CH696947A5 - Timepiece with a perpetual calendar display. - Google Patents

Abstract

The display (43) consists of an indicator (46) which sweeps over concentric disks. An outer disk (47) shows days of the week for four weeks and two disks (51,52) show the day of the month for first and second parts of the month. The month is displayed on an inner disk (56). The first and second day of the month disks are successively displaced by amounts to allow for the month length and then restore correct order

Description

       

  The present invention relates to a timepiece provided with a watch movement and a calendar display comprising: a dial with a fixed graduation in days of whole weeks that extends over the entire turn of the dial, date indicator means, driven in rotation in steps and having at least one date scale in correspondence with the graduation of the days, and a movable calendar index rotated by the watch movement opposite the graduations days and dates.

Patent application EP 285 881 describes a perpetual calendar electronic wristwatch of this kind, in which central hands hours, minutes and seconds are driven by a first motor to indicate the time,

   a fourth central hand is driven from this engine 1/35 turn per day to indicate the date, while another off-center hand is driven by a second motor to indicate the month. The date is indicated by the fourth hand on two concentric graduations, namely a fixed graduation of days which is divided into thirty-five equal sectors bearing the names of the days of five consecutive weeks, and a graduation of the dates carried by a rotating disk and divided equally into thirty-five equal sectors of which thirty-one consecutive fields bear the dates from 1 to 31, the other four sectors being virgin. At the end of each month, the date disc is moved by a third motor to place the next month's calendars in correspondence of the graduation of the days.

   Thus, the user can see at any time the complete calendar of the current month, while the fourth hand indicates the date and the day on the graduations matched. However, a disadvantage of this way of displaying the date is that, until the evening of the last day of the month, the user can not see the calendar of the beginning of the following month. On the other hand, in a watch having a mechanical clockwork movement, the design of a mechanism causing such a date display would be very difficult.

In French patent no. 793 442, it was proposed a mechanical calendar in which the seven dates of a whole week are visible in a window beside which are inscribed the names of the days of the week.

   The mechanism comprises two concentric date discs each having a semicircular sector which carries the dates of a first part or a second part of the month, the ends of these sectors overlapping over one, two or three days, alternatively to place the first month of the month following the last calendar of the previous month, then to restore the continuous continuation of the calendars around the middle of the month. The rotation of the two date discs is operated once a week by means of a manual control or a clockwork movement.

   The relative movements of one of these disks relative to the other are determined by a cam mechanism carried by one of the disks and representing the different lengths of the months.

This mechanical calendar has the disadvantage of not indicating the current date because it can not be combined with a rotary indicator such as a needle driven by a watch movement. The observer must therefore know a priori what is the day of the week to be able to read the date or vice versa. In addition, he can only read the calendar for one week at a time.

   Another disadvantage is that when the week extends to the end of a month and the beginning of the following month, the observer does not know whether the name of the month displayed in the window provided for this purpose corresponds to the beginning or the weekend.

A primary object of the present invention is to overcome the aforementioned drawbacks with a date display mode allowing a global view of the calendar not only on the current week, but also over one or more weeks to come, what the number of days in the current month.

   Preferably, the calendar will be of the perpetual type, that is to say taking into account leap years.

An additional object of the invention is to allow the indication of the date by means of a single mobile index indicating not only the day and the date, but also the month and possibly the year.

Another object of the invention is to design a calendar mechanism capable of causing such a calendar display from the watch movement.

For this purpose, there is provided a timepiece of the type indicated above in the preamble, characterized:

  
in that the date indicator means comprise two concentric date discs that can be angularly offset with respect to one another, namely a first disc whose graduation includes the dates of a first part of a month and a second disk whose graduation includes the other calendars up to 31, corresponding to a second part of a month,
in that the first date disc is moved N not in the second part of a month, N being equal to the number of days of the said month minus the number of days of the graduation of the days, so that the last day of said month on the graduation of the second disc is followed by the first calendar of the following month on the graduation of the first disc,

  
and in that the second date disk is moved by the same number N of steps in the first part of the following month, which restores the continuous sequence of dates on the set formed by the two date scales.

Thus, the calendar display at all times a correspondence between the days and days over a period of several weeks which includes the current week and one or more weeks that follow, which helps the user to choose dates in this period, for example to schedule appointments. In the first part of the month, this period spans the entire month in progress.

   In the second part of the month, which can start at any date chosen by the manufacturer, preferably between 15 and 20, the first date disk is moved while the second disk remains stationary, so that the date of the month 1 next month takes place just after the last day of the current month. Consequently, the correspondence between dates and days is established not only for the end of the current month, but also for the first part of the following month.

Of course, the calendar mobile index is driven so as to advance one day in 24 hours in front of the fixed graduation of the days.

   It indicates at the same time the day and the date on the respective graduations matched one of the other.

