CH686019B5 - Mechanism perpetual calendar watch piece. - Google Patents

Description

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CH 686 019G A3

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Description

The present invention relates to a perpetual calendar mechanism of a timepiece by which can be displayed, on the dial of the piece, both the months of the year and the cycle of four years including the leap year.

The principles of perpetual calendar mechanisms are described in a book entitled "Modern watches calendar" by B. Humbert, 1953, Editions Scriptor S. A. in Lausanne.

According to this work, such a mechanism may include a date star provided with a month finger acting on another mobile which it advances at the end of each month. This mobile also includes a month cam which has a periphery at several heights so as to materialize, depending on the type of mechanism chosen, twelve months of the year or forty-eight months of four consecutive years.

In the case where the cam represents a twelve-month cycle, it is associated with a mobile rotating with it around its own axis, this mobile being placed in a deep notch of the cam at the place where it must materialize the month of February. This mobile, which turns around in four years, is capable of presenting at the periphery of the cam, either a height which represents a month of February of 28 days, or a height which represents a month of February of 29 days.

The month cam cooperates with a rocker capable, by palpating the profile of the cam, of causing the star of the calendar to perform the correct number of days in a month. This means that the mechanism is thus able to take into account the months of 31 days and 30 days and also the months of February at 28 and 29 days according to the leap cycle.

In the case where the cam represents 48 months, its profile immediately includes the four heights necessary according to an adequate arrangement so as to be able to directly take into account the variation in the number of days in the months, including the months of February over four years . Consequently, there too, the rocker can detect the correct number of days of the month each time and act accordingly on the date star.

In the two types of mechanisms, the rocker allows, at the end of each month, to adjust the mobile of the days thanks to a ratchet which is brought back on a toothed profile of this mobile of 0, 1, 2 or 3 steps corresponding, the scale then rotating the mobile for the number of days required near midnight of the day on which the change is to take place.

For the realization of these mechanisms, horlo-gersconcepteurs are notably confronted with two problems for which they must find a solution. The mechanism must be as compact as possible and the readability of the information it provides must be guaranteed at all times.

For example, in the second solution briefly mentioned above, the fact of directly coupling an indicator to the 48-month cam is a favorable measure for a reduction in congestion, but this goes to the detriment of readability, the graduation on the dial must then present 48 divisions to indicate the month. On the other hand, in this case it is also possible to obtain a direct display of the leap cycle.

To improve readability then, it is necessary to use a reduction gear with reference, which naturally increases the complexity and the bulk.

The first construction described above found a solution which not only improves the readability, but also reduces the dimensions of the mechanism. This solution described in patent EP 0 135 823 comprises a twelve-month cam and groups the mechanism around a single axis of rotation while ensuring a coaxial display of information concerning the months and the years.

However, in this case, the leap cycle indicator does not change in relation to a fixed scale on the dial, but in relation to markers which move with the month indicator, which only displays the month in relation to at a fixed scale provided on the dial.

As a result, we have certainly gained in compactness of the mechanism, but the readability of the information is not as good as one might wish.

The invention therefore aims to provide a mechanism of the kind indicated above, and having a particularly satisfactory compromise between the compactness of the mechanism and the readability of the information.

The subject of the invention is therefore a mechanism the characteristics of which appear in claim 1.

Thanks to these characteristics, and in particular to the use of a differential gear train of particular transmission ratios, one obtains a perpetual calendar mechanism which combines perfect readability with dimensions as small as possible, the month information and of the year being displayed by indicators which move relative to fixed reference marks provided on the dial of the timepiece.

Other characteristics and advantages of the invention will become apparent during the description which follows, given solely by way of example and made with reference to the appended drawings in which:

- fig. 1 is an axial sectional view along line l-l of FIG. 2 of a first embodiment of the invention;

- fig. 2 is a plan view on the dial side;

- fig. 3 is an axial sectional view along the line IV-IV of FIG. 4 of a second embodiment of the invention; and

- fig. 4 shows a plan view on the dial side of this second embodiment.

