CH714690B1 - Calendar mechanism, movement and timepiece. - Google Patents

Abstract

Disclosed is a calendar mechanism which can be constituted in a simple manner, which can avoid the application of a load to a gear train, and which can automatically carry out date catch-up at the end of a month of February at the same time in a normal year and in a leap year. A calendar mechanism (10) comprises a short month date drive wheel (25) which rotates one revolution in a day about a first axis (C1); a date indicator (50), which has an end-of-month finger (53) and which rotates one revolution in a month; and a short month date advancing finger (35) which is provided on the short month date drive wheel (25), which rotates in synchronism with the short month date drive wheel ( 25) while being moved, which pushes the month-end finger (53) to rotate the date indicator (50) through a first angle on the last day of a short month other than February among the short months in each of which the number of months is equal to less than 30 days, which pushes the end of month finger (53) to rotate the date indicator (50) by a second angle greater than the first angle on the last day of a month of February in a leap year and which pushes the end of month finger (53) to rotate the date indicator (50) by a third angle greater than the second angle on the last day of the month February of a normal year. The invention also relates to a movement as well as a timepiece comprising such a calendar mechanism.

Description

1. Field of the invention

The present invention relates to a calendar mechanism, a movement and a timepiece.

2. Description of Related Prior Art

[0002] In a calendar timepiece that can display a date and a month, it is known to provide a calendar mechanism which advances two dates so as to minimize the date correction at the end of a month. short that is thirty days or less.

[0003] For example, Japanese patent no. 4624848 (patent document 1) described below proposes a calendar mechanism comprising a planetary gear mechanism having a month satellite unit which has five drive teeth and a set of fixed sun gear teeth which is coaxial with a date indication and which has a direct drive relationship with the satellite month unit.

[0004] In addition, the article by Soichiro MATSUZAKI in "Chronos, Japanese version", Simsum Media Co., Ltd., February 3, 2011, pages 114 to 115 (non-patent document 1), described below, proposes a mechanism calendar comprising a control cam, a month indicator locking shaft which is operated by the control cam, a month indicator locking arm finger, a date finger, and a month star (month indicator) and a date indicator arranged so as to be coaxial with each other.

[0005] In addition, there is a calendar mechanism in which an advancement of four dates takes place at the end of a month of February of a normal year, in which an advancement of three dates takes place at the end of a month of February in a leap year and in which an advancement of two calendars takes place at the end of a short month other than the month of February (for example, see Soichiro MATSUZAKI, in „Chronos, Japanese version“, Simsum Media Co., Ltd., February 3, 2011, pages 108 to 111 (non-patent document 2)). Non-patent document 2 describes a calendar mechanism comprising a main lever, a 24-hour wheel claw provided to swing the main lever once a day, a 48-month cam provided to change the tilting angle of the main lever by the wheel claw of 24 hours per month, as well as a date indicator rotating by at least one tooth per day under the action of the tilting main lever. In the calendar mechanism described in non-patent document 2, a projection provided for rotating the date indicator by one tooth per day on the end of the tilting by the 24-hour wheel claw, as well as a main claw to make an additional rotation of the date indicator according to the angle of tilting of the main lever at the end of the short months equips the main lever.

[0006] However, in the prior art disclosed in Patent Document 1, the constitution is complicated due to the planetary gear mechanism employing plural gears. In addition, in the prior arts described in patent document 1 and in non-patent document 1, since the date advancement is two dates at the end of the short months, it is necessary to manually perform an additional date advancement each year at the end of February. Further, in the prior art described in non-patent document 2, as the main lever is swung daily, the load applied to the cog driving the 24-hour wheel claw can be increased by an amount which is that required for swing the main lever.

SUMMARY OF THE INVENTION

[0007] One aspect of the present invention is to propose a calendar mechanism which can be constituted in a simple manner, which makes it possible to avoid the application of a load to a cog and which can automatically carry out a catch-up of the date at the end of February in both a normal year and a leap year, as well as a movement and a timepiece.

[0008] According to the present application, there is provided a calendar mechanism according to claim 1.

According to the present invention, without needing to use a complicated planetary gear mechanism as described in the related prior art, it is possible to constitute a calendar mechanism with a simple constitution including a date drive wheel for a short month, a date advance finger for a short month, as well as a date indicator having an end-of-month finger. Furthermore, the date advance finger for short month pushes the end of month finger so as to cause the month indicator to rotate through a first angle on the last day of a short month other than the month of February among short months, each of which has a number of days less than or equal to 30 days, and he pushes the end-of-month finger so as to rotate the date indicator by a second angle greater than the second angle the last day of the month of February of a leap year, so that the number of dates of the date catch-up carried out at the end of the month of February of a leap year is higher than the number of dates of the date catch-up carried out at the end of a short month other than February. In addition, the date advance finger for short month pushes the end of month finger on the last day of the month of February of a normal year so as to rotate the date indicator by a third angle greater than the second angle. Consequently, the number of dates of the date catch-up carried out at the end of February of a normal year may be higher than the number of dates of the date catch-up carried out at the end of February of a leap year . Consequently, the date catch-up at the end of the month of February, which is carried out manually in the relevant prior art, can be carried out automatically both in a normal year and in a leap year. In addition, the date advance finger for short month pushes the end of month finger on the last day of the short month so as to rotate the date indicator, so that the period over which there is an increase of the load applied to the train driving the date drive wheel for the short month provided with the date advance finger for the short month can take place only on the last day of the short month. Consequently, it is possible to propose a calendar mechanism which can be constituted in a simple manner, which makes it possible to eliminate the application of a load on the wheel train and which can automatically carry out a date correction at the end of the month of February even both in a normal year and in a leap year.

[0010] It is preferred that the calendar mechanism be according to claim 2.

[0011] According to the present application, when the sliding contact portion of the date advance lever for short months is in sliding contact with any protruding portion among the first protruding portions, the second protruding portion and the third protruding portion, the short month date advance lever can be moved relative to the state where the sliding contact portion is not in sliding contact with any of the protruding portions. The second protruding portion is larger than the first protruding portion in the circumferential direction around the predefined axis. Consequently, the time during which the sliding contact portion is in sliding contact with the second protruding portion and during which the date advance lever for short month is thus moved is longer than the time during which the contact portion sliding is in sliding contact with any of the first projecting portions and during which the date advance lever for short month is thus moved. Consequently, the time during which the short month date advance lever brings the short month date advance finger into mesh with the month end finger on the last day of the month of February is longer than the length of time that the short month date advance lever causes the short month date advance finger to mesh with the month end finger on the last day of a short month other than February.

[0012] Further, when viewed from the axial direction of the predefined axis, the third protruding portion extends the second protruding portion in February of a normal year and is moved back out of the position extending the second portion in protrudes in February of a leap year, so that in February of a normal year, the time during which the short month date advance lever is moved from the state where the sliding contact portion does not is in sliding contact with any of the protruding portions is longer than in February of a leap year. Therefore, the time during which the short month date advance lever causes the short month date advance finger to mesh with the month end finger on the last day of February of a year normal is longer than the time during which the short month date advance lever brings the short month date advance finger into mesh with the month end finger on the last day of the month of February of a leap year.

[0013] As a result, the date advance finger for short month can push the end of month finger to rotate the date indicator by the second angle greater than the first angle on the last day of the month of February. 'a leap year, and the number of calendars of the adjustment carried out at the end of the month of February of a leap year may be higher than the number of calendars of the adjustment carried out at the end of a short month other than the month of February. In addition, the date advance finger for short month can push the end of month finger so as to rotate the date indicator by a third angle greater than the second angle on the last day of the month of February d a normal year, and the number of catch-up dates at the end of February in a normal year may be higher than the number of catch-up dates carried out at the end of February in a leap year. Therefore, it is possible to provide a calendar mechanism which is able to automatically catch up at the end of February even in a normal year and also in a leap year.

[0014] It is preferred that the calendar mechanism be according to claim 3.

[0015] According to the present application, it is possible to have a period during which the cam of the years is stopped with respect to the cam of the months. Therefore, it is possible to place the years cam in a predetermined rotating position at the end of February compared to the case where the years cam continuously rotates. Consequently, it is possible to reliably carry out the date catch-up at the end of a short month, by moving the date advance lever for short month with the desired trajectory.

[0016] It is preferable that the calendar mechanism be according to claim 4.

[0017] According to the present application, the range over which the date advance lever for short months can pivot is defined. Consequently, it is possible to prevent the date advance lever for the short month from inadvertently touching another component. Therefore, problems can be prevented from occurring in various mechanisms including the calendar mechanism.

[0018] It is preferred that the calendar mechanism be according to claim 5.

[0019] According to the present application, the date advance finger for the short month can be pushed in a direction away from the end of month finger. Consequently, it is possible to move the date advance finger for short month away from the end of month finger during a month (a long month whose number of days is 31 days) other than a short month, without using a return member provided to return the date advance finger for short month in the direction away from the end of month finger. Therefore, it is possible to avoid malfunctions of the calendar mechanism.

[0020] A movement according to the present application comprises a calendar mechanism as defined above.

[0021] Furthermore, a timepiece according to the present application comprises the movement as defined above.

[0022] According to the present application, the calendar mechanism which can be simply constituted, which can avoid the application of a load on the gear train and which can automatically carry out a catch-up of the date at the end of the months of February even as well a normal year than a leap year, so that it is possible to offer a movement and a timepiece that are excellent in terms of reliability and convenience.

[0023] According to the present application, it is possible to propose a calendar mechanism which can have a simple construction, which makes it possible to avoid the application of a load on the gear train and which can automatically carry out a catch-up of the date at the end of February including both a normal year and a leap year, as well as a movement and a timepiece.