In a first particular embodiment, the graduation of the days comprises 28 days on the turn of the dial, so that N is always positive and that the movements of the date discs take place in the increasing direction of the graduations of the days. and dates. Thus, the calendar display always shows a correspondence between the calendars and the days over a period of four weeks.

   The mobile calendar index is driven in this case so as to take a turn in 28 days next to the fixed graduation of the days.

In a second particular embodiment, the graduation of the days comprises 35 days on the turn of the dial, so that N is always negative and that the movements of the date discs are carried out in the decreasing direction of the graduations of the days. and dates. Thus, the calendar display always shows a correspondence between the calendars and the days over a period of more than four weeks.

   The mobile calendar index is driven in this case so as to take a turn in 35 days next to the fixed graduation of the days.

In the two aforementioned embodiments of the invention, the calendar display can be completed advantageously by a disk of the months, divided into twelve sectors each bearing the name of a month and concentrically arranged to the date discs, next to the mobile calendar index, the month disk being driven so as to perform, relative to the moving index, a relative rotation of a lap in one year.

   This relative rotation is preferably in the opposite direction to that of the rotation of the index, so that the increasing order of months is arranged in the same direction as the increasing order of days and dates.

The calendar display of the perpetual type may further comprise a disk years, preferably divided into four sectors corresponding to the four years of a leap years cycle, this disk being driven in continuous relative rotation with respect to the calendar index to perform a four-year turn against this index.

Other features and advantages of the present invention will appear in the following description of various embodiments, presented as non-limiting examples with reference to the accompanying drawings, in which:

  
 <tb> fig. 1 <sep> represents a first embodiment of the display devices of a perpetual calendar watch according to the invention, comprising a conventional display of the time and a calendar display, as of January 31, 2001,


   <tb> fig. 2 <sep> represents the calendar view as of February 5, 2001,


   <tb> fig. 3 <sep> represents the calendar view as of February 19, 2001,


   <tb> fig. 4 <sep> represents the calendar display as of March 5, 2001,


   <tb> fig. 5 <sep> represents the calendar display as of April 19, 2001,


   <tb> fig. 6 <sep> represents the calendar view as of May 5, 2001,


   <tb> fig. 7 <sep> represents the calendar view as of February 19, 2004,


   <tb> fig. 8 <sep> represents the calendar view as of March 5, 2004,


   <tb> fig. 9 <sep> represents a second embodiment of the calendar display, on the same date as in FIG. 5


   <tb> fig. 10 <sep> represents the calendar display of fig. 9 at the same date as in fig. 6


   <tb> fig. 11 <sep> represents a third embodiment of the calendar display, on the same date as in FIG. 3


   <tb> fig. 12 <sep> schematically represents an embodiment of a perpetual calendar mechanism for controlling the calendar display according to FIG. 11


   <tb> fig. 13 <sep> is a sectional diagram of the mechanism of FIG. 12


   <tb> fig. 14 <sep> is an enlarged view of a program wheel of the mechanism of FIG. 12, in a position corresponding to the month of April of a normal year,


   <tb> fig. 15 <sep> is a sectional view along the line XV-XV of FIG. 14


   <tb> fig. 16 <sep> represents the program wheel of fig. 14 in a position corresponding to the end of February of a leap year,


   <tb> fig. 17 <sep> schematically represents an embodiment of a perpetual calendar mechanism for controlling the calendar display according to Figs. 1 to 8, e


   <tb> fig. 18 <sep> is a sectional diagram of the mechanism of FIG. 17.

With reference to FIG. 1, the display members of the watch comprise conventional analog time indication members, comprising an hour hand 41 and a minute hand 42 which turn in front of a dial 43 bearing, for example, twelve fixed time references 44. Needles 41 and 42 are conventionally driven by a clockwork movement to rotate around the central axis 45 of the watch. Of course, we could still add a second hand in the center.

A calendar index 46 is driven by the watch movement of the watch so as to perform a complete revolution around the axis 45 in 28 days, preferably clockwise, next to a graduation of 47 days which is fixed on the dial 43.

   The graduation 47, which extends all round the dial, is divided into twenty-eight equal sectors bearing the names of the days of four consecutive weeks. The index 46 is carried by an annular disc 48 which can be driven either continuously or by 1/28 turn to place the index 46 always in front of the middle of a sector of the fixed graduation 47. One could also provide a central hand to fulfill the function of the index 46, as will be seen later about the third embodiment.

The calendars 1 to 31 are distributed on respective sectors of two date discs 51 and 52, next to the graduation of days 47. Each sector bearing a date extends over 1/28 turn, so that it can be placed in exact correspondence of a sector of the graduation of days 47.

   The first date disk 51 carries a graduation 53 having the dates of a first part of the month, for example in this case the dates of 1 to 15 on fifteen consecutive sectors. The second date disc 52 carries a graduation 54 comprising the calendars of the second part of the month, that is to say in the present case from 16 to 31 out of sixteen consecutive sectors.

