplified leap. The user must therefore not correct the display of the date up to the year 2100 AD, which is non-leap even if it is divisible by 4. This mechanism includes a programming unit which has a large number of levels, some of which have one or two retractable teeth. These teeth are carried by levers and are brought into their active position by corresponding control cams, so that they can cooperate with a daily indexing wheel comprising several levels of drive fingers. When the daily indexing wheel rotates, it drives the programming unit at least one step per day. At the end of a month with less than 31 days, one or more of the retractable teeth are in the active position and in the path of the corresponding training finger, and are also driven by the daily indexing wheel. The programming unit is thus trained at the rate of one, two or three additional steps depending on the month and, in the case of February, whether the year is a leap year or not.

However, said programming mobile has a high complexity in view of the fact that it comprises a stack of several levels of teeth and control cams, which is difficult to develop and assemble. Furthermore, this arrangement has a relatively large height, which represents a bulk in the thickness of the movement.

The object of the invention is therefore to provide a perpetual calendar mechanism for a timepiece, in which the above-mentioned defects are at least partially overcome.

Disclosure of the invention [0005] More specifically, the invention relates to a date mechanism for a timepiece as defined by claim 1. This mechanism comprises:

- a date mobile arranged to be driven step by step at the rate of one step per day by means of a corresponding actuator (such as a finger), under the effect of any clockwork movement (mechanical, electric,...);

- a synchronization wheel in kinematic connection with said date mobile;

- a first subsystem which concerns the additional jump made at the end of each month having less than 31 days (corresponding to the passage of the date mobile from 30 to 31). This subsystem comprises a correction wheel in kinematic connection with said synchronization wheel, said correction wheel carrying a retractable tooth arranged to be driven by means of an actuator corresponding to the end of each month having less than 31 days thus a corresponding control cam arranged to bring said retractable tooth into its active position at the end of each month concerned;

- a second subsystem which concerns the still additional jump made at the end of each month in February (corresponding to the passage of the date mobile from 29 to 30). This second subsystem further comprises a correction wheel in kinematic connection with said synchronization wheel and which also carries a retractable tooth arranged to be driven through yet another actuator corresponding to the end of each month of February as well as a corresponding control cam arranged to bring said retractable tooth into an active position at the end of each month of February; and

- a third subsystem which concerns the further jump at the end of February in non-leap years (corresponding to the changeover from the date mobile from 28 to 29). This third subsystem further comprises a correction wheel in kinematic connection with said synchronization wheel and which also carries a retractable tooth arranged to be driven through yet another actuator corresponding to the end of each month of February having 28 days as well as a control cam arranged to bring said retractable tooth into an active position at the end of each month of February in non-leap years.

These three subsystems are arranged laterally each with respect to the others in the plane of the mechanism, that is to say in juxtaposition.

By these means, the thickness of the mechanism is significantly reduced compared to that of the prior art mentioned above since no complex stacking of cams and wheels is no longer necessary, and that the subsystems are easier to adjust individually compared to the programming mobile of the aforementioned prior art. In addition, the use of the synchronization wheel not only ensures synchronization of the date mobile with the three subsystems, but also gives the manufacturer great freedom to arrange the three subsystems and the mobile of date in the mechanism as required.

Advantageously, said synchronization wheel is a ring gear, with internal or external toothing. The synchronization wheel can thus have a large diameter while leaving the possibility of pivoting of other mobiles on axes crossing its interior space.

Advantageously, said date mobile, and / or one or more of said wheels of the subsystems, meshes directly with said synchronization wheel. This construction represents a very compact arrangement comprising a minimum of components.

Advantageously, said control cam of each subsystem is coaxial with said corresponding wheel. Advantageously, each retractable tooth is carried by a corresponding lever pivotally mounted on said corresponding wheel and cooperating with said corresponding control cam in order to determine the radial position of the retractable tooth in question.

Advantageously, each control cam is arranged to be driven by a kinematic link driven directly or indirectly on said synchronization wheel.

