JP2014115197A - Timepiece calendar mechanism, movement provided with the mechanism, and calendar timepiece - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a timepiece calender mechanism, a movement provided with the calender mechanism, and a calendar timepiece provided with the mechanism capable of coaxially stably performing a fan-shaped display.