   The second disc 52 is located behind the first disc 51 and has a larger diameter, so that its graduation 54, disposed on a circular arc of greater radius than the graduation 53, is always visible along the periphery of the first disk 51 and that three sectors of the respective ends of the two graduations 53 and 54 can be juxtaposed, as seen in FIG. 1 for the dates 13 to 18.

It is obvious that the index 46 being in front of one of the sectors of the graduation 47, bearing the name of the present day, indicates at the same time the date being in correspondence of this sector.

   If the index was in a zone where the two graduations 53 and 54 overlap (a circumstance which does not occur in the examples described here), the observer should by convention read the nearest date of the index, c that is to say on the first graduation 53.

Inside the disk 48 bearing the index 46, the perpetual calendar display comprises an annular disc of the months 56, bearing a graduation of the months 57 composed of twelve sectors whose respective angles are proportional to the length of the month they represent. The disk 56 is driven by the clockwork movement so as to follow the disk 48 and its index finger 46, but with relative retrograde rotation to delay one revolution per year.

   Inside the disc 56 is an annular disc of the years 58 bearing a graduation 59 composed of four equal sectors, corresponding to the Julian cycle of four years, the last of which is leap and indicated by the Roman numeral IV. As a result, the 58-year-old disc is driven by the watch movement so as to follow the disc 48 carrying the index finger 46, but with relative retrograde rotation to delay by one revolution in four years relative to the disc 48.

   Thus, the index 46 analogically indicates the current month on the graduation 57 and the number of the year in the quadrennial cycle on the graduation 59, besides the day of the week and the date.

The relative rotations of the disks 56 and 58 relative to the disk 48 of the index are retrograde because their graduations are increasing in the clockwise direction, which is that of the rotation of the index. Otherwise, if these relative rotations were in the same direction as the rotation of the disc 48, said graduations should be increasing in the opposite direction to that of the rotation of the disc 48. This would result in other ratios between the rotational speeds of these discs. .

In FIG. 1, the date displayed is Wednesday, January 31, 2001, which is the first year of a quadrennial cycle.

   We can read the correspondence between the calendars and the days of the week throughout the period from January 16th to February 15th of this year, that is to say on the second part of January and the first part of February. The limits of this period are highlighted by the overlap of the two date scales between 13 and 18.

At a predetermined date during the first part of the following month, namely in February, the second date disc 52 is advanced in one go three steps of 1/28 turn (N = 3) in the increasing direction of its graduation 53, that is to say here in the clockwise direction, to the position shown in FIG. 2. Its date 16 is then at the end of the date 15 of the first disc 51.

   Thus, the display shows the correspondence between the days and the calendars over the whole month now in progress (February). The user notices this because the two date scales succeed one another in the middle of the month. In this example, said predetermined date is the 5th of each month, but the manufacturer may choose another date if he deems it appropriate.

It is also noted in FIG. 2 that the disk of the months 56 followed the rotation of the index 46, but with a small retrograde offset so that the index is now in front of the beginning of the sector "FEV" of the graduation of the months.

   In the same way, the record of the years 58 followed the rotation of the index 46, but with a small retrograde shift making that the index is now a little further in the sector "I" of the graduation of the years.

At a predetermined date during the second part of the current month (February), the first date disc 51 is advanced from zero steps, that is to say does not move, because for February of a normal year N = 28 days - 28 = 0. FIG. 3 represents for example the state of the calendar display on February 19, 2001.

   The date of 19 is chosen here for the displacement of the first disc because it is the first which avoids the presence of the index finger 46 in front of the overlap zone of the two date scales, for example in their position shown in FIG. . 1.

At a predetermined date during the first part of the following month, namely March 5, 2001, the second date disc 52 is advanced by the same number of steps N = 0 as in the previous operation, that is, that is, that it does not move and that the state of the display on that date is represented in FIG. 4.

On March 19, the first date disc 51 is advanced N = 31 - 28 = 3 steps to bring its date 1 after the 31st day of March. This state is not represented.

   The correspondence between days and dates is then established for the second part of March and the first part of April.

On April 5, the second date disk 52 is advanced by the same number of steps N = 3 as in the previous operation, in order to reset its date 16 after the date of the first disk 51 and thus display the correspondence between days and calendars throughout the month of April. This state is not represented.

On April 19, the first date disc 51 is advanced N = 30 - 28 = 2 steps to bring its date 1 after the April 30 date, in the position shown in FIG. 5.

   Correspondence between days and dates is then established for the second part of April and the first part of May.

On May 5, the second date disc 52 is advanced by the same number of steps N = 2 as in the previous operation, in order to reset its date 16 after the date of the first disc 51 and thus display the correspondence between days and calendars throughout the month of May. This state is represented in FIG. 6. The same pair of operations is performed in successive months, with the appropriate values of N.