Advantageously, said actuators are arranged to be driven by a timepiece movement by means of a respective kinematic link which does not involve said synchronization wheel.

In addition, another advantage of the mechanism according to the invention is to allow corrections to be made in both directions, that is to say forward and backward, while keeping the synchronization of the different displays when the user makes a manual correction by means of an operating device such as a time-setting rod.

The mechanism according to the invention can be incorporated into a watch movement, which also comprises at least one display member arranged to be driven by said mechanism, for example in order to provide an indication of the date, month or the like.

Brief description of the drawings [0016] Other details of the invention will appear more clearly on reading the description which follows, made with reference to the accompanying drawings in which:

Fig. 1 is an isometric view of a perpetual calendar mechanism according to the invention; Fig. 2 is a top view, dial side, of the mechanism of FIG. 1; Fig. 3a and 3b are isometric views of the first subsystem, involved at the end of months with less than 31 days, as well as part of a second kinematic link; Fig. 4a and 4b are isometric views of the second subsystem, involved at the end of each February, as well as part of said second kinematic link; Fig. 5a, 5b and 5c are isometric views of the third subsystem, involved at the end of each February having only 28 days, as well as of the last mobile of a third kinematic link.

Embodiment of the invention [0017] Figs. 1 and 2 represent views of the entire perpetual calendar mechanism 1 according to the invention, respectively in isometric view and in top view (that is to say seen from the dial side).

The mechanism 1 comprises a date mobile 3, with 31 teeth, integral in rotation with a star 3a, also with 31 teeth, and is driven at the rate of one step per day from a power take-off on the basic movement (not shown) via a first ad hoc kinematic link 5. In the illustrated embodiment, this PTO is located at the 7-hour mobile, which is driven by a motor source such as a barrel, an electric motor or the like, at the rate of two complete turns per day under the control of a regulating system such as a balance spring, a tuning fork, a quartz oscillator or the like in a known manner.

The first kinematic link 5 comprises a series of mobiles arranged in an ad hoc manner ending with a drive mobile 9 arranged to perform one revolution per 24 hours, the reports garnered as well as the teeth which the first connection comprises kinematics 5 being adapted for this purpose. The driving mobile 9 not only includes a pinion in indirect kinematic connection with the hour mobile 7, but also a finger 9a. The latter is arranged to drive said 31-tooth star 3a which comprises the date mobile 3, at a rate of one step per day, typically around midnight, and therefore acts as an actuator. In order to ensure the correct angular positioning of the date mobile 3, a jumper 11 cooperates with the teeth of the star 3a in a known manner.

Alternatively, the PTO can be on any other mobile of the movement, the details of the first kinematic link 5 being adapted accordingly so that the finger 9a (or an actuator taking another form) drives the mobile of calendar at the rate of one step per day.

The date wheel 3 is engaged with a synchronization wheel 13 which connects the date wheel 3 to three subsystems 15, 17 and 19 which are arranged laterally with respect to each other in the plane of the mechanism 1 , and which ensure that the date mobile 3 takes a suitable number of additional steps, at the end of the months having less than 31 days, as will follow more clearly later. The synchronization wheel 13 can be a ring gear (as illustrated here), or can be a solid wheel, and acts as a reference between the date wheel 3 and correction wheels 15a, 17a, 19a that comprise the subsystems 15 , 17, 19, and which will be described below. Thus, when the date mobile 3 or one of the correction wheels 15a, 17a, 19a (see below) pivots, the others are also driven by the synchronization wheel 13.

Each of these subsystems 15, 17, 19 is associated with a respective drive finger 23a, 23b, 23c, which is in kinematic connection with the hour wheel 7 by means of a second kinematic connection 21 also arranged ad hoc. This second kinematic link distributes the force received from the hour wheel 7 to each of the drive fingers 23a, 23b, 23c so that they perform one revolution per day and act as an actuator for the subsystem 15, 17, 19 correspondent. These fingers 23a, 23b, 23c each cooperate with a respective retractable tooth that comprises each subsystem 15, 17, 19, as will clearly follow later.