BRIEF DESCRIPTION OF DRAWINGS

[0024] Figure 1 is a plan view of a timepiece, a movement and a calendar mechanism according to one embodiment. FIG. 2 is a plan view of a date advance mechanism according to the same embodiment. Fig. 3 is an exploded view showing the shapes of a month cam and a year cam. Figure 4 is a plan view showing a rotational position of the year cam relative to the month cam. Figure 5 is a plan view showing a rotational position of the year cam relative to the month cam. Figure 6 is a plan view showing a Maltese cross mechanism. Fig. 7 is a plan view of a month-advancing mechanism according to the aforementioned embodiment. Fig. 8 is a block diagram illustrating the power transmission path in the calendar mechanism according to the aforementioned embodiment. Fig. 9 is a view for explaining a state change of the calendar mechanism according to the aforementioned embodiment. Fig. 10 is a view explaining a state change of the calendar mechanism according to the aforementioned embodiment. Fig. 11 is a view explaining a state change of the calendar mechanism according to the aforementioned embodiment. Fig. 12 is a view explaining a state change of the calendar mechanism according to the aforementioned embodiment.

DESCRIPTION OF EMBODIMENTS

In the following, an embodiment of the present invention will be described with reference to the drawings.

[0026] Generally, a device body comprising the driving part of the timepiece is called a “movement”. The state of the finished product obtained by fitting the movement with a dial, hands or the like, and placing the movement in a timepiece box is called a “complete timepiece”. Among the two sides of the plate forming a frame of the timepiece, the side with the crystal of the timepiece case, that is to say the side with the dial is called the rear side of the movement . Moreover, among the two sides of the plate, the side with the bottom of the timepiece case, i.e. the side opposite the dial, is called the front side of the movement. Further, in the following description, clockwise is referred to as clockwise and counterclockwise is referred to as counterclockwise on each plan views in Figure 1 and the following figures.

[0027] Figure 1 is a plan view of a timepiece, a movement and a calendar mechanism according to the aforementioned embodiment. Fig. 1 is a plan view obtained when viewed from the rear side of a movement 100. Further, in Fig. 1, each constituent component is seen as if viewed through a dial 2, for the sake of convenient.

As shown in Figure 1, a timepiece 1 is provided with a dial 2 comprising an indicator indicating information relating to time or the like. Timepiece 1 is provided with an hour hand (not shown) indicating the hours, a minute hand (not shown) indicating the minutes and a seconds hand (not shown) indicating the seconds.

In addition, timepiece 1 has a month display zone 4 and a date display zone 6.

[0030] The month display zone 4 comprises a month display window 4a placed between a position substantially at six o'clock of the timepiece and the center of the timepiece 1. For example, the timepiece clockwork 1 displays a month to a user by exposing to view, in the month display window 4a, the letters indicating the month (for example, the letters "FEB" representing the month of "February" in the figure 1) present on a 5 month display disc.

[0031] The date display zone 6 is located over a range extending substantially from 12 o'clock to 6 o'clock. The timepiece 1 has a date hand 7 indicating the date. The timepiece 1 displays the date to a user by causing the date hand 7 to indicate one of the characters “1” to “31” present on the dial 2.

The movement 100 has a winding stem 8 and a crown 9 placed at a distal end of the winding stem 8. The movement 100 allows the date and month to be corrected in such a way that the crown 9 is pulled towards the outside with respect to a timepiece case 1a, then is turned in a predefined direction so as to turn a date indicator 50 and a month indicator 80 (both described below) and be able to correct the date and the month.

The movement 100 has a calendar mechanism 10. The calendar mechanism 10 has a date advancement mechanism 20 and a month advancement mechanism 60. In what follows, we will describe in detail the mechanism of calendar 10 with date advance mechanism 20 and month advance mechanism 60, with reference to the respective drawings. In addition, the calendar mechanism 10 of the embodiment is a mechanism conventionally called a perpetual calendar which automatically advances the date on February 28 of a normal year up to the first date and automatically catches up the date on February 29 of a leap year up to the first date. Also, a normal year is a year that is not a leap year and whose last date of February is 28.

Date advancement mechanism

Figure 2 is a plan view of the date advancement mechanism according to the embodiment.

As shown in Figure 2, the date advancement mechanism 20 mainly comprises an hour wheel 21, a date drive wheel for short month 25, a date advance lever for short month 30, a 27 month cam, a 28 year cam, a 90 Maltese cross mechanism (corresponding to what is called „drive mechanism“ in the appended claims), a 40 date indicator drive wheel, a date indicator 50 and a date jumper 56.

The hour wheel 21 is driven in rotation by power transmitted from a power source (not shown) which is housed inside the timepiece box 1a, such as a motor or a movement barrel, for example. The hour wheel 21 rotates around a predetermined axis, clockwise. For example, the rotation of the hour wheel 21 is transmitted to the date drive wheel for short month 25, via a gear train such as a minute wheel 22 or an intermediate date indicator 23.

The date drive wheel for short month 25 comprises a small date drive toothing for short month 25a which meshes with an intermediate date indicator pinion 23a of the intermediate date indicator 23. The wheel date drive for short month 25 rotates on a first axis C1 (corresponding to what is called "predefined axis" in the appended claims) counterclockwise, at the rate of one revolution per day (i.e. in 24 hours). The month cam 27 is provided at a central axis of the short month date drive wheel 25, so as to be coaxial with and relatively rotatable with respect to the short month date drive wheel. 25. As will be described later in detail, as month cam 27 completes one revolution in December, month cam 27 rotates on a different cycle than short month date drive wheel 25.

The short month date advance lever 30 is provided on the short month date drive wheel 25. The short month date advance lever 30 is placed so as to extend along an outer edge of the short month date drive wheel 25 and has the general shape of a substantially circular arc. The short month date advance lever is secured to the short month date drive wheel 25 at a position overlapping the month cam 27 and the year cam 28 in a direction orthogonal to the axial direction. of the first axis C1. The short month date advance lever 30 rotates around the month cam 27 in synchronism with the short month date drive wheel 25. Furthermore, the expression "in synchronism" means that several elements move simultaneously and covers both the case in which the elements have the same angle of rotation and the case in which their angles of rotation are different.

The date advance lever for short month 30 comprises a main lever body 31 which is carried by the date drive wheel for short month 25 so as to be rotatable on an axis parallel to the first axis C1, a shank 33 which extends from a base end of the lever main body 31, in a direction opposite to the lever main body 31, a sliding contact finger 34 (corresponding to what is called the sliding contact portion in the appended claims), which projects from a distal end of the lever main body 31, and a short month date advancing finger 35. The lever main body 31 extends from the center of rotation, clockwise around the first axis C1. Shank 33 extends from the base end of lever main body 31 counterclockwise around first axis C1. The shank 33 is shaped to be shorter than the main lever body 31. The shank 33 abuts against a degree adjustment rod 37 (described later), from the outside of the wheel. date drive for short month 25 in a radial direction.

The sliding contact finger projects from the distal end of the main lever body 31, towards the inside of the date drive wheel for short month 25, in a radial direction. The sliding contact finger 34 is able to be in sliding contact with an outer peripheral surface of the cam of the months 27 and an outer peripheral surface of the cam of the years 28.

The date advance finger for short month 35 projects from the distal end of the main body of the lever 31, towards the outside of the date drive wheel for short month 25, according to a radial direction. The date advance finger for short month 35 presses on an end-of-month finger 53 (described later) disposed on the date indicator 50, so as to cause this date indicator 50 to rotate. short month 30 rotates about the first axis C1 counter-clockwise, one revolution per day, in response to one rotation of the short month 25 date drive wheel. Although the details will be provided later, it is now indicated that the short month date advance finger 35 rotates while being moved inward and outward in a radial direction.

The date drive wheel for short month 25 is equipped with the degree adjustment rod 37. The degree adjustment rod 37 touches the tail 33 of the date advance lever for short month 30, from the inside the date drive wheel for short month 25, in a radial direction. The degree adjusting rod 37 determines one end of the angular stroke of the short month date advance lever 30. In other words, the degree adjusting rod 37 prevents the lever main body 31 of the lever from The short-month date advancement 30 moves outward from the short-month date drive wheel 25, in a radial direction, beyond a predefined stroke.

[0043] The month cam 27 rotates on the first axis C1, counter-clockwise, step by step, at the rate of a step of 30° per month, and rotates one revolution in one. year. The 27 month cam is coaxial with the 80 month indicator (see Figure 1) and rotates in synchronism with the 80 month indicator.

Figure 3 is an exploded view showing the shapes of the month cam and the year cam.

As shown in Figure 3, a plurality of protruding portions 27a to 27e are disposed at an outer peripheral surface of the month cam 27. The protruding portions 27a to 27e of the month cam 27 are formed respectively at positions corresponding to the short months (February, April, June, September and November) each of which has 30 days or less than 30 days when the outer peripheral surface of the month cam 27 is divided into 12 portions around the first axis C1 and successively dedicated to the months of the year, from January to December in a clockwise direction. The bottoms between the projecting portions 27a to 27e are formed at positions corresponding to long months, each of which has 31 days. Furthermore, the protruding portions 27a to 27e consist of first protruding portions 27b to 27e corresponding to the months (April, June, September and November) other than the month of February among the short months and of a second protruding portion 27a corresponding to the month of February.