According to the example of figs. 1 and 2, the perpetual calendar mechanism according to the invention comprises a month 1 mobile comprising a month star 2 to 48 teeth as well as a cam 3 of 48 months including

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CH 686 019G A3

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the profile represents the evolution of the duration of the months over four years, each quadrant of this cam therefore corresponding to one year.

Cam 3 thus has four heights, namely hi for the months of 31 days, h2 for those of 30 days, h3 for the months of February of 28 days and h4 for the month of February to 29 days, that is to say - say that of the leap year.

The mobile 1 naturally goes around in four years and is driven by a day star (not shown) which, by an appropriate finger, advances one step every last day of the month around midnight.

In addition, the cam 3 cooperates with a rocker symbolized in the figures by an arrow B which palpates the profile of the cam and can cause the day star to advance by the number of days required at midnight at the end of each month.

The construction of a day star and a seesaw is known from the aforementioned work and it is therefore superfluous to describe it here in detail.

The mechanism according to the invention is mounted on a base or plate 4 which can be superimposed on a watch movement of any suitable type equipped with a motor output at 12 or 24 hours making it possible to properly drive the day star at each midnight passage.

In the base 4 is driven a pivot 5 whose axis X-X defines the central axis of the mechanism according to the invention. Around this axis X-X is grouped a train of differential gears generally designated by the reference 6 and whose mobile of months 1 is the satellite carrier.

A central wheel or sun wheel 7 is fixedly mounted on the pivot 5. It meshes with a satellite mobile 8 which is rotatably received in a hole 9 in the satellite carrier 1. More specifically, the mobile-satelli-te 8 comprises a pinion 10 extended by two cylindrical bearings 11a and 11b, the bearing 11a swirling in the hole 9 of the mobile 1.

A wheel 12 is fixed around the seat 11b, so that the pinion 10 and this wheel 12 are integral in rotation.

The wheel 12 meshes with a mobile 13 which comprises a wheel 14 surmounted by a barrel 15 and pivoting on the pivot 5. The barrel 15 crosses the dial C of the watch and carries a needle 16 indicative of the months of the year.

The barrel 15 also passes through a central hole 17 of the cam 3 as well as a second barrel 18 which is driven into this hole 17 and which is therefore integral in rotation with the mobile or satellite carrier 1. This barrel 18 also crosses the dial C and carries a needle 19 indicating the years.

The gear ratios of the mobiles of the differential gear train are chosen so that the mobile 13 of the months rotates four times faster than the mobile 1. In this case, the ratio introduced by the differential train is therefore multiplied by four.

In fig. 1 and 2, it is assumed that it is in the month of December of the leap year, the mobile 1 rotating in the direction of the arrow F. The rocker B is then on the range 20 of the cam 3 (see the bottom of Fig. 2) which represents the month of December of the leap year and the month of January of the following year.

In a concrete embodiment, the gears have numbers of teeth as follows:

Wheel 7

25

Sprocket 8

10

Wheel 12

24

Wheel 14

12

Figs. 3 and 4 represent a second embodiment of the invention.

In this case, the mechanism according to the invention comprises a mobile 20 forming a planet carrier and comprising a month star 21 with 12 teeth, as well as a month cam 22 whose profile represents the months of a single year.

As in the embodiment of FIGS. 1 and 2, the mobile 20 cooperates with a day star (not shown) and with a rocker symbolized by the arrow B.

This mechanism is mounted on a base 23 in which is driven a pivot 24 of axis X-X which is the central axis of the mechanism.

On the pivot 24 is cut a pinion 25 which constitutes the central wheel or sun wheel of a differential gear train 26 of which the mobile 20 is the planet carrier.

The pinion 25 is engaged with a satellite mobile 27 comprising a wheel 28 meshing with this pinion 25, a pin 29 rotatably mounted in a hole 30 of the month star 21 and a wheel 31, it being understood that the wheels 28 and 31, as well as the pin 29 are integral in rotation.