Figs. 7 and 8 show the transition from February to March in a leap year. As of February 19, 2004 corresponding to FIG. 7, the first date disc 51 has been advanced by N = 29 - 28 = 1 step to bring its date 1 after the last 29th of February.

   Correspondence between days and dates is then established for the second part of February and the first part of March.

At the date of March 5, 2004 corresponding to FIG. 8, the second date disc 52 has been advanced by the same number of steps N = 1 as in the previous operation, in order to reset its date 16 following the date 15 of the first disc 51 and thus display the correspondence between days and dates throughout the month of March.

In a variant not shown, the portion of the first disk 51 which is not covered by the graduation 53 could be removed and the portion bearing this graduation could cover the edge of the second disk 52,

   so that the two graduations 53 and 54 could be arranged on arcs of equal radius and that the ends of the first graduation 53 could be superimposed on those of the second graduation 54 instead of being juxtaposed. This would have the advantage of reducing the radial clutter of the display, but would prevent reading the calendar over a period of more than 28 days.

Figs. 9 and 10 show a second embodiment which avoids this last disadvantage. Only here will be described what differs from the first embodiment. Of course, the watch also comprises the time display members 41 to 44 shown in FIG. 1, but these are omitted in FIGS. 9 and 10 to clarify the drawing. The fixed graduation 47 days is divided in this case into thirty-five equal sectors and thus covers five weeks.

   The calendar index 46 is driven in the increasing direction of the graduation 47, in this case clockwise, so as to take a turn in 35 days. On the first date disk 51, the edge zone carrying the graduation 53 covers the second date disk 52 and is indented on the rest of the circumference to show the graduation 54 of the second disc, except that it will hide the dates 29, 30 and / or 31 at the end of the months of less than thirty-one days thanks to the relative movements of the disks 51 and 52.

FIG. 9 represents the state of the calendar display on Thursday, April 19, 2001, therefore on the same date as in FIG. 5.

   Previously the position of the first disk 51 was such that its date 15 was next to the date 16, the two graduations 53 and 54 thus being connected to display the complete calendar of the month of February. To reach the position of fig. 9, the first disk 51 has retracted N = 5 steps relative to the fixed graduation 47 and the second disk 52, so in the counterclockwise direction, to place its date 1 now representing the 1 <er> May following the 30th date representing 30 April, the sector of the date of 1 covering that of 31. The display shows the correspondence between days and calendars for the second part of April and the first part of May.

   In this embodiment, the absolute value of the number N is equal to minus the number of days in the current month.

In the first part of the following month, here May 5, 2001, the calendar display is put in the position shown in FIG. 10 by a decline of the same number of five steps of the second disc 52 to bring the date 16 after the 15 and then show the correspondence between days and calendars throughout the month of May.

   We also see in this figure that in the second part of May, the first disc 51 will have to go back four steps to place its date 1 after 31, the 1st <er> June 2001 being a Friday.

Note also that the fixed graduation of the days 47 could be arranged outside with respect to the date scale 53 and 54, without the readability of the display is affected.

While the two embodiments described above are based on a graduation of days covering respectively four weeks and five weeks on the circumference of the dial, we can predict a number of different weeks and generalize the concept of the display. by the two date disks 51 and 52 alternately displaced by N steps, defining an algebraic value (positive or negative) of N by the following formula:

  
N = M - 7 S
where S is the number of weeks of the graduation of the days and M is the number of days of the month concerned. A positive value of N characterizes a rotation of the disc in the increasing direction of the graduations of the days and the calendars. For example, in the second embodiment described above, S is 5 and the formula becomes N = M-35, so that N is always negative and therefore the disks must move backward relative to the graduation of the days.

However, it should be noted that a value of S less than 4 makes it difficult to read the calendars, because of the magnitude of the overlaps of their two graduations, and that a value of S greater than 5 requires very strong inscriptions. small and has no advantage.

   This is why embodiments where S is 4 or 5 are preferable.

Figs. 11 to 13 illustrate a third embodiment, which is close to the first and which will be described essentially differences with respect to the latter.

A first difference is that the index 46 and the disc 48 carrying it in the first embodiment are replaced by a central hand which constitutes the calendar index 46. It also makes a turn in 28 days in the increasing sense of the graduation of days 47.

   In order to be clearly distinguishable from the hands of the hours 41 and minutes 42, the hand of the calendar index 46 may for example have a particular color.

A second difference is that the fixed graduation of the days 47 is disposed around the annular date discs 51 and 52, that is to say directly on the dial of the watch. This avoids interposing a fixed element between the different disks of the calendar mechanism.

Finally, a third difference lies in the display of years. In this embodiment, the annular disk of the years 58 performs a revolution in ten years with respect to the index 46, its graduation 59 bearing the numbers from 0 to 9.