[0046] The first projecting portions 27b to 27e are formed so as to taper from the inside to the outside of the short-month date drive wheel 25 in a radial direction, in a plan view ( see figure 2). The first projecting portions 27b to 27e include peaks provided at ends of the short-month date drive wheel 25 on the outside in the radial direction. The tops of the first projecting portions 27b to 27e are in the form of cylindrical surfaces around the first axis C1. The top of the first projecting portion 27b is formed so as to face a finger portion 55 of the month-end finger 53 at a position corresponding to the thirtieth day of April (see Fig. 2). This applies to the first projecting portions 27c to 27e.

The second projecting portion 27a is formed so as to be larger than the first projecting portions 27b to 27e in the circumferential direction around the first axis C1. The second projecting portion 27a is formed to taper from the inside to the outside of the short month date driving wheel 25 in a radial direction, in a plan view. The second protruding portion 27a includes a peak at one end of the short-month date drive wheel 25, outward in a radial direction. The top of the second projecting portion 27a is in the form of a cylindrical surface around the first axis C1. A radius of curvature of the top of the second projecting portion 27a is equal to the radius of curvature of the tops of the first projecting portions 27b to 27e. The dimension of the top of the second projecting portion 27a in the circumferential direction around the first axis C1 is greater than each of the dimensions of the tops of the first projecting portions 27b to 27e in the circumferential direction around the first axis C1. The top of the second projecting portion 27a is formed so as to correspond to the finger portion 55 of the month-end finger 53 at a position corresponding to a period from the 29th day to the 30th day of February .

The funds between the projecting portions 27a to 27e are in the form of cylindrical surfaces around the first axis C1. Each of the funds is formed so as to be opposite the finger portion 55 of the month-end finger 53 at a position corresponding to the period from the 28th day to the 30th day of each corresponding month (month long).

The cam of the years 28 is carried by the cam of the months 27 so as to be rotatable. The cam of the 28s performs revolutions around the first axis C1 in synchronism with the cam of the months 27 and rotates with respect to this cam of the months 27. The cam of the 28s is provided between a position corresponding to the months of February and March of the outer peripheral surface of the month cam 27 and the first axis C1 when viewed in the axial direction of the first axis C1. The outer peripheral surface of the cam 28 is provided with three projecting portions which are third projecting portions 28a. The third projecting portions 28a are provided at the level of three of the four zones into which the cam of the years 28 is divided and which are distributed around the axis of rotation of this cam of the years 28. In the following, among the four areas of the division, the three areas where the third protruding portions 28a are located are respectively called the areas with protrusion and the only region where there is no third protruding portion 28a is called the non-protruding area.

[0050] Figures 4 and 5 are plan views showing angular positions of the year cam relative to the month cam. Also, in Figures 4 and 5, shading coincides with the cam of 28 years.

As shown in Figure 4, in a state where an area with protrusion is positioned outside the months cam 27 in a radial direction with respect to the axis of rotation of the years cam 28, the year cam 28 is such that a third projecting portion 28a extends the second projecting portion 27a of month cam 27, when viewed in the axial direction of the first axis C1. This third protruding portion 28a is located downstream of the second protruding portion 27a of the month cam 27, clockwise around the first axis C1, when it extends the second protruding portion 27a of the month cam 27 when viewed in the axial direction of the first axis C1. Further, as shown in Fig. 5, in a state where the non-protruding area is outside the month cam 27 in a direction radial to the axis of rotation of the month cam 28, the year cam 28 is formed so as to be completely covered by month cam 27 when viewed in the axial direction of the first axis C1. In other words, in a state where the area without protrusion is outside the months cam 27 in a direction radial to the axis of rotation of the months cam 28, the months cam 28 is such that the third projecting portions 28a are moved back out of the position extending the second projecting portion 27a of the month cam 27, when viewed in the axial direction of the first axis C1. In the month of February of a normal year, the third projecting portion 28a of the years cam 28 extends the second projecting portion 27a of the months cam 27, when viewed in the axial direction of the first axis C1. Moreover, in the month of February of a leap year, the third projecting portions 28a of the years cam 28 are moved back out of the position extending the second projecting portion 27a of the month cam 27, when viewed according to the axial direction of the first axis C1.

As shown in Figure 4, each third projecting portion 28a includes a peak located at one end on the outside of the cam years 28 in a radial direction. In a state where a third protruding portion 28a extends the second protruding portion 27a of the month cam 27 when viewed in the axial direction of the first axis C1, the top of this third protruding portion 28a extends along a arc-shaped with the same center as the top of the second protruding portion 27a of the month cam 27. In a state where the top of a third protruding portion 28a is aligned with the second protruding portion 27a of the month cam month 27 when looking in the axial direction of the first axis C1, the top of the third projecting portion 28a is continued by the top of the second projecting portion 27a. In other words, the top of a third protruding portion 28a is formed so as to be opposite the finger portion 55 of the month-end finger 53 in a position corresponding to the 28th day of the month of February of a normal year.

As shown in Figure 3, the Maltese cross mechanism 90 intermittently rotates the cam 28s. The Maltese cross mechanism 90 comprises a finger wheel 91 and a cam Maltese cross 95s The finger wheel 91 and the cam Maltese cross of the years 95 are placed at the same position according to the axial direction of the first axis C1. The finger wheel 91 is placed on the first axis C1. The finger wheel 91 is fixed to a support element (for example to the plate, to the gear train, or the like (not shown)) in order to support the month cam 27 for rotation. In other words, the month finger 91 rotates around the first axis C1 in a relative manner with respect to the month cam 27. An outer peripheral surface of the finger wheel 91 includes an arcuate segment 92 extending in an arc shape around the first axis C1 when viewed in the axial direction of the first axis C1, as well as a cam advancing finger of the years 93 which is placed between the two ends of the arc segment 92 and which projects in a direction orthogonal to the first axis C1.

[0054] The 95s cam Maltese cross is linked to the 28s cam. The 95s cam Maltese cross is coaxial with the 28s cam and attached to this 28s cam. other words, the 95s cam maltese cross is supported by the 27 months cam so as to be rotatable and rotates around the first axis C1 in synchronism with the 27 months cam. For example, the cam maltese cross 95s and the 28s cam are arranged on opposite sides with the 27s month cam interposed between them. The 95s cam Maltese cross comprises four teeth 96. The four teeth 96 are arranged at regular angular intervals around the axis of rotation of the 95s cam Maltese cross. A distal end of each 96 tooth is formed with a distal end surface 96a able to be in sliding contact with the arcuate segment 92 of the finger wheel 91. The distal end surface 96a of each tooth 96 extends in an arcuate shape having a diameter identical to that of the arcuate portion 92 of the finger wheel 91 when viewed in the axial direction of the first axis C1.

[0055] The cam Maltese cross of the 95s rotates about the first axis C1 in synchronism with the month cam 27 while allowing the distal end surface 96a of a tooth 96 to be in sliding contact with the portion in arc 92 of the finger wheel 91. In a state where the distal end surface 96a of a tooth 96 is in sliding contact with the arcuate portion 92 of the finger wheel 91, the rotation of the Maltese cross of cam of 95 years compared to cam of 27 months is prevented. In a state where any of the protruding portions 28a of the cam of the years 28 extends the second protruding portion 27a of the cam of the months 27 when viewed in the axial direction of the first axis C1, the Maltese cross of 95s cam is bonded to 28s cam so that distal end surface 96a of tooth 96 is in sliding contact with arcuate portion 92 of finger wheel 91.

Figure 6 is a plan view showing the Maltese cross mechanism. Further, in Fig. 6, a condition before the 95s cam Maltese cross engages the 93s cam advancing finger is shown in two dots.

As shown in Figure 6, the 95s cam Maltese cross engages the 93s cam advancing finger once during a 360° revolution performed by it. When the 95s cam Maltese cross meshes with the 93s cam advance finger, the 95s cam rotates 90° to the 27s cam while continuing its revolution. Then the teeth 96 of the cam Maltese cross 95 in sliding contact with the arcuate segment 92 of the finger wheel 91 are switched. Therefore, the 90s Maltese cross mechanism allows the 28s cam (see Figure 3) linked to the 95s cam Maltese cross to rotate 90° with each 360° rotation of the months cam 27.

As shown in Figure 2, the date advance lever for short month 30 rotates around the first axis C1 in a state where the sliding contact finger 34 is able to be in sliding contact with the peripheral surface of the month cam 27. The distal end of the date advance finger for short month 35 is positioned on the outermost side of the date drive wheel for short month 25 in a radial direction , in a state where the sliding contact finger 34 is in sliding contact with the top of one of the protruding portions 27a to 27e of the month cam 27 or with the top of the third protruding portion 28a of the month cam. years 28. In addition, the distal end of the date advance finger for short month 35 is positioned on the innermost side of the date drive wheel for short month 25 in a radial direction, in a state where the sliding contact finger 34 is in contact ct sliding with the funds between the projecting portions 27a to 27e. Accordingly, the month cam 27 causes the short month date advancing finger 35 to move inward and outward in a radial direction of the short month date driving wheel 25, response to the rotation of the short month date advance lever 30 rotating in synchronism with the short month date drive wheel 25. In the following, a position in which the short month date advance finger 35 is located on the innermost side of the short month date drive wheel 25 in a radial direction is called an "innermost position", while a position in which the finger The short-month date advancer 35 is located on the outermost side of the short-month date drive wheel 25 in a radial direction is called an “outermost position”.

The rotation of the date drive wheel for short month 25 is transmitted to the date indicator drive wheel 40, via a date transmission wheel 24, for example. The date indicator drive wheel 40 rotates one revolution per day (that is to say in 24 hours) counterclockwise, on an axis different from the first axis C1.

