This application is based on and claims priority under 35 USC 119 from European Patent Application No. 19157299.9 filed Feb. 14, 2019, which is incorporated herein by reference in its entirety.
The invention concerns a month and leap year display mechanism for a timepiece.
The invention concerns the field of timepiece complications comprising a calendar.
Calendar mechanisms are one of the classic timepiece complications. Some complex mechanisms are able to manage the duration of months or years. Leap year displays or indicators allow the user to determine whether or not the current year is a leap year, and, depending on the level of complexity of the watch, can manage the display of the last day of February, and the correct change to the first of March.
In the case of the simplest calendar mechanisms, simply knowing whether or not the current year is a leap year allows the user to make the right correction to the display on the last days of the current month, generally by means of the control stem. The mechanisms differ depending upon whether they concern a simple date calendar, an annual calendar or a perpetual calendar. In these latter cases, the leap year control mechanism requires expensive components, for example a Maltese cross-shaped cam, and take up a certain amount of space inside the watch case, or the case of the timepiece if it is static like a clock.
The leap year display is often achieved by displaying a sector of a disc with four quadrants inside a small window, or by the cooperation of an index with one part of such a disc.
WO Patent No. 01/48568 in the name of BELPANORM discloses a perpetual calendar mechanism actuated by a motorized wheel of a timepiece movement and displaying at least the calendar date. It is composed exclusively of rotating movable elements formed by gears and the drive wheel makes one revolution per day instantaneously at midnight. One of the gears is a date wheel driving a movable element displaying the date. The date wheel comprises thirty-one teeth and is driven at a rate of one step per day by a drive tooth integral with the drive wheel. At least one of the other gears is a movable element for the length of the months, capable of being driven in the last four days of the month by a control wheel integral with the date wheel; this movable element for the length of the months comprises a set of teeth composed of a set of 0 to 3 groups of teeth, each of the groups corresponding to a month of the year. The date wheel is driven at the end of months of thirty-one days by a number of steps corresponding to the difference between thirty-one and the number of days of the month concerned by an adjustment clock train comprising at least one drive pinion integral with the drive wheel, the movable element for the duration of the month, the date drive pinion and the control wheel.
The present invention proposes to combine a display of the current month with a display of the current year type (leap year or non-leap year), with a very simple, inexpensive, very reliable, easy to correct mechanism, which is confined to a reasonable space inside the timepiece concerned.
To this end, the invention concerns a month and leap year display mechanism for a timepiece according to claim 1.
The invention also concerns a calendar mechanism comprising a date mechanism arranged to cooperate with a timepiece movement and comprising at least one such month and leap year display mechanism, according to claim 17.
The invention also concerns a timepiece comprising at least one timepiece movement arranged to drive at least one such month and leap year display mechanism, and/or to drive at least one such calendar mechanism.
Other features and advantages of the invention will appear upon reading the following detailed description, with reference to the annexed drawings, in which:
The invention concerns a month and leap year display mechanism 10 for a timepiece 1000.
According to the invention, this mechanism 10 includes a leap year display integrated in a month display. The invention is described in the particular non-limiting case of a Gregorian calendar display, but lends itself perfectly to other types of calendar, notably of the lunar or Zodiac type, which those skilled in the art will know how to make by replacing the device for changing the display at the end of the month, which will be described hereinafter, with device for changing the display at the end of a lunar month, or at the end of any ad hoc period.
Depending on the configuration of the timepiece, mechanism 10 either comprises a movement 100, or mechanism 10 is arranged to cooperate with a movement 100. In both cases, this movement 100 is arranged to drive a month display wheel set 2, formed in particular but not exclusively by a display ring or a display disc, via a control mechanism 3, comprised in mechanism 10. This month display wheel set 2 is arranged to rotate about an axis of rotation D and is arranged underneath a cover plate or underneath a dial 1. This dial 1 or cover plate, for example a bridge, or suchlike, comprises a month window 1C, which is contained within an angular sector of 90° about axis of rotation D. This month window 1C is arranged to allow a user to see a quarter of month display disc 2, while the other three quarters of month display disc 2 are concealed from the user, by dial 1 and/or at least one fixed portion of timepiece 100.