   In addition, a central disc of the '60s is concentrically placed at the center of the calendar display and carries a decades' index of 61 next to the graduation of the' 59s. The decades disc is driven so as to perform a hundredth turn. years in comparison with the record of the years 58. Consequently, its index 61 indicates on the graduation 59 the figure of tens of the current year. This can be recalled to the user by means of an inscription such as "x 10" on the index of decades 61.

The calendar display members of the examples described above may be actuated by any appropriate means, at times determined by the mechanical, electromechanical or electronic movement of any timepiece, whether it is act of a watch or a clock.

   They can in particular be operated by one or more electric motors dedicated to them.

Figs. 12 and 13 show a calendar mechanism capable of actuating the display shown in FIG. 11 from the watch movement of the analog watch, more precisely from a central wheel hours 99 which is integral with the hour hand 42 and which obviously takes a turn in twelve hours. In fig. 13, the figures written in italics represent the numbers of teeth of the mobiles which will be described below.

The hour wheel 99 meshes with a wheel 101 having a pinion 102 which meshes with a wheel 103 having a pinion 104, which meshes with a wheel 105 integral with two other wheels 106 and 107.

   The wheel 105 meshes with a wheel 108 attached to a barrel 109 which surrounds the axes of the needles 41, 42 and which carries the calendar index needle 46. With the numbers of teeth indicated in FIG. 13, it is verified that the transmission ratio between the hour wheel 99 and the index 46 is:
  <EMI ID = 2.0>

As the hour wheel 99 makes two laps per day, the index finger 46 turns clockwise in exactly 28 days.

The wheel 107 meshes with a central wheel 110 integral disk 58 years.

   In order to follow the index 46 by delaying with respect thereto by one turn in ten average years of the Julian cycle, the disk 58 is driven by the wheel 99 with the following transmission ratio:
  <EMI ID = 3.0>

As a result, the disk 58 years rotates clockwise a little more slowly than the index 46, relative to which it undergoes the following shift (expressed in number of revolutions) during an average year of the Julian cycle:
  <EMI ID = 4.0>

The wheel 106 meshes with a wheel 111 secured to the disc of the decades 60. It is driven by the wheel hours 99 with the following report:
  <EMI ID = 5.0>

Thus, we note that the record of the decades turns clockwise slower than the index 46, but slightly faster than the record of the 58 years.

   In an average year, it undergoes the following shift with respect to the disk 58:
  <EMI ID = 6.0>

In this way, the index of decades 61 takes a hundred years to go through the entire graduation of the 59 and indicates the decade on this graduation.

On the barrel 109 is fixed a driving wheel 112 which meshes with a wheel 113 secured to a wheel 114, which meshes with a central wheel 115 secured to the disc of the month 56. This disc is driven by the barrel 109 of index 46 clockwise such that its offset from index 46 in an average year is:
  <EMI ID = 7.0>

On the other hand, the driving wheel 112 drives the date discs 51 and 52 by means of a perpetual calendar mechanism 120 shown in the right part of Figs. 12 and 13.

   The wheel 112 meshes with a wheel 121 integral with a wheel 122 which meshes with a wheel 123, itself secured to a wheel 124 to a tooth 125. The wheels 123 and 124 are driven by the barrel 109 at 12 rotations clockwise per average year, which is apparent from the following formula in which R 1 is given by formula (1):
  <EMI ID = 8.0>

Two program wheels 126 and 127 are arranged on either side of the wheel 124, so that the single tooth 125 of the latter alternately drives the two program wheels in the counterclockwise direction, each one once. per month with a half-month lag between one and the other. Note that this offset can be changed by slightly moving the wheel to a tooth relative to the program wheel pair.

   Each program wheel 126 and 127, the structure of which will be described later, takes one complete turn per calendar year, regardless of the number of days this year.

The first program wheel 126 drives step by step a pinion 130 secured to a wheel 131 which meshes with an internal toothing 132 of the first date disk 51. The second program wheel 127 drives step by step a pinion 134 integral with a wheel 135 which meshes with an internal toothing 136 of the second date disk 52.

   In fig. 13, the second program wheel 127 is omitted to clarify the drawing.

Table I indicates more precisely the numbers of revolutions made by the main rotary mobiles of the calendar mechanism shown in FIG. 13, in an average year of the Julian cycle.

Table I

[0058]
 <Tb> No. reference <September> Designation <sep> Number of tours in 365.25 days


   <Tb> 99 <sep> Hour wheel <September> 730.5


   <Tb> 46 <sep> Calendar index <September> 13.04464


   <Tb> 56 <sep> Disc of the months <September> 12.04467


   <Tb> 58 <sep> Years disk <September> 12.94468


   <Tb> 60 <sep> Disk decades <September> 12.95468


   <Tb> 124 <sep> Single tooth wheel <September> 11.99988

The value indicated in the last row of Table I has a relative error of -10. <-6> compared to the ideal value of 12, so that the moment when the one-tooth wheel 124 controls the advance of a date disc will be delayed by about 5 minutes per year, which is better than the accuracy of running a good mechanical watch.