To begin, we will explain the operation of the first subsystem 15, which is arranged to ensure the additional step that the date mobile takes at the end of each month having less than 31 days, that is to say the months of February, April, June, September and November.

This first subsystem 15 is illustrated in more detail in FIGS. 3a and 3b, and comprises a correction wheel 15a comprising 31 teeth which is engaged with the synchronization wheel 13 and therefore performs one revolution per month. The correction wheel 15a carries a retractable tooth 15b secured to a lever 15e. The latter is pivotally mounted on a stud projecting from the board of said correction wheel 15a. The retractable tooth 15b is held in the inactive position, that is to say retracted, by an elastic element 15c which cooperates with the lever 15e. The elastic element as illustrated is a leaf spring, but another form of elastic element (spiral spring, elastomer block, leaf spring made of material with the lever 15e, ...) is also possible. A mounting plate 15d, optional, is interposed between, on the one hand, the lever 15e and the elastic element 15c and, on the other hand, with the correction wheel 15a in order to position the retractable tooth 15b to cooperate with the corresponding drive finger 23a when the latter is in its active position and is in the path of said drive finger 23a.

The position of the lever 15e and therefore the active or inactive position of the retractable tooth 15b are defined by a control (or programming) cam 15f. The lever 15e is kept in contact with the periphery of the control cam 15f. The latter is integral in rotation with a control wheel 15g, and is mounted coaxially and free in rotation relative to said correction wheel 15a.

The periphery of the cam 15f has five bearings 15h of a first radius, higher, which correspond to the months having less than 31 days, and whose radius is defined to bring the retractable tooth 15b in its active position. The rest of the periphery of the cam 15f has a second, lower radius, defined so that the retractable tooth 15b is retracted out of the path of the drive finger 23a under the effect of the elastic element 15c when this part of the cam 15f cooperates with the lever 15e.

The control wheel 15g is rotated at the rate of one revolution per year from the synchronization wheel 13 via a third kinematic link 25 ad hoc. The gear ratio and the teeth of this kinematic link 25 are arranged to ensure the desired speed of rotation of the control wheel 15g, as well as to ensure good synchronization of the control cam 15f. Thus, at the end of each month having less than 31 days, the bearings of upper radius 15h corresponding to the month in question, cooperate with the lever 15e so that the retractable tooth 15b is brought into its active position and can cooperate with the corresponding training finger 23a. Since the correction wheel 15a rotates at an angular speed which is different from that of the control wheel 15g, the retractable tooth 15b will of course be moved radially several times during each month, but if the tooth 15b is not located in the path of finger 23a, there will be no additional training. It can thus be considered that the "active position" of the retractable tooth 15b corresponds exclusively to the state in which the tooth is capable of cooperating with the finger 23a (that is to say that the tooth 15b is deployed and is located in the path of finger 23b).

At the end of each day, when the date mobile 3 drives the synchronization wheel 13, the latter in turn drives the correction wheel 15a as well as the third kinematic link 25, which, if necessary, leads to rotation of the control cam 15f. We also note that in the illustrated embodiment, the control cam 15f is not angularly moved at the end of each day since the third kinematic link includes a single-toothed wheel 25a which rarely causes the next wheel 25b of said kinematic linkage 25. However, a large number of other variants of the third kinematic linkage are entirely possible, including variants in which the cam 15f is driven every day.

If the retractable tooth 15b is in its active position under the control of the cam 15f and is in the path of the drive finger 23a, the correction wheel 15a will be driven at an additional step by said finger 23a. According to the kinematics illustrated, the training of the date mobile 3 by the finger 9a is carried out at midnight, and that of the first subsystem by the finger 23a a little before, at 11:15 pm, in order to separate these two drives over time. so that the training of the date mobile 3 is done correctly at midnight, the fact of separating the jumps allows us not to take too much torque in one jump. However, the exact moments of the two drives can be determined by the manufacturer by working on the angular positions of the actuators 9a and 23a.