A date finger 42 is arranged on the date indicator drive wheel 40. The date finger 42 comprises a spring portion 43 having a circular arc shape in a plan view, as well as a portion contact 45 disposed at a distal end of the spring portion 43. The date finger 42 is disposed so as to be covered by the date indicator drive wheel 40 in a plan view. The date finger 42 is integral with the date indicator drive wheel 40 and rotates in synchronism with this date indicator drive wheel 40. The spring portion 43 is elastically deformable in the direction circumferential and in the radial direction of the date indicator drive wheel 40. The contact portion 45 rotates around the central axis of the date indicator drive wheel 40 due to the rotation of this date indicator drive wheel 40 and thus pushes on the date indicator toothing 51 to rotate the date indicator 50.

The date indicator 50 has the shape of a disc and on the outer peripheral edge thereof, the date indicator toothing 51 is formed. The date indicator toothing 51 has 31 teeth formed with a pitch of 360°/31=approximately 11.6° and corresponding to 31 dates which represent the number of days in a long month. The date indicator toothing 51 is pushed once a day by the contact portion 45 of the date finger 42 which rotates one revolution per day. Consequently, the date indicator 50 rotates step by step, around a second axis C2, clockwise, by one step per day having the same angle as the angular step (approximately 11.6°) of the date indicator toothing 51, and completes one revolution in one month (that is to say in 31 days).

The date indicator 50 has the end of month finger 53. The end of month finger 53 is provided at the same position as the date advance lever for short month 30 in the axial direction of the first axis. C1. The end of month finger 53 extends in a radial direction from the date indicator 50. The distal end of the end of month finger 53 forms the finger portion 55 which tapers from the inside towards the exterior of the date indicator 50 along a radial direction in a plan view. A side surface 55a (corresponding to what is referred to as the "thrust portion" in the appended claims) on the finger portion 55, which faces downstream with respect to counter-clockwise rotation watch around the second axis C2, is inclined towards the outside of the date indicator 50 in the radial direction. The distal end of the finger portion 55 is configured so as to pass inside a rotation path of the date advance finger for short month 35 in its outermost position when the indicator date 50 is in a position corresponding to the period from the 28<th> day to the 30<th> day.

[0063] For example, when the finger portion 55 is positioned opposite the month cam 27 on the last day of a month (for example in the state shown in FIG. 2), the date advance finger for short month 35 of the date advance lever for short month 30 which is in its outermost position can come into contact with the lateral surface 55a of the finger portion 55. At this instant, in the event that the sliding contact finger 34 of the date advance lever for short month 30 is in sliding contact with the top of one of the projecting portions 27a to 27e of the month cam 27 or else with the top of the third portion projecting 28a from the years cam 28, the finger portion 55 and the short month date advance finger 35 are engaged since the short month date advance finger 35 is prevented from moving inside of the date drive wheel for short month 25 depending on the direction radial. Therefore, the date indicator 50 is pushed by the short month date advancing finger 35 rotating with the short month date drive wheel 25 and rotates. Furthermore, in a case where the sliding contact finger 34 of the short month date advance lever 30 is not in sliding contact with the top of one of the projecting portions 27a to 27e of the month cam 27 or with the top of the projecting third portion 28a of the years cam 28, the side surface 55a of the finger portion 55 pushes, towards the center of the month cam 27, the date advance finger for the month short 35 which comes into contact with the side surface 55a. Consequently, the date advance finger for short month 35 avoids the finger portion 55 and does not engage with this finger portion 55.

The date jumper 56 is in abutment against the date indicator 50. The date jumper 56 is a component provided for adjusting the position of the date indicator 50 in rotation. The date jumper 56 comprises a portion forming a date jumper spring 58, the distal end 57 of which is a free end and which is elastically deformable. The distal end 57 of the portion forming the date jumper spring 58 can engage with the date indicator toothing 51. The date jumper 56 regulates the rotation of the date indicator 50 by the fact that the distal end 57 is in mesh with the date indicator toothing 51. Consequently, the date indicator 50 can rotate step by step, one step per day having the same angle as the angular step (about 11.6 °) of the date indicator toothing 51.

Month advancement mechanism

Figure 7 is a plan view of the month advancement mechanism according to the embodiment.

As illustrated in Figure 7, the month advancement mechanism 60 mainly comprises a date cam 61, a hammer 70, a date hand wheel 67, the month indicator 80, a month 86, as well as a booster wheel 78.

[0067] The date cam 61 is in synchronism with the date indicator 50 and rotates one revolution in a month (that is to say in 31 days) clockwise, around of the second axis C2. The outer peripheral surface of the date cam 61 forms a cam surface 62 which is formed in a spiral shape so that its radius gradually increases counterclockwise. The cam surface 62 has an outermost portion 63 whose distance from the second axis C2 is a maximum separation distance. The cam surface 62 has an innermost portion 64, the distance to the second axis C2 of which is a minimum separation distance.

The hammer 70 has, as a whole, an L-shape through a portion forming a follower 71 and a portion forming a main body of the lever 73. A connecting portion between the follower 71 and the main body of the lever 73 in the hammer 70 serves as a pivot portion 72 and is rotatably supported to reciprocate about a predetermined axis.

[0069] Follower 71 is shaped to have a distal end that curves toward cam surface 62 of date cam 61.

Opposite the pivot portion 72, one end of the main lever body 73 is fan-shaped and has an edge at which a lever toothing 74 is formed. The lever toothing 74 engages with the date hand wheel 67.

The hammer 70 is connected to the return wheel 78, via the date hand wheel 67. The hammer 70 is biased in the direction of clockwise, around the pivot portion 72, by the return wheel 78. Consequently, the follower 71 is pushed against the cam surface 62 of the date cam 61 and it is in sliding contact with the date cam 61 due to the rotation of this date cam 61.

The follower 71 of the hammer 70 is moved relatively when it is in sliding contact with the cam surface 62, in response to the rotation of the date cam 61.

[0073] When the follower 71 is at the level of the innermost portion 64, the hammer 70 is in a position in which it is tilted to the maximum in the direction of clockwise around the axis of the pivot portion 72. In the following, the position where the hammer is tilted maximally clockwise is referred to as the „initial position“. Further, when the follower 71 is at the outermost portion 63, the hammer 70 is in a position in which it is swung maximally counter-clockwise around the axis of the pivot portion 72. In the following, the position in which the hammer 70 is swung maximally counterclockwise is referred to as the „end position“. In Figure 7, the hammer 70 in its initial position is shown in two-dot dashed line while the hammer 70 in its final position is shown in solid line. Here, as mentioned above, the date cam 61 rotates one revolution in a month. Consequently, the hammer 70 makes a return trip between the initial position and the final position once a month.

A month advancing finger 75 is arranged on the main lever body 73. The month advancing finger 75 is provided between the pivot portion 72 and the lever toothing 74. The month advancing finger month 75 is formed so as to project towards the month indicator 80 disposed on the side opposite the date cam 61 with respect to the main lever body 73. The month advancing finger 75 is carried so as to be pivoted about a predetermined pivot axis, relative to lever main body 73. Month advance finger 75 pushes and rotates month indicator 80 on the last day of each month.

[0075] Further, a spring blade portion 76 is formed at a central portion of the main lever body 73 so as to extend along a direction of extension of the main lever body 73. spring blade 76 is elastically deformable as a whole, while one end of the lever tooth 74 side is fixed to the lever main body 73 and the other end of the pivot portion 72 side is a free end . The leaf spring portion 76 urges the month advancement finger 75 counterclockwise about the pivot axis, while the other end abuts against a month finger portion. 75 month advancement.

The lever toothing 74 of the hammer 70 meshes with the date hand wheel 67. The date hand wheel 67 is connected to the date hand 7 (see FIG. 1), thus causing this date hand 7. When the hammer 70 is in the initial position, the date hand wheel 67 is in a state where it is turned as far as possible counterclockwise. At this time, the date hand 7 indicates "1" among the numbers ranging from "1" to "31" present on the dial 2 to indicate the dates. Furthermore, when the hammer 70 is in the final position, the date hand wheel 67 is in a state in which it is turned to the maximum clockwise. At this time, the date hand indicates “31” among the numbers ranging from “1” to “31” present on dial 2 to indicate the date. Consequently, the date hand 7 is moved one step each day in response to the rotation of the date cam 61 and the movement of the hammer 70.

In addition, the follower 71 of the hammer 70 is instantly moved from its outermost position 63 to its innermost position 64, by a biasing force of the return wheel 78 and the hammer 70 is moved from its final position to its initial position, so that the date hand wheel 67 pivots very rapidly counterclockwise. At the same time, the date hand 7 pivots very rapidly in the anti-clockwise direction and it is instantly switched from a state indicating the number "31" present on the dial to indicate the date to a indication state of the number „1“. Consequently, the date hand 7 is moved back and forth in a fan shape at the level of the date display zone 6.

The month indicator 80 is arranged on the side opposite the date cam 61 with respect to the hammer 70, so as to be rotatable around the first axis C1. The month indicator 80 is disc-shaped, and at its outer peripheral edge there is a month indicator toothing 81. The month indicator toothing 81 has twelve teeth formed with a pitch of 30 ° corresponding to twelve months which represent the number of months in a year. The month indicator toothing 81 is pushed once by the month advancing finger 75 disposed on the hammer 70, when the hammer 70 moves from its final position to its initial position. Hammer 70 makes a round trip once a month. Therefore, the month indicator gear 81 is pushed once a month by the month advance finger 75.

The month jumper 86 is in abutment against the month indicator 80. The month jumper 86 is a component intended to adjust the position of the month indicator 80 in rotation and comprises a portion forming a jumper spring of month 88 whose distal end 87 is a free end and which is elastically deformable. Distal end 87 of month jumper spring portion 88 is engageable with month indicator toothing 81. Month jumper 86 adjusts rotation of month indicator 80 by distal end 87 meshes with the month indicator teeth 81. Consequently, the month indicator 80 rotates step by step around the first axis C1, with a step of 30° per month in the counter-clockwise direction of a watch and completes one revolution in a year.