Note that if the calendar mechanism was to be driven not by the watch movement, but by a clean electric motor, the wheels 101 to 104 could be removed and the engine could be controlled by the watch movement for once a day, train the wheel set 105-107.

Figs.

   14 and 16 represent the program wheel 126 in two situations which correspond respectively to the month of April of a normal year (to reach the state of the display according to Fig. 5) and to the end of February of a leap year (display state according to Fig. 7).

The program wheel 126 is a composite mobile which rotates on a fixed axis 139 provided with a fixed wheel 140 with six teeth. It comprises a first board 141 provided with an input toothing with twenty-four teeth 142 regularly spaced, a second board 143 provided with an output toothing 144 which will be described later, two eight-toothed planet wheels 145 and 146 which meshes with the fixed wheel 140, and a sliding movable member 147 provided with a single tooth 148 preceded by a hollow 149 itself preceded by a shoulder 150 in an arc.

   The elements 140, 145, 146 and 147, which are drawn in bold lines to facilitate the reading of the drawing, are housed between the boards 141 and 143, in a recess 152 of the second board 143. The side wall of this recess has two shoulders. 153 and 154 forming stops which define the two functional positions of the sliding element 147. The planet wheels 145 and 146 are rotatable about respective pins 155 and 156 integral with the second plate 143.

   With the fixed wheel 140, they constitute a control mechanism of the sliding element 147, as will be described later.

The output teeth 144 of the program wheel is a toothing with thirty-six modules, but has only twenty-four teeth 158 and twenty-nine recesses 159 adjacent to these teeth, the teeth and the recesses being arranged in groups that are separated by five gaps corresponding to months of less than 31 days. These gaps are occupied by respective shoulders 160 to 164 in an arc, respectively corresponding to the months of February, April, June, September and November.

   The shoulders 161 to 164 correspond to the removal of two teeth and a hollow between them, for the months of 30 days, while the shoulder 160 corresponds to the removal of three teeth and two recesses therebetween, for a month of February of 29 days. In the position shown in FIG. 14, the shoulder 150 of the sliding member 147 extends the shoulder 160 of a module, so that these two shoulders combined correspond to the removal of four teeth and three recesses therebetween for a normal February month of 28 days.

The height of the shoulders 150 and 160 to 164, that is to say their radius relative to the center 151 of the program wheel, is sufficient for two successive teeth of the pinion 130 can slide back against the shoulder, thus blocking the position of the pinion 130, the wheel 131 (Fig.

   12) and the date disk 51 associated with the latter. Thus, the successive positions of the date disk are indexed by the output teeth of the program wheel, without the need for a jumper spring. Such indexing and its advantages are described in Swiss Pat. 688 671 of the same applicant.

It will be understood that the passage of each shoulder 160 to 164 in front of the pinion 130 rotates it one step, so finally has the same effect as the passage of one of the teeth 158.

Each turn of the wheel 124 to a tooth 125 produced at a feed of two steps of the input gear 142 of the program wheel, that is to say a twelfth of a turn. Between these operations in advance, the program wheel is stopped by the circular periphery 176 of the wheel 124, which is pressed against the head of the teeth 142.

   The program wheel, trained twelve times a year, goes one full year. In figs. 14 and 16, the circumference of the program wheel is subdivided into twelve sectors equal to 30 degrees, numbered by the Roman numerals I to XII and corresponding to the twelve months of the year. The number of troughs 159 associated with each month determines the number of steps of the advance made this month by the pinion 130, the wheel 131 and the date disc 51. This number is 0, 1, 2 or 3 depending on the month corresponding to twenty-eight, twenty-nine, thirty or thirty-one days, as explained above.

The sliding element 147 and its control mechanism are intended to change the number of steps of the advance corresponding to the month of February, depending on whether this month is twenty-eight or twenty-nine days.

   In the position shown in FIG. 14, which corresponds to a month of February of 28 days, the element 147 is in the retracted position and its additional tooth 148 is superimposed on a tooth 158a of the second board 143. The thickness of the tooth 158a corresponds to the lower half of the thickness of the other teeth 158 of the toothing 144. The two teeth 148 and 158a having exactly the same shape, the additional tooth 148 is somehow retracted and has no particular effect. The hollow 149 which precedes it is opposite a wider recess 166 of the board 143, which is otherwise covered by the shoulder 150 of the element 147.

   Thus, the pinion 130 will remain locked by sliding on the shoulders 160 and 150 during all the twelfth of a turn corresponding to the month of February of a normal year, and no step ahead of the date disk will be made, as it is described with reference to FIG. 3.