By these means, at the end of each month having less than 31 days and particularly the months of 30 days, the date mobile 3 is advanced at a rate of two steps, the first of which is carried out by the synchronization wheel 13 following the drive of the retractable tooth 15b by the corresponding drive finger 23a (which advances the indication of the date from 30 to "31"), the other directly via the drive finger 9a , which advances the date indication from 31 to "1".

On the other hand, during the transition from an indication of "30" to "31" at the end of the months having 31 days, the retractable tooth 15b is retracted and therefore does not cooperate with the actuator 23a.

The second subsystem 17 and the third subsystem 19 which will be described below, intervene for the additional jumps to be made at the end of February. For the 28-day months, 3 additional jumps must be made (28 to 29, 29 to 30 and 30 to 31), in addition to the jump made by the training finger 9a. For the months of 29 days, we must therefore only make two additional jumps (29 to 30 and 30 to 31). The additional jump to switch the indicator from 30 to 31 is provided by the first subsystem, as described above. The second subsystem 17 is more particularly arranged to ensure the jump from the date indication from "29" to "30", and it therefore operates every February. The third subsystem 19 is more particularly arranged to ensure the additional jump of the date indication from "28" to "29" at the end of the 28-day months. In the case of a leap year, the third subsystem 19 does not intervene, the step from "28" to "29" having been carried out regularly by means of the drive finger 9a cooperating with the mobile 3. In the case of a non-leap year, the third subsystem 19 intervenes before the second subsystem 17, as will be described below in the context of the discussion relating to the latter.

The second subsystem 17 is illustrated in more detail in FIGS. 4a and 4b, and operates on the same general principle as the first subsystem 15. The components of the second subsystem 17, the reference signs of which have the suffixes "a", "b", "c" etc., correspond to the equivalent components of the first subsystem 15 bearing the same suffix, and therefore do not have to be completely re-described. Therefore, only the differences between the two subsystems 15 and 17 will be discussed below.

Since the retractable finger 17b of this subsystem is brought into its active position only once a year, in particular at the end of February, the control cam 17f has only one first radius bearing, superior, 5 p.m. which takes place once a year. This control cam 17f therefore pivots at the same angular speed as the control cam 15f of the first subsystem 15, and consequently the control wheel 17g of the second subsystem 17 meshes directly with the control wheel 15g of the first subsystem -system 15. However, a direct meshing is not compulsory, one or more cross-references can be inserted. Alternatively, the control wheel 17g of the second subsystem 17 can be driven from the synchronization wheel 13 by means of a dedicated additional kinematic link.

By these means, at the end of each month in February, the upper radius bearing 17h moves the lever 17e so that the retractable tooth 17b adopts its active position in the trajectory of the corresponding drive finger 23b. Again, the corresponding drive finger 23b drives the retractable tooth 17b, if it is present and in its active position, which drives the synchronization wheel 13, as well as the date wheel 3, by an additional step. This training of the second subsystem 17 must be carried out before the retractable tooth 15b of the first subsystem 15 is trained, in order to change the indication from "29" to "30". In the illustrated embodiment, this training is carried out, if necessary, around 10:00 pm, therefore before that of the first subsystem 15. Consequently, at the end of each month in February, the date mobile 3 is driven at the rate of a first step by the synchronization wheel 13 under the effect of the second subsystem 17, then of an additional step by the synchronization wheel 13 under the effect of the first subsystem 15, and finally another step by the training finger 9a. These three workouts are carried out in a sequence determined by the relationship between the training fingers 9a, 23a, 23b.

The third subsystem 19 is illustrated in FIGS. 5a, 5b and 5c. Again, the components of the third subsystem 19, whose reference signs have the suffixes “a”, “b”, “c” etc., correspond to the equivalent components of the first subsystem 15 having the same suffix, and must not therefore not be completely re-described. Only the differences will be discussed below.