According to the invention, control mechanism 3 is arranged to make month display wheel set 2 complete one revolution in four years. Thus, month display wheel set 2 rotates by one forty-eighth of a revolution at the end of each month.
And this month display wheel set 2 bears, on an angular sector of 90°, at least one characteristic leap year marking.
And month display wheel set 2 either carries indices, which are each arranged to indicate one month on a static month scale of dial 1, or equidistant month markings, wherein one of the month markings is pointed to by a fixed mark of dial 1.
The Figures illustrate the design of such a leap year display, which includes, in this particular and non-limiting version, a cover plate, particularly in the form of a dial 1, of a month display wheel set 2 which is a ring, or a disc bearing an annular display track, and a control and distribution mechanism 3. Month display wheel set 2 is mounted to pivot about axis of rotation D. Control mechanism 3, driven by movement 100 or by a date mechanism 200, has the function of driving month display wheel set 2 one angular pitch, at each change of month, and of returning month wheel set 2 to a new rest position until it is actuated at the end of the next month.
In a first variant, and as seen in
In the Figures, these indices are triangular, and leap year index 2A bears the letter S for the leap year (from the German ‘Schaltjahr’).
In a particular embodiment, the ordinary year indices 2B are different from one another, each comprising a numbered indication, visible to the user, of the number of years remaining until the next leap year.
In another particular embodiment, the ordinary leap year indices 2B are different from one another, each comprising a numbered indication, visible to the user, of the number of years elapsed since the last leap year.
In a second variant, and as seen in
In a third variant, and as seen in
As regards control mechanism 3, in a particular, non-limiting manner illustrated in
Input wheel set 31 pivots 1/31st of a revolution at the end of each day; it is preferably driven by a date mechanism 200, and, depending on the type of date mechanism (notably a perpetual calendar or annular calendar), this rotation may conventionally require 2 to 3 hours at the end of the day. The date mechanism performs the end of month correction.
More particularly, input wheel set 31 is integral with a wheel of a date mechanism 200.
It is also possible to envisage, although this is of limited interest, the month and leap year display mechanism 10 being independent of any date mechanism; in such case it is driven by a movement 100, and it is up to the user to make the end of month correction.
More particularly, input wheel set 31 is arranged to pivot first star wheel 321 once per month, on the last day of the month.
In the particular case of a lunar calendar, the conventional driving of a 59-toothed wheel makes it possible to actuate the pivoting of first star wheel 321 on the last day of a lunar month, for a zodiac or Muslim or Israelite or similar calendar display.
More particularly, stop wheel 34 has an alternation of hollows 34A and peaks 34B, and intermediate wheel 32 and transformation train 33 are arranged to drive stop wheel 34 through the angular pitch between two successive hollows 34A during each basic rotation of first star wheel 321.
More particularly, each basic rotation of first star wheel 321 causes a roller 351, comprised in click 35, to move up a cam ramp between a hollow 34A and a peak 34B on a first part of the angular pitch, against spring 352 in order to wind the latter. This spring 352 is arranged, when it unwinds after roller 351 has passed over peak 34B, to pivot stop wheel 34 on a second part of the angular pitch to a new rest position in which roller 351 is wedged in a hollow 34A until the end of the following month.
More particularly, each rotation of stop wheel 34 causes a rotation of 1/48th of a revolution of month wheel set 2.
More particularly, each basic rotation of first star wheel 321 causes a rotation of a quarter turn of stop wheel 34.
In the non-limiting variant illustrated by the Figures, during the change from the last day of a month to the first day of the next month, input wheel set 31 drives intermediate wheel 32 and causes it to make one eighth of a revolution. Transformation train 33 is then arranged to pivot stop wheel 34 a quarter of a revolution.