[0080] Furthermore, the month display disk 5 (see FIG. 1) is placed on the month indicator 80. The month display disk 5 is placed so as to be coaxial with the month indicator. month 80 and covering the month indicator 80 and it rotates in synchronism with this month indicator 80. Characters from „JAN“ (January) to „DEC“ (December) which indicate each month are present on a surface of the month display disc 5 so as to be distributed with a step of 30° in the direction of clockwise.

The return wheel 78 is connected to the hammer 70 via the date hand wheel 67 and urges the hammer 70 towards the month indicator 80. The return wheel 78 has a portion forming a spring spiral 79 at a central space portion, while a main body 78a has an annular shape, for example. One end of the spiral spring 79 is fixed to the gear train bridge (not shown) of the timepiece 1 and the other end of the spiral spring 79 is connected to the main body 78a of the return wheel 78. The spring spiral 79 is coaxial with return wheel 78 and is spiral-shaped counter-clockwise so as to extend along an Archimedean curve, for example. Return wheel 78 rotates counter-clockwise, causing spiral spring 79 to decrease in diameter and elastically deform.

[0082] The hammer 70 moves from its initial position to its final position, thus causing the return wheel 78 to rotate counterclockwise, via the date hand wheel 67. Therefore, a biasing force is accumulated in the coil spring 79 of the return wheel 78 so as to rotate this return wheel 78 clockwise. Further, immediately after the hammer 70 has reached its final position and the follower 71 has passed the outermost portion 63 of the date cam 61, the biasing force of the spiral spring 79 is released and the return wheel 78 rotates clockwise very rapidly. Consequently, the hammer 70 can instantly move from its final position to its initial position.

Functioning

Figure 8 is a block diagram showing the power transmission path within the calendar mechanism according to the embodiment. In Figure 8, an arrow shown in a solid line indicates the direction of power transmission, while an arrow shown in a broken line indicates a positioning maneuver and a double line indicates a state of coaxial union.

[0084] We will now describe an operation of the calendar mechanism described above. In the following description, reference is made to FIGS. 1 to 8 for the reference numerals of the constituents of the calendar mechanism 10. Further, in the following, an operation of the calendar mechanism 10 will be described in the case where the date becomes the first day of the following month from the first day of a month until the last day.

As shown in Figure 8, the power supplied by a power source (not shown) such as a motor or a movement barrel is transmitted to the date drive wheel for short month 25, by the intermediary of a gear train such as the hour wheel 21, the minute wheel 22 and the intermediate date indicator 23. Consequently, the date drive wheel for short month 25 rotates around the first axis C1 in the direction anti-clockwise, at a speed of one revolution per day. Furthermore, the date advance finger for short month 35 mounted on the date drive wheel for short month 25 rotates around the first axis C1 in the counterclockwise direction, at a speed of one revolution per day, in synchronism with the date drive wheel for short month 25.

Furthermore, the power transmitted to the date drive wheel for short month 25 is transmitted to the date indicator drive wheel 40, via the date transmission wheel 24 meshing with the short month date drive wheel 25. Consequently, the date indicator drive wheel 40 rotates counterclockwise, at a rate of one revolution per day. Furthermore, the date finger 42 disposed on the date indicator drive wheel 40 rotates counterclockwise, at a speed of one revolution per day, in synchronism with the date indicator drive 40.

After having come into abutment against the date indicator toothing 51 of the date indicator 50 due to the rotation, the contact portion 45 of the date finger 42 pushes the date indicator toothing 51 with the time passing by. Furthermore, the moment at which the contact portion 45 of the date finger 42 comes into abutment against the date indicator toothing 51 of the date indicator 50 is generally set at a predetermined time before midnight when the date is changed ( for example between 11 p.m. and midnight, i.e. 0 a.m. of the following day). Then, if the date indicator toothing 51 is pushed by the contact portion 45 of the date finger 42 and is turned clockwise by a predetermined angle, the distal end 57 of the jumper jumper date 56 and the date indicator toothing 51 are temporarily uncoupled from each other and are again brought into engagement with each other. Consequently, the date indicator 50 rotates step by step in the clockwise direction, by one predetermined angular step per day, and rotates by one revolution in a month.

[0088] Furthermore, the date cam 61, which is linked to the date indicator 50 and which rotates in synchronism with this date indicator 50, rotates step by step in the direction of clockwise, one step a day, and turns one revolution in a month.

[0089] Here, the follower 71 is relatively moved from the innermost portion 64 to the outermost portion 63 due to the rotation of the date cam 61, and thus moves the hammer 70 from the initial position (position corresponding to the first day of the month) to the final position (position corresponding to the last day of the month). Consequently, the date hand wheel 67 meshing with the lever toothing 74 of the hammer 70 rotates step by step clockwise, one step per day. Furthermore, the date hand 7 linked to the date hand wheel 67 is moved by an amount corresponding to one day, at midnight when the date is changed, in response to the rotation of the date hand wheel. dates 67. As described above, the calendar mechanism 10 operates the date hand 7 step by step from the first day to the last day of the month.

Then, when the date is changed from the last day of the month to the first day of the following month, the calendar mechanism 10 operates the date hand 7 as explained below.

[0091] First, operation for a long month will be described.

In the case of a long month, the last day is the 31 <th> day, the date advancement at the end of the month is carried out solely by the date indicator drive wheel 40. More precisely , the date finger 42 disposed on the date indicator drive wheel 40 engages with the date indicator toothing 51 to rotate the date indicator 50 by one step on the 31st day a month long. In other words, it is necessary to prevent the date advance finger for short month 35 from acting on the finger portion 55 of the end of month finger 53 over the period from the 28th day to the 30th day. <th> day of a long month.

Fig. 9 is a view which explains a state change of the calendar mechanism according to the embodiment and which is a plan view showing a state of a part of the date advance mechanism on the 28th >day of a month long.

As shown in Figure 9, the month cam 27 is such that a bottom is positioned at a region opposite the center of the date indicator 50 on the outer peripheral surface in the long month. Consequently, the date advance finger for short month 35 is recessed in its innermost position by the month cam 27, from the 28th day to the 30th day, and, with the time passing, rotates without coming into engagement with the end of month finger 53. Consequently, the date indicator 50 is stopped in a state where its position is fixed by the date jumper 56 without being pushed by the date finger. date advancement for short month. Furthermore, the date cam 61 rotating in synchronism with the date indicator 50 is also stopped without rotating.

Then, after having come into abutment against the date indicator toothing 51 of the date indicator 50 due to the rotation, the date finger 42 placed on the date indicator drive wheel 40 pushes on the date indicator toothing 51 with the passage of time. Then, if the date indicator toothing 51 is pushed by the contact portion 45 of the date finger 42 and is turned clockwise by a predefined angle, the distal end 57 of the jumper date 56 and the date indicator toothing 51 are temporarily released from each other and are brought into engagement with each other again. Consequently, the date indicator 50 and the date cam 61 rotate by one step at a predefined angular step. Consequently, the date hand 7 is switched from the 31st day to the 1st day and is thus moved by an amount corresponding to one day.

[0096] Operation for a short month other than the month of February will now be described.

[0097] In the case of a short month among the short months other than the month of February, since the last day is the 30<th> day, the advancement of the date at the end of the month is carried out both by the date indicator drive wheel 40 and by the date drive wheel for short month 25. More precisely, on the 30th day of a short month other than the month of February, the advance finger calendar for short month 35 engages with the date portion 55 of the end of month finger 53 in order to cause the date indicator 50 to rotate by one step, and the date finger 42 disposed on the drive wheel date indicator 41 engages with date indicator toothing 51 to rotate date indicator 50 by one step. In other words, the date advance finger for short month 35 is avoided with respect to the finger portion 55 of the end of month finger 53 and the date advance finger for short month 35 is engaged with the finger portion 55 of the end of month finger 53 to rotate the date indicator 50 by one step on the 30<th> day over the period going from the 28<th> day to the 29<th> day of a short month among short months other than February.

Fig. 10 is a view which explains a state change of the calendar mechanism according to the embodiment and which is a plan view showing a state of a part of the date advance mechanism on the 30th >day of a short month other than February.

As shown in Figure 10, the month cam 27 is such that the top of a first projecting portion associated with the corresponding months among the first projecting portions 27b to 27e is opposite the finger portion 55 of the month-end finger 53 in a position corresponding to the 30th day in a short month other than February. Therefore, the short month date advance finger 35 is retracted to the innermost position by the month cam 27 on day 28 and day 29, and is placed in the outermost position by the cam of months 27 on the 30th day. When the date indicator 50 is in the position corresponding to the 30 <th> day, the finger portion 55 of the end of month finger 53 has entered inside the trajectory of the date advance lever for short month 30 in the outermost position. Therefore, after abutting the month-end finger 53 by the rotation of the short-month date driving wheel 25, the short-month date advancing finger 35 pushes the finger portion 55 of the month-end finger 53 to cause the date indicator 50 to rotate through a first angle with the passage of time. The moment when the date advance finger for short month 35 comes into abutment against the finger portion 55 of the end of month finger 53 is generally set at a predefined time before midnight when the date is changed (for example between 9 p.m. and 10 p.m.). Further, the timing at which the short month date advance finger 35 abuts the finger portion 55 of the month end finger 53 can be adjusted anyhow by changing the angular setting of the date finger 42 (i.e. by adjusting the position of the contact portion 45 of the date finger 42) and the angular adjustment of the date advance finger for short month 35.