This subsystem 19 relates to the additional jump at the end of February in non-leap years, February comprising only 28 days according to the simplified cycle of 4 years. To this end, the control cam 19f has three first radius bearings, upper, 19h, which correspond to the months of February at 28 days of the 4-year cycle, the angular difference between a 19h bearing and the following 19h bearing being 90 °, 90 ° and 180 ° respectively. The "missing" stage corresponds to the month of February of 29 days of the leap year, which therefore requires no additional step on the part of the third subsystem 19.

The control cam 19f as well as the control wheel 19g which is integral with it in rotation, are arranged to make a revolution in four years, so that the bearings of upper radius 19h control the lever 19th to bring the tooth retractable 19b in its active position at the end of each month of February having 28 days according to the simplified cycle of four years. We see in these figures that the control cam 19f is made integral in rotation with the control wheel 19g by means of lugs 19i projecting from the upper surface of the cam 19f, which cooperate with complementary notches ( not shown) provided on the underside of the control wheel 19g. This same principle can also apply to the cams 15f, 17f of the other subsystems 15, 17. Alternatively, the positions of the lugs and notches can be reversed, or the cams 15f, 17f, 19f can be screwed, pinned, welded or glued on their respective control wheel 15g, 17g, 19g, or can be of material with these.

In order to drive the control wheel 19g in rotation, the latter is driven from the correction wheel 19a of this subsystem, via a third kinematic link 27. This third kinematic link 27 has a single-toothed wheel 27a which is integral in rotation with the correction wheel 19a and which drives a wheel 27b which is coaxial, and integral in rotation with a single-toothed wheel 27c (see fig. 5c), which drives in turn the control wheel 19g, the shapes of the teeth as well as the gear ratios ensuring that the latter performs one revolution in 4 years and has one of its bearings with a greater radius 19h to the lever 19th at the right time. Of course, other embodiments of this third kinematic link are possible, which take force on any suitable mobile.

By these means, the evening of February 28 of a non-leap year, the retractable finger 19b of the third subsystem 19 is driven by the corresponding drive finger 23c, around 8:30 p.m. (but another time before the second subsystem 17 intervenes is of course possible). The correction wheel 19a is thus driven at a rate of one step, which in turn drives the synchronization wheel 13. The correction wheels 17a, 15a of the other subsystems as well as the date wheel, are thus driven to one step, advancing the date indication from "28" to "29". Subsequently, the retractable tooth 17b of the second subsystem 17 is driven as described above, which in turn advances the synchronization wheel 13 and the date mobile 3 by an additional step, advancing the indication of date from "29" to "30". Still subsequently, the first subsystem 15 intervenes to advance these same elements by one more step, thus advancing the date indication from “30” to “31”, and finally the training finger 9a drives the date mobile by one not final, to advance the indication from “31” to “1”.

Note that in the example proposed, this mechanism cannot delete the leap year for years divisible by 100 which are not divisible by 400, so a user must correct the indication himself at the end February for the year 2100, 2200 etc.

Regarding the displays derived from the mechanism 1 according to the invention, one can simply provide a date indication member 29, integral in rotation with the date mobile 3. This member 29 may be a needle, a disc , a ring or the like. Alternatively, such a member 29 can be driven directly or indirectly by the date mobile 3 or by the synchronization wheel 13. The mechanism 1 thus forms part of a display mechanism. It is also possible to provide means for displaying the month 31, means for displaying 33 the position of the year in the 4-year cycle which determines leap years on mobiles forming part of a additional train 35 driven by the third kinematic link or by another mobile such as the date mobile 3 or the synchronization wheel 13. It is also possible to derive a display of the day of the week from the hours mobile 7 by providing a kinematic link adapted to this purpose. A person skilled in the art can determine, by applying his general knowledge, ad hoc gear arrangements which serve to fulfill these aims.