Stop wheel 34 is thus driven approximately a quarter of a revolution by input wheel set 31 via the intermediate wheel and transformation train 33. Of this 90° rotation, around 45° are used to release click 35 and to wind its spring 352, to the position shown in
Naturally, other gear reduction factors can be employed without departing from the invention.
Advantageously, display mechanism 10 also includes a month correction mechanism 20, which is arranged to change the angular position of month display wheel set 2 on command by the user.
In a variant, this correction mechanism 20 comprises a drive element 222 directly operable by the user and arranged to drive month display wheel set 2 directly, by meshing, friction or magnetic cooperation.
In a variant, correction mechanism 20 comprises an actuator directly operable by the user and arranged to drive stop wheel 34 in rotation.
In an alternative, the correction can be made in a similar manner to that of the day of the week for calendar mechanisms displaying the day and date: in one of the positions of stem 221 and particular in position T2 of the stem, the date is corrected in a first direction of rotation, and the day of the week is corrected in a second direction of rotation opposite to the first. In the context of the invention, the correction would thus be as follows: in position T2 of the stem, the date is corrected in a first direction of rotation, and the position of month display wheel set 2 is corrected in a second direction of rotation opposite to the first.
The invention also concerns a calendar mechanism 300, which includes a date mechanism 200 arranged to cooperate with a movement 100 of a timepiece 1000, wherein calendar mechanism 300 includes at least one display mechanism 10 according to the invention. More particularly, this date mechanism 200 includes a train, which is arranged to count the number of days of the current month, and to cause input wheel set 31 to rotate 1/31st of a revolution from the first to the 27th of the month, and, on the last day of the current month, to rotate 4/31sts of a revolution when the current month has 28 days, or 3/31sts of a revolution when the current month has 29 days, or 2/31sts of a revolution when the current month has 30 days, or 1/31st of a revolution when the current month has 31 days, to cause input wheel set 31 to make one complete revolution during the current month.
More particularly, date mechanism 200 has a date display 1B, and input wheel set 31 is arranged to control the position of date display 1B.
More particularly, date mechanism 200 includes a date corrector 220 arranged to change the position of date display 1B.
More particularly, date corrector 220 is also arranged to change the angular position of month display wheel set 2.
The correction is described above for the case of a Gregorian calendar. A similar correction mechanism, controlled by the movement or by the user, can be realized for other types of calendar, particularly a lunar calendar, which require corrections at certain times.
The invention also concerns a timepiece 1000 including at least one timepiece movement 10 arranged to drive at least one such display mechanism 10, and/or to drive at least one such calendar mechanism 300.
More particularly, this timepiece 1000 is a watch.
Naturally, the principle of the invention can be extended to other types of calendar timepieces, particularly astronomical watches or astronomical clocks, in which, in particular, according to the principle of the invention, it is possible to manage the year display in addition to the month display, by differentiating, on a year display wheel set, between ordinary years, leap years, century years not divisible by 400 which are not leap years and have a February of 28 days, and century years divisible by 400 which are leap years and have a February of 29 days, or millennial years, which, although theoretically leap years, have a February of 28 days. In short, as a result of the present invention, it is possible easily to integrate in any timepiece a display that gives the user information as to whether it is a leap year, and/or, depending on the organisation of the display indices, how many years there are until the next leap year, or since the last one. The theoretical duration of February and the number of days in the current year are thus known. The invention allows correct adjustment of perpetual calendar mechanisms.
The invention allows a significant space saving inside the case of the timepiece concerned. Further, no additional indicator area is required on the timepiece dial. The essential classic displays of a wristwatch, like the time and date, remain perfectly clear and legible, and in the foreground.
The display is devised according to the principle of the Gregorian calendar or Julian calendar and is adaptable to any other type of calendar, particularly a lunar calendar.
Further, this display is not temporally limited, and does not lose its function on any expiry date.
The display mechanism according to the invention is economical, as is its correction mechanism.
Number | Date | Country | Kind |
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19157299.9 | Feb 2019 | EP | regional |