[0100] In the embodiment, the date advance finger for short month 35 comes into abutment against the finger portion 55 of the end of month finger 53 at a predefined time before midnight, but the date advance finger date for short month 35 can also come into abutment against the finger portion 55 of the end of month finger 53, for example, between one o'clock and three o'clock in the morning.

[0101] Then, if the end of month finger 53 is pushed by the date advance finger for short month 35 and the date indicator 50 rotating in synchronism with the end of month finger 53 is turned in the clockwise by a predetermined angle, the distal end 57 of the date jumper 56 and the date indicator teeth 51 are temporarily released from each other and are again brought into engagement. with each other. Consequently, the date indicator 50 and the date cam 61 rotate one step at a predetermined angular step. Consequently, the date hand 7 passes from the 30<th> day to the 31<th> day and is thus operated by an amount corresponding to one day.

Furthermore, after having come into abutment against the date indicator toothing 51 of the date indicator 50 due to the rotation, the date finger 42 disposed on the date indicator drive wheel 40 pushes on the date indicator toothing 51 as the time elapses. Therefore, in a manner similar to what occurs on the last day of a long month as described above, date indicator 50 and date cam 61 rotate one step at a predetermined angular step. Consequently, the date hand 7 is switched from the 31st day to the 1st day and is thus operated by an amount corresponding to one day.

[0103] In the case of a short month other than the month of February, the operation described above causes the date indicator 50 and the date cam 61 to rotate by two steps in one day at a predefined angular step. . In other words, this operation causes the date hand 7 to be switched from the 30th date to the 1st date, causing the 31st date to pass quickly.

The operation during the month of February of a leap year will now be described.

[0105] In the case of the month of February of a leap year, since the last day is the 29th day, the date advancement at the end of the month is carried out both by the date indicator drive wheel 40 and by the date drive wheel for short month 25. More specifically, the date advance finger for short month 35 comes into engagement with the finger portion 55 of the end of month finger 53 to rotate the date indicator 50 by two steps on the 29th day of the month of February of a leap year, and the date finger 42 provided on the date indicator drive wheel 40 comes into engagement with the toothing of date indicator 51 to rotate the date indicator 50 by one step.

Fig. 11 is a view which explains a state change of the calendar mechanism according to the embodiment and which is a plan view showing a state of a part of the date advance mechanism on the 29th >day of February in a leap year.

As shown in Figure 11, the month cam 27 is such that the top of the second projecting portion 27a is opposite the finger portion of the end of month finger 53 in a position corresponding to the period from from the 29<th>day to the 30<th>day of the month of February. Accordingly, the short month date advance finger 35 is moved to its outermost position by the month cam 27 on the 29th day. In addition, the finger portion 55 of the end of month finger 53 is on the trajectory of the date advance lever for short month 30 which is in its outermost position when the date indicator 50 is placed in a position corresponding to the period from the 29th day to the 30th day. Here, the top of the second projecting portion 27a is longer than the dimension of the tops of the first projecting portions 27b to 27e in the circumferential direction around the first axis C1. Therefore, the short month date advance finger 35 is placed in its outermost position for a longer period of time than in the above-described case of a short month other than February. . Therefore, after abutting and engaging the month-end finger 53 on the 29th day by the rotation of the short month date drive wheel 25, the date advance finger for short month 35 pushes on the finger portion 55 of the end of month finger 53, with the passage of time, to cause the date indicator 50 to rotate through a second angle greater than the first angle mentioned above.

[0108] When the end of month finger 53 is pushed by the date advance finger for short month 35 and the date indicator 50 rotating in synchronism with the end of month finger 53 rotates through the second angle in the clockwise, the uncoupling between the distal end 57 of the date jumper 56 and the date indicator toothing 51 and the re-engagement of the distal end 57 of the date jumper 56 and the toothing date indicator 51 with each other are repeated twice. Consequently, the date indicator 50 and the date cam 61 rotate by two steps having a predefined angular value. Consequently, the date hand 7 is moved by a quantity corresponding to two days passing from the 29<th> day to the 31<th> day.

Furthermore, after having come into abutment against the date indicator toothing 51 of the date indicator 50 due to the rotation, the date finger 42 provided on the date indicator drive wheel 40 pushes on the date indicator toothing 51 with the passage of time. In a manner similar to what occurs at the end of a long month as described above, the date indicator 50 and the date cam 61 rotate by a step having a predefined angular value. Consequently, the date hand 7 moves from the 31st day to the 1st day and is thus operated by an amount corresponding to one day.

In the case of a month of February in a leap year, the operation described above results in the date indicator 50 and the date cam 61 rotating by three steps having a predefined angular value, in one day. In other words, this operation causes the date hand 7 to pass from the 29<th> day to the 30<th> day and to the 31<th> day, by causing rapid advancement, and to pass to the first date.

The operation during the month of February of a normal year will now be described.

[0112] In the case of the month of February of a normal year, since the last day is the 28<th> day, the date advancement at the end of the month is carried out both by the drive wheel date indicator 40 and by the date drive wheel for short month 25. More precisely, the date advance finger for short month 35 comes into engagement with the finger portion 55 of the end of month finger 53 to make turn the date indicator 50 by three steps and the date finger 42 provided on the date indicator drive wheel 40 comes into engagement with the date indicator toothing 51 to cause the date indicator 50, on the 28th day of February of a normal year.

Fig. 12 is a view which explains a state change of the calendar mechanism according to the embodiment and which is a plan view showing a state of a part of the date advance mechanism on the 28th >day of February of a normal year.

As shown in Figure 12, the month cam 27 is such that the top of the second projecting portion 27a is opposite the finger portion 55 of the end of month finger 53 in the position corresponding to the period. from the 29<th>day to the 30<th>day of February. Further, the years cam 28 is such that the apex of the third projecting portion 28a is opposite the finger portion 55 of the month-end finger 53 in the position corresponding to the 28th day of the month of February. of a normal year. Accordingly, the short month date advance finger 35 is placed in its outermost position by the years cam 28. Further, the finger portion 55 of the month end finger 53 is placed on the trajectory of the date advance lever for short month 30 in the outermost position when the date indicator 50 is placed in the position corresponding to the period going from the 28<th>day to the 30<th> day. Here, the top of the second projecting portion 27a is longer than the dimensions of the tops of the first projecting portions 27b to 27e in the circumferential direction around the first axis C1. In addition, the top of the third projecting portion 28a extends the top of the second projecting portion 27a when looking in the axial direction of the first axis C1. Consequently, the short month date advance finger 35 is placed in its outermost position for a longer period of time than in the case of a February month of a leap year. Therefore, after abutting and engaging the month end finger 53 due to the rotation of the short month date drive wheel 25 on the 28th day, the month advance finger date for short month 35 pushes on the finger portion 55 of the end of month finger 53 and causes the date indicator 50 to rotate through a third angle greater than the second angle mentioned above, as time passes.

[0115] If the end of month finger 53 is pushed by the date advance finger for short month 35 and the date indicator 50 rotating in synchronism with the end of month finger 53 rotates by the third angle in the clockwise, the uncoupling between the distal end 57 of the date jumper 56 and the date indicator toothing 51 and the re-engagement of the distal end 57 of the date jumper 56 and the toothing date indicator 51 with each other are repeated three times. Consequently, the date indicator 50 and the date cam 61 rotate by three steps by a predefined angular value. Consequently, the date hand 7 is moved by an amount corresponding to three days passing from the 28<th> day to the 31<th> day.

Furthermore, after having come into abutment against the date indicator toothing 51 of the date indicator 50 due to the rotation, the date finger 42 provided on the date indicator drive wheel 40 pushes on the date indicator toothing 51 with the passage of time. Consequently, in a manner similar to what occurs on the last day of a long month as described above, the date indicator 50 and the date cam 61 rotate by a step of a predefined angular value. Consequently, the date hand 7 moves from the 31st day to the 1st day and is thus moved by an amount corresponding to one day.

In the case of the month of February of a normal year, the operation described above results in the date indicator 50 and the date cam 61 rotating by four steps by a predefined angular value in one day. In other words, this operation causes the date hand 7 to pass from the 28<th> day to the 29<th> day, to the 30<th> day and to the 31<th> day by causing rapid advancement.

[0118] Then, the date cam 61 turns one step on the 31st day of a long month, turns two steps on the 30th day of a short month other than February, turns three steps on the 29th day of February of a leap year or turns four steps on the 28th day of February of a normal year, thus causing the follower 71 of the hammer 70 to go to the beyond the outermost portion 63 of the date cam 61. Further, after the follower 71 has gone beyond the outermost portion 63, the hammer 70 is instantaneously moved from its final position to its initial position, by a biasing force produced by the return wheel 78 (see the two-dot chain line in Figure 7). Consequently, the follower 71 of the hammer 70 is moved relatively to the innermost portion 64 of the date cam 61.

At this instant, in the case of the last day of a long month, in response to the movement of the hammer 70 from the final position to the initial position, the date hand wheel 67 turns instantaneously in the opposite direction to the Clockwise. Consequently, the date hand 7 linked to the date hand wheel 67 moves instantaneously from the position indicating “31” of the last day to the position indicating “1” of the first day.

[0120] Furthermore, in the case of the 30 <th> day of a short month other than the month of February, in the date hand wheel 67, in response to the rotation of one step of the indicator 50 and the date cam 61 caused by the end of month finger 53, the hammer 70 reaches the final position. At the same time, the date hand wheel 67 turns one step clockwise. Furthermore, the date hand 7 linked to the date hand wheel 67 moves from a position indicating "30" of the last day to the position indicating "31".