In the leap position shown in FIG. 16, which corresponds to a month of February of 29 days, the sliding element 147 is moved temporarily to the left with respect to the previous figure, so that its additional tooth 148 is moved one module relative to the teeth 144 , while the adjacent hollow 149 of the sliding element is always facing the wider recess 166 of the toothing 144. The shoulder 150 of the element 147 is then superimposed on the shoulder 160 of the plate 143.

   The tooth 148 and the recess 149 thus determine the unique pitch of the advance of the first date disc at the end of February of a leap year, as described with reference to FIG. 7.

The teeth of the two planet wheels 145 and 146 are arranged to abut by sliding against two corresponding edges 168 and 169 of the sliding element 147 so as to position this element, namely to move it between its two positions shown in FIGS. . 14 and 16 and positively position it permanently without the help of a spring. Since the gear ratio between the fixed wheel 140 and each of the planet wheels 145 and 146 is 3/4, each satellite wheel rotates three quarters of a year in the direction of the arrow that it carries.

   In other words, from February to the next, it is shifted a quarter of a turn in the opposite direction to the arrow. The wheel 145 has a long tooth 171 and seven short teeth 172, so that its long tooth 171 will push the sliding member 147 in February only one year out of four, which will put the element 147 in the leap position shown in FIG. fig. 16. On the other side, the satellite wheel 146 has five long teeth 173 which rest against the edge 169 of the element 147 to hold it in the position of FIG. 14, while the short teeth 172 of the other satellite wheel 145 pass along the opposite edge 168 of this element. The latter is retained by abutment against the shoulder 153.

   In the position of fig. 16, it is the three short teeth 174 of the wheel 146 which pass freely along the edge 169 of the element 147, which is retained by abutment against the shoulder 154. Moreover, the element 147 has a curved inner edge 170 which can rest by sliding against the head of the teeth of the fixed wheel 140.

Between two successive leap years, the rotation of the planet wheels 145 and 146 will twice temporarily put the sliding element 147 in its leap position, but these events will occur in other months than February, so that the tooth additional 148 will be distant from the pinion 130 and will have no effect at these times.

The second program wheel 127 is identical to the first 126 and operates in exactly the same way,

   to drive the second date disk 52 with the same number of steps as the first, but with a shift of half a month. If necessary, another value of this offset can be chosen by modifying the mutual positions of the axes of the program wheels and the wheel 124 which drives them.

Figs. 17 and 18 are similar to FIGS. 12 and 13 and represent a calendar mechanism capable of actuating the display shown in FIGS. 1 to 8 from the watch movement of the analog watch, more precisely from a central wheel hours 99.

   In fig. 18, the numbers written in italics represent the numbers of mobile teeth that will be described below.

The hour wheel 99 meshes with a wheel 171 having a pinion 172 which meshes with a central wheel 173 secured to the disk 48 bearing the calendar index 46. With the numbers of teeth shown in FIG. 18, it is verified that the transmission ratio between the hour wheel 99 and the index 46 is:
  <EMI ID = 9.0>

As the hour wheel 99 makes two laps per day, the index finger 46 rotates clockwise in exactly 28 days.

The wheel 173, which is shown twice in FIG. 18 to clarify the diagram, is secured to another central wheel 174 which meshes with a return formed of two wheels 175 and 176.

   The wheel 176 meshes with a central wheel 177 secured to the disk of the months 56 and another central wheel 178. The latter drives, via a two-wheel return 180 and 181, a central wheel 182 secured to the disk of the years 58 .

In addition, the central wheel 174 to sixty-seven teeth plays the same role of driving wheel that the wheel 112 of the example of Figs. 12 and 13, to drive in the same way the date discs 51 and 52 via the perpetual calendar mechanism 120 comprising in particular the two program wheels 126 and 127, this mechanism being identical to that of the example mentioned above.

The foregoing description shows that the program wheels 126 and 127 of the perpetual calendar mechanism may have a relatively simple and low thickness construction.

   In addition, as the numbers of teeth of the elements that make it up are relatively small, the modules of the teeth are sufficiently large, which contributes to reducing the cost of manufacture. On the other hand, it should be noted that the entire calendar device described above is devoid of return springs or jumper springs, which have the disadvantage of creating friction, therefore wear and an adverse influence. on the watch.

In the second embodiment illustrated by FIGS.

   9 and 10, where the number of steps N = M - 35 of the monthly displacements of each date disk are between 4 and 7 in absolute value, a person skilled in the art can construct a program wheel similar to the wheel 126 described hereinabove. above, but whose numbers of teeth and recesses in the output teeth 144 will be adapted to the values of N. This set of teeth will have up to 7 tooth modules per monthly sector (sectors I to XII shown in FIG. therefore have a circumference divided into 84 modules.