During a manual correction of said date mobile 3 by means of an operating member such as a winding and / or time-setting rod (not illustrated), the mechanism described above keeps the synchronization of the various display elements 31, 33, 35, regardless of the direction of said correction.

Furthermore, it is noted that a large number of additional variations are possible based on the mechanism 1 described above.

For example, the use of the synchronization wheel 13 gives the manufacturer the freedom to place the subsystems according to his needs in the plane of the mechanism, in ad hoc locations. The synchronization wheel 13 can be an internal gear crown, and can be arranged at the periphery of the mechanism 1 and possibly at the periphery of the basic movement (not illustrated).

Each direct gear can be replaced by an indirect gear having one or more references, and the number of teeth of the various toothed members can vary according to the needs of the manufacturer. Finally, still other variants are possible without departing from the scope of the invention as defined in the claims.

Claims (11)

claims 1. Date mechanism (1) for a timepiece comprising: - a date mobile (3) arranged to be driven in steps at the rate of one step per day by means of a corresponding actuator (9a); characterized in that said mechanism (1) further comprises: - a synchronization wheel (13) in kinematic connection with said date mobile (3); - a first subsystem (15), a second subsystem (17) and a third subsystem (19) arranged laterally with respect to each other and substantially in the same plane, each subsystem (15, 17 , 19) comprising a correction wheel (15a, 17a, 19a) in kinematic connection with said synchronization wheel (13) and each carrying a respective retractable tooth (15b, 17b, 19b), as well as a respective control cam ( 15f, 17f, 19f) arranged to bring said respective retractable tooth (15b, 17b, 19b) into an active position in which it is capable of being driven by a respective actuator (23a, 23b, 23c) at the end of a month, in which: - the control cam (15f) of the first subsystem (15) is arranged to bring said respective retractable tooth (15b) into its active position at the end of each month having less than 31 days; - The control cam (17f) of the second subsystem (17) is arranged to bring said respective retractable tooth (17b) into its active position at the end of each month in February; and - the control cam (19f) of the third subsystem (19) is arranged to bring said respective retractable tooth (19b) into its active position at the end of each month of February having only 28 days. 2. Mechanism (1) according to claim 1, wherein said synchronization wheel (13) is a ring gear. 3. Mechanism (1) according to one of the preceding claims, in which said date mobile (9) meshes directly with said synchronization wheel (13). 4. Mechanism (1) according to one of the preceding claims, in which said correction wheel (15a, 17a, 19a) of at least one of said subsystems (15, 17, 19) meshes directly with said wheel synchronization (13). 5. Mechanism (1) according to one of the preceding claims, in which said control cam (15f, 17f, 19f) of each subsystem (15, 17, 19) is coaxial with said correction wheel (15a, 17a , 19a) corresponding. 6. Mechanism (1) according to one of the preceding claims, wherein each retractable tooth (15b, 17b, 19b) is integral with a respective lever (15th, 17th, 19th) pivotally mounted on said correction wheel (15a , 17a, 19a) respective and cooperating with said corresponding control cam (15f, 17f, 19f). 7. Mechanism (1) according to one of the preceding claims, in which each control cam (15f, 17f, 19f) is arranged to be driven by a kinematic link (25,27) taking force on said synchronization wheel (13 ). 8. Mechanism (1) according to the preceding claim, wherein said actuators (9a, 23a, 23b, 23c) are arranged to be driven by a timepiece movement via a respective kinematic link (5, 21) n ' not including said synchronization wheel (13). 9. Watch movement comprising a mechanism (1) according to one of the preceding claims as well as at least one display member (29, 31,33) arranged to be driven by said mechanism (1). 10. Watch movement according to the preceding claim, wherein said mechanism is arranged such that a correction of the date mobile (3) by an operating member such as a winding stem can be done in both directions of rotation. , while keeping the synchronization of said at least one display member (29, 31, 33). 11. Timepiece comprising a timepiece movement according to one of claims 9 and 10.