[0121] Then, as in the case of a long month, in response to the movement of the hammer 70 from the final position to the initial position, the date hand wheel 67 turns instantaneously in the anti-clockwise direction. show. Consequently, the date hand 7 linked to the date hand wheel 67 moves instantaneously from the position indicating “31” of the last day to the position indicating “1” of the first day.

Furthermore, in the case of the 29 <th> day of the month of February of a leap year, the date hand wheel 67 rotates in a manner corresponding to the rotation of two steps of the date indicator 50 and of the date cam 61 by the end of month finger 53, so that the hammer 70 reaches the final position. At the same time, the date hand wheel 67 rotates two steps clockwise.

[0123] Furthermore, the date hand 7 linked to the date hand wheel 67 moves from the position indicating "29" of the last day of the month of February of a leap year to the position indicating "31". .

[0124] Then, as in the case of a long month, the date hand wheel 67 turns instantaneously counterclockwise in a manner corresponding to the movement of the hammer 70 from the final position to the initial position. Consequently, the date hand 7 linked to the date hand wheel 67 moves instantaneously from the position indicating “31” of the last day to the position indicating “1” of the first day.

Furthermore, in the case of the 28 <th> day of the month of February of a normal year, in the date hand wheel 67, in response to the rotation of three steps of the date indicator 50 and from the date cam 61 caused by the end of month finger 53, the hammer 70 reaches the final position. At the same time, the date hand wheel 67 rotates three steps clockwise. Furthermore, the date hand 7 linked to the date hand wheel 67 moves from the position indicating “28” of the last day of the month of February of a normal year to the position indicating “31”.

[0126] Then, as in the case of a long month, in response to the movement of the hammer 70 from the final position to the initial position, the date hand wheel 67 turns instantaneously in the anti-clockwise direction. show. Consequently, the date hand 7 linked to the date hand wheel 67 moves instantaneously from the position indicating “31” of the last day to the position indicating “1” of the first day.

As described above, according to the calendar mechanism 10 of the embodiment, on the last day of a long month, the date indicator 50 is pushed by the date finger 42 and it is turned one step. , thus causing the date hand 7 to be moved by an amount corresponding to one day. Further, according to the calendar mechanism 10, the last day of a short month other than February, if the month end finger 53 is pushed by the short month date advance finger 35 and the date indicator 50 turns one step, this date indicator 50 is pushed by the date finger 42 so as to turn another step, thus causing the date hand 7 to be moved by an amount corresponding to two days. Further, according to the calendar mechanism 10, on the last day of February in a leap year, if the month end finger 53 is pushed by the short month date advance finger 35 and the date 50 is turned by two steps, this date indicator 50 is pushed by the date finger 42 so as to turn another step, thus causing the date hand 7 to be moved by an amount corresponding to three days . Further, according to the calendar mechanism 10, on the last day of February of a normal year, if the month end finger 53 is pushed by the short month date advance finger 35 and the date 50 is turned by three steps, this date indicator 50 is pushed by the date finger 42 so as to turn another step, thus causing the date hand 7 to be moved by an amount corresponding to four days .

[0128] Further, when the date is changed from the last day of the month to the first day of the next month, the hammer 70 moves from the final position to the initial position, thereby causing the month advance finger 75 to push on the month indicator toothing 81 of the month indicator 80. Then if the month indicator toothing 81 is pushed by the month advancing finger 75 and rotates counterclockwise d At a predefined angle, the distal end 87 of the month jumper 86 and the month indicator toothing 81 temporarily disengage from each other and are again brought into engagement with each other. Consequently, the month indicator 80 and the month cam 27 rotate by a step of an angular value of 30°. Consequently, it is possible to rotate the month display disc 5 integral with the month indicator 80, and to unlock the month. Further, in this case, the positions of the projecting portions 27a to 27e of the month cam 27 and the year cam 28 are also changed. Consequently, the date advance finger for short month 35 can be moved according to whether it is a long month, a short month other than the month of February, the month of February of a year leap year and the month of February of a normal year.

The operation described above takes place repeatedly and thus allows the calendar mechanism 10 to perform a date advancement of the date indicator 50 by one day and an operation of the date hand 7 d one day on the last day of a long month, that the calendar mechanism 10 carries out a date advancement of the date indicator 50 by two days and an operation of the date hand 7 by two days on the last day of a short month other than the month of February, that the calendar mechanism 10 carries out a date advancement of the date indicator 50 by three days and an operation of the date hand by three days on the 29th day of the month of February of a leap year, that the calendar mechanism 10 carries out a date advancement of the date indicator 50 by four days and an operation of the date hand 7 by four days on the 28th day of the month of February of a normal year and that the calendar mechanism 10 carries out the display of the date. Further, the calendar mechanism 10 of the present embodiment performs month advancement and performs month display by rotating the month display disc 5 on the last day of the month.

As described in detail above, according to the present embodiment, it is possible to constitute the calendar mechanism 10 by employing a simple constitution comprising the date drive wheel for short month 25, the advance finger short month date indicator 35, as well as the date indicator 50 having the month end finger 53, without the need to use a complicated planetary gear mechanism as disclosed in the related prior art. Further, the short month date advance finger 35 pushes on the month end finger 53 the last day of a short month other than February among the short months, each of which has a lower number of days or equal to thirty days, to rotate the date indicator 50 through a first angle, and pushes the end of month finger 53 on the last day of the month of February of a leap year to rotate the date indicator 50 of a second angle larger than the first angle. Consequently, the number of days of the date adjustment carried out at the end of the month of February of a leap year may be greater than the number of days of the date adjustment carried out at the end of a short month other than the month from February. Further, the short month date advance finger 35 pushes the month end finger 53 on the last day of February of a normal year to rotate the date indicator 50 through a third greater angle than the second angle. Consequently, the number of days of the date catch-up carried out at the end of February of a normal year may be greater than the number of days of the date catch-up carried out at the end of February of a leap year . Consequently, it is possible to automatically carry out the date catch-up at the end of the month of February which is carried out manually in the related prior art both in the case of a normal year and in the case of a leap year . Further, the short month date advance finger 35 pushes the month end finger 53 on the last day of a short month to rotate the date indicator 50, so that the time at which the applied load on the cog driving the date drive wheel for short month 25 provided with the date advance finger for short month 35 is larger can exist only on the last day of the short months. Consequently, it is possible to propose a calendar mechanism 10 which can have a simple construction, which makes it possible to eliminate the application of a load on the gear train and which is able to automatically carry out the date catch-up at the end of the month of February even in both a normal year and a leap year.

Further, the calendar mechanism 10 includes the sliding contact finger 34 which is in sliding contact with the outer peripheral surface of the month cam 27 and with the outer peripheral surface of the year cam 28, as well as the short month date advance lever 30 which rotates around the month cam 27. The outer peripheral surface of the month cam 27 has several first projecting portions 27b to 27e corresponding to the short months other than February, as well as a second projecting portion 27a corresponding to the month of February. The outer peripheral surface of the cam of the years has the third protruding portion 28a, which, when viewed in the axial direction of the first axis C1, extends the second protruding portion 27a in February of a normal year and which, when 'we look in the axial direction of the first axis C1, is retracted from the position extending the second projecting portion 27a in February of a leap year, by the rotation of the cam of the years 28.

[0132] Depending on the configuration, when the sliding contact finger 34 of the date advance lever for short months 30 comes into sliding contact with any protruding portion among the first protruding portions 27b to 27e, the second portion projecting portion 27a and the third projecting portion 28a, it is possible to move the date advance lever for short month 30 with respect to a state in which the sliding contact finger 34 is not in sliding contact with any of the portions projecting. Since the second protruding portion 27a is larger than the first protruding portions 27b to 27e around the first axis C1 in the circumferential direction, the time during which the sliding contact finger 34 is in sliding contact with the second protruding portion 27a and during which the short month date advance lever 30 is so placed is longer than the duration during which the sliding contact finger 34 is in sliding contact with any of the first projecting portions 27b to 27e and month short month date advance lever 30 is thus otherwise positioned. in engagement with the month-end finger 53 on the last day of the month of February is longer than the period during which the date advance lever for the month cou rt 30 causes the short month date advance finger 35 to mesh with the month end finger 53 on the last day of a short month other than February.

In addition, when looking in the axial direction of the first axis C1, the third projecting portion 28a extends the second projecting portion 27a in February of a normal year and is set back from the position extending the second portion projecting 27a in February of a leap year. Therefore, the length of time that the short month date advance lever 30 is otherwise set in February of a normal year from the state in which the sliding contact finger 34 is not in sliding contact with any protruding portions is longer than that in February of a leap year. Thus, a period during which the short month date advance lever 30 allows the short month date advance finger 35 to be in mesh with the month end finger 53 on the last day of the month of February d a normal year is longer than the time during which the short month date advance lever 30 allows the short month date advance finger 35 to engage with the end of month finger 53 the last February day of a leap year.

As described above, the date advance finger for short month 35 can push the end of month finger 53 on the last day of the month of February of a leap year to rotate the date indicator 50 of the second angle greater than the first angle and the number of days of the date adjustment carried out at the end of the month of February of a leap year may be greater than the number of days of the date adjustment carried out at the end of a short month other than February. Further, the short month date advance finger 35 may push the month end finger 53 to rotate the date indicator 50 through a third angle greater than the second angle on the last day of February. of a normal year and the number of days of the date adjustment carried out at the end of the month of February of a normal year may be greater than the number of days of the date adjustment carried out at the end of the month of February of a leap year. Therefore, it is possible to provide a calendar mechanism 10 which can automatically perform date catch-up at the end of February even in both a normal year and a leap year.