The wheel 31 has a particular shape as shown in FIG. 4. It includes eight teeth of different heights which represent a cycle of four years including a leap year.

The profile of the cam for the months 22 has two heights hi, h2, respectively for the months of 30 and 31 days, while on the angular portion corresponding to the month of February, the cam has a notch 32 in which is housed in particular the wheel 31. During the operation of the mechanism, the latter can therefore have its teeth at the periphery of the cam 22, that is to say be part of the profile of the cam 22.

The eight teeth of the wheel 31 have four teeth of maximum height Hi and used only for meshing, a trimmed tooth of intermediate height H2 for years whose month of February has 29 days and three trimmed teeth of minimum height H3 for 28 days in February. It can be seen that the teeth of maximum height Hi alternate respectively with the teeth having the heights H2 and H3.

Seen from the rocker B, these heights H2 and H3 correspond respectively to heights h3 and h4 of the profile of the cam 22.

The arrangement is designed in such a way that the flip-flop B "sees" a tooth of height H2 or H3 when the notch 32 is in front of it, that is to say each year at the end of February.

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The wheel 31 meshes with a central mobile 33 which is housed in the central part of the notch 32. The mobile comprises a wheel 34 secured to a barrel 35 crossing the dial C and carrying a needle 36 indicative of the years.

Furthermore, the star 21 includes a barrel 37 journalling on the pivot 24 and in the barrel 35 and carrying a needle 38 indicative of the months.

In this embodiment, the differential gear train also introduces a ratio of four, but this time in the reducing direction.

In the embodiment of FIGS. 3 and 4, the following numbers of teeth can be used, for example:

Sprocket 25

20

Wheel 28

16

Wheel 31

12

Wheel 34

20

It can therefore be seen that the invention provides an extremely compact perpetual calendar mechanism, while ensuring readability that is entirely convenient for the user, the graduation of the twelve months being distributed, in both cases, over 360 °.

In addition, the two graduations of the months and years are fixed relative to the dial and can therefore be entered directly there.

Of course, according to a variant, instead of indicator needles, it is also possible to use discs passing in front of counters made in the dial.

Claims (4)

Claims 1. Timepiece perpetual calendar mechanism comprising a month mobile (1; 20) intended to take one step per month under the action of a day mobile, said month mobile comprising a month star (2 ; 21) and a month cam (3; 22) integral in rotation with one another and forming the planet carrier plate of a differential gear train (6; 20), said month mobile ( 1; 20) being intended to cooperate with a rocker (B) intended to act on the day star for, by feeling said month cam, advancing said star by the number of days desired at the end of each month, said mechanism also comprising indicators (16, 19; 36, 38) for respectively indicating the month of the year and the year in a four-year cycle including a leap, said indicators being respectively coupled to gears of said differential gear train (6; 26), said mechanism being characterized in that one of said indicators (16; 36) is coupled to said mobile month (1; 20) through a transmission ratio of four and in that they indicate the respective information of month and year with respect to fixed marks carried by the dial (C) of said timepiece. 2. Mechanism according to claim 1, characterized in that said ratio of four is a multiplier and in that said movable month comprises a 48 month star (2) and a cam (3) whose profile represents the variation in the number of days in the months over four consecutive years. 3. Mechanism according to claim 1, characterized in that said ratio of four is reducing, in that said movable month (20) comprises a twelve month star (21) and a cam (22) whose profile represents the variation of the number of days of the months in a year, the variation of the days of February over four years being materialized by a toothed wheel (31) whose teeth of distinct heights (H2, H3) are arranged to be present on the periphery of said cam (22). 4. Mechanism according to claim 3, characterized in that said toothed wheel (31) comprises eight teeth of which four teeth have a normal meshing profile (height H), these teeth with normal profile alternating with four teeth with trimmed profile , three of these teeth having a minimum height (H3) for the months of February of 28 days, while a fourth tooth has an intermediate height (H2) for the months of February of 29 days. 5 10 15 20 25 30 35 40 45 50 55 60 65 5