    

Claims (16)

1. Timepiece equipped with a clockwork movement and a calendar display comprising: a dial (43) with a fixed graduation (47) in days of whole weeks which extends over the entire circumference of the dial, date indicator means (51, 52), driven in rotation by steps and having at least one date scale in correspondence with the graduation of the days, and a calendar mobile index (46) rotated by the watch movement with respect to the graduations of the days and the calendars, characterized in that the date indicator means comprise two concentric date discs (51, 52) capable of being angularly offset with respect to each other, namely a first disc (51) whose graduation (53) ) contains the dates (1 to 15)  a first portion of a month and a second disc (52) whose graduation (54) includes the other calendars up to 31, corresponding to a second part of a month, in that the first date disc (51) is moved by N not in the second part of a month, N being equal to the number of days of said month minus the number of days of the graduation of the days, so that the last date of said month on the graduation of the second disc is followed by the first calendar of the following month on the graduation of the first disc, and in that the second date disc (52) is moved by the same number N of steps in the first part of the following month, which restores the continuous sequence of the dates on the set formed by the two date scales. 2. Timepiece according to claim 1, characterized in that the graduation of the days (47) comprises twenty-eight days on the turn of the dial, so that N is always greater than or equal to zero and the displacements of the discs dates are made in the increasing direction of the graduations of the days and the calendars. 3. Timepiece according to claim 1, characterized in that the graduation of the days (47) comprises thirty-five days around the dial, so that N is always negative and that the movements of the date discs s' in the decreasing direction, they make graduations of days and dates. 4. Timepiece according to claim 1, characterized in that the calendar display comprises a month disc (56), concentric with the date discs and carrying a circular graduation of the months (57), this record of the months being driven to rotate relative to one revolution in one year relative to the calendar moving index (46). 5. Timepiece according to claim 1, characterized in that the calendar display comprises a disc of the years (58), concentric to the date discs and carrying a circular graduation of the years (59), this year disc being driven to perform a lap in an integer number of years with respect to the mobile calendar index (46). 6. Timepiece according to claim 5, characterized in that the disk years (58) performs a revolution in ten years with respect to said index, its graduation (59) bearing the numbers from 0 to 9, and in that the calendar display further includes a disc of decades (60), driven to perform a lap in one hundred years relative to said index and bearing a decades index (61) next to the graduation of the years (59). 7. Timepiece according to one of claims 1 to 6, characterized in that the two date scales (53, 54) are arranged on arcs of circles of different radii, so that they can be partially juxtaposed . 8. Timepiece according to one of claims 1 to 6, characterized in that the two date scales (53, 54) are arranged on arcs of circles of equal radius, so that they can be partially superimposed . 9. Timepiece according to one of claims 1 to 6, characterized in that it comprises a calendar mechanism (120) driven by the watch movement and having, to drive the first date disk (51). a first program wheel (126) driven once a month by the watch movement so as to make one turn per year and provided with an output toothing (144) having five gaps corresponding to the months of less than thirty-one days, and a gear train (130, 131) connecting the output teeth of this program wheel to a toothing (132) of the first date disc (51). 10. Timepiece according to claim 9, characterized in that the calendar mechanism (120) comprises, for driving the second date disk (52), a second program wheel (127), similar to the first and driven wheel once a month by the watch movement so as to make one turn per year, and a gear train (134, 135) connecting the output toothing of the second program wheel to a toothing (136) of the second date disc ( 52), and that the two program wheels (126, 127) are driven by means of a wheel (124) to a tooth (125) which rotates twelve times a year, both program wheels being arranged and other of the one-tooth wheel to be driven by said tooth (125) alternately in the first part and in the second part of each month. Timepiece according to claim 9 or 10, characterized in that the or each program wheel (126, 127) carries a movable element (147) provided with an additional tooth (148) and a control mechanism ( 140,145,146), the movable member having a leap position, wherein the additional tooth (148) is added to the output gear (144) in the gap corresponding to February, and a withdrawal position in which the additional tooth (148) is retracted, the control mechanism being arranged to put the movable member (147) temporarily in the leap position each February in program wheel positions which are shifted by a quarter of a second. turn from one year to the next, so that the additional tooth (148) drives the corresponding gear only one year out of four. 12. Timepiece according to claim 11, characterized in that said control mechanism comprises two planet wheels (145, 146), rotatably mounted on the program wheel and meshing with a fixed wheel (140) concentric with the program wheel so that each satellite wheel shifts a quarter turn per year from the program wheel, said planet wheels having cam surfaces abutting said movable member (147) to position it. 13. Timepiece according to claim 12, characterized in that the fixed wheel (140) has six teeth and each satellite wheel (145, 146) has eight teeth. Timepiece according to claim 12, characterized in that said movable element (147) is arranged to pivot about the center of the program wheel and in that its additional tooth (148), in its retracted position, is superimposed on one (158a) of the teeth of the output gear (144) of the program wheel. 15. Timepiece according to claim 10, characterized in that each program wheel (126, 127) is devoid of any spring. 16. Timepiece according to claim 10, characterized in that the calendar mechanism is devoid of any spring.