[0135] In addition, in the calendar mechanism 10, the Maltese cross mechanism 90 intermittently rotates the cam of 28 years.

[0136] Consequently, it is possible to have a period during which the cam of the years 28 is stopped with respect to the cam of the months 27. Consequently, it is easy to position the cam of the years 28 in a rotating position. predefined at the end of February, compared to the case where the cam of the years runs continuously. Consequently, it is possible to reliably carry out the date catch-up at the end of the short months by means of a movement of the date advance lever for the short month 30 with a desired trajectory.

Further, the short month date drive wheel 25 is provided with the degree adjustment rod 37 defining the range over which the short month date advance lever 30 pivots. Therefore, for example , in a state where the short-month date advance lever 30 is on the side opposite the date indicator 50 with respect to the first axis C1, or the like, the range over which the date advance lever can pivot date for short month 30 is defined and it is possible to prevent the date advance lever for short month 30 from accidentally touching another component. Therefore, occurrence of problems in various mechanisms including the calendar mechanism 10 can be avoided.

[0138] Furthermore, the end of month finger 53 is formed so as to have the side surface 55a which comes into contact with the date advance finger for short month 35 to push back this date advance finger for short month. short month 35 rotating in synchronism with the short month date drive wheel 25, in a direction away from the end of month finger 53. Consequently, the short month date advance finger 35 can be pushed back in a direction away from the end of month finger 53. Consequently, it is possible to move away the date advance finger for short month 35 from the end of month finger 53 during long months without using a biasing element of the short month date advance finger 35 in the direction away from the month end finger 53. Therefore, the short month date advance finger 35 can prevent the date indicator 50 from being turned by a push on the month-end finger during long months. Therefore, it is possible to prevent a malfunction of the calendar mechanism 10.

In addition, the month indicator 80 rotates around the first axis C1 and the date indicator rotates around the second axis C2. Consequently, it is possible to freely arrange the date display means such as the month display disc 5 which is fixed to the month indicator 80 and the date hand 7 which is fixed to the indicator date 50, compared to the arrangement in which the month indicator and the date indicator are coaxial with each other. Therefore, it is possible to provide the calendar mechanism 10 which can have a simple constitution and which is excellent in degree of freedom for the arrangement of the month and date display.

[0140] According to the movement 100 and the timepiece 1 of the embodiment, there is provided the calendar mechanism 10 which can be constituted in a simple manner, which can avoid the application of a load on the gear train and which can automatically catch up with the date at the end of February even in both a normal year and a leap year. Therefore, it is possible to provide the movement 100 and the timepiece 1 which are excellent in reliability and convenience.

The present invention may adopt various examples of modification within its technical scope and is not limited to the embodiment described above with reference to the drawings.

[0142] For example, in the embodiment described above, the month cam 27 rotates one revolution in a year in synchronism with the month indicator 80, but the present invention is not limited to this mode. of achievement. For example, the month cam can be set to rotate one revolution in a whole number of years (two or more years) in sync with the month indicator. In this case, the outer peripheral surface of the month cam is provided with the first protruding portion and the second protruding portion by the number of years required for one revolution of the month cam and the year cam is disposed by the number of years required for a cam ride of months. Therefore, it is possible to obtain the same operation effects as with the calendar mechanism 10 described above.

[0143] Furthermore, in the embodiment described above, the cam of years 28 is configured to turn one revolution in four years. However, it is not limited to this. The years cam can be configured to rotate one revolution in a number of years equal to a multiple of four.

[0144] Furthermore, in the embodiment described above, the third projecting portion 28a is arranged downstream of the second projecting portion 27a of the month cam 27 clockwise around the first axis C1 when looking at the axial direction of the first axis C1. However, it is not limited to this. The third protruding portion can be arranged upstream of the second protruding portion of the month cam in a clockwise direction around the first axis C1 when viewed in the axial direction of the first axis C1.

[0145] Furthermore, in the embodiment described above, the Maltese cross mechanism 90 includes the finger wheel 91 and the cam Maltese cross of the years 95. However, the constitution of the Maltese cross mechanism does not is not particularly limited. For example, the Maltese cross mechanism may comprise teeth linked to the cam of the years, a jumper which defines the rotational position of the teeth, an advancement finger which causes the teeth to rotate by one step in conjunction with the revolving movement of the teeth.

[0146] Further, in the embodiment described above, the 28s cam is configured to rotate intermittently by the Maltese cross mechanism 90. However, the 28s cam can be configured to rotate continuously. .

Furthermore, in the embodiment described above, the calendar mechanism 10 is configured in such a way that the month cam 27, the date drive wheel for short month 25 and the date advance finger date for short month 35 rotate around the first axis C1 and the date indicator drive wheel 40 and the date finger 42 rotate around an axis different from the first axis C1. However, the present invention is not limited to this embodiment and the month cam, the date drive wheel for short month, the date indicator drive wheel, the date advance finger for short month and the date finger can rotate around the first axis C1 by providing that the month cam, the date drive wheel for short month and the date indicator drive wheel are coaxial. Therefore, the size of the calendar mechanism can be reduced.

In addition, in the embodiment described above, the date hand 7 is linked to the date hand wheel 67 and is intended to go back and forth, but the present invention does not is not limited to this embodiment. For example, the date hand can be attached to the date indicator and actuated to rotate.

[0149] The embodiment uses return wheel 78 which includes spiral spring 79 as a biasing member to bias hammer 70 toward month indicator 80, but is not limited thereto. Therefore, for example, a coil spring may be employed as an element to bias the hammer 70.

[0150] Further, the embodiment uses the month display disc 5 as the month display means, but it is not limited thereto. For example, as a means of displaying the months, one can adopt an arrangement in which the characters indicating the months are present on the dial 2 and the indication is made by a month hand. Furthermore, in the embodiment described above, as the date display means, the date hands 7 and 7B are adopted, but not limited thereto. For example, as date display means, an arrangement can be adopted in which characters indicating the days are present on a day display disc and characters designating a day are visible through a date window.

[0151] Further, the constituent elements of the embodiment described above may be suitably replaced by constituent elements known within the scope not departing from the concept of the present invention.

Claims (7)

1. Calendar mechanism including: a short-month date drive wheel (25) which is designed to rotate one revolution in one day around a predefined axis (C1); a date indicator (50) which has an end-of-month finger (53) and which rotates one revolution in a month; And a short month date advancing finger (35) carried by the short month date drive wheel (25), which rotates in synchronism with the short month date drive wheel (25) while being movable, which pushes the month-end finger (53) so as to rotate the date indicator (50) through a first angle on the last day of a short month other than the month of February among the short months in each of which the number of days is less than or equal to 30 days, which pushes the end-of-month finger (53) so as to cause the date indicator (50) to rotate through a second angle greater than the first angle last day of the month of February of a leap year and which pushes the end of month finger (53) so as to rotate the date indicator (50) by a third angle greater than the second angle on the last day February of a normal year. 2. Calendar mechanism according to claim 1, further comprising: a month cam (27) which is coaxial with the short month date drive wheel (25) and which rotates one revolution in a year; a year cam (28) which is carried by the month cam (27) so as to be rotatable; a drive mechanism (90) which is adapted to rotate the year cam (28) relative to the month cam (27); And a short month date advance lever (30) which includes a sliding contact portion (34) coming into sliding contact with an outer peripheral surface of the month cam (27) and an outer peripheral surface of the year cam (28), and which is provided to be rotatable with respect to the short month date drive wheel (25) and to rotate around the month cam (27) in synchronism with the calendar for short month (25), wherein the outer peripheral surface of the month cam (27) comprises: several first projecting portions (27b, 27c, 27d, 27e) which each correspond to a month among the short months other than the month of February, and a second projecting portion (27a) which corresponds to the month of February and which is larger than the first projecting portions (27b, 27c, 27d, 27e) in a circumferential direction around the predefined axis (C1), wherein the outer peripheral surface of the years cam (28) includes a third protruding portion (28a), where, when looking in the axial direction of the predefined axis, the third protruding portion (28a) prolongs the second protruding portion (27a) in February of a normal year and is moved back out of the position prolonging the second projecting portion (27a) in February of a leap year, due to the rotation of the year cam (28) by the drive mechanism (90), wherein the short month date advance lever (30) comprises the short month date advance finger (35), and wherein the short month date advance lever (30) is adapted to bring the short month date advance finger (35) into engagement with the month end finger (53), being in contact sliding with the first projecting portions (27b, 27c, 27d, 27e) on the last day of a month among the short months other than the month of February, to bring the date advance finger for the short month (35) to to be engaged with the month-end finger (53), being in sliding contact with the second projecting portion (27a) on the last day of the month of February of a leap year and to bring the date advance finger for short month (35) to be in engagement with the month-end finger (53), being in sliding contact with the second protruding portion (27a) and the third protruding portion (28a) on the last day of the month of February of a normal year. 3. Calendar mechanism according to claim 2, wherein the drive mechanism (90) is adapted to rotate the years cam (28) intermittently. 4. Calendar mechanism according to one of claims 1 to 3, wherein the short month date drive wheel (25) includes a degree adjustment rod (37) which is adapted to adjust the pivoting range of the short month date advance lever (30). 5. Calendar mechanism according to one of claims 1 to 4, wherein the month end finger (53) includes a push portion (55a) which comes into contact with the short month date advance finger (35) to push back, in a direction away from the end of month (53), the date advance finger for short month (35), when the date advance finger for short month (35) rotates in synchronism with the date drive wheel for short month ( 25). 6. Movement including: a calendar mechanism (10) according to one of claims 1 to 5. 7. Timepiece including: a movement (100) according to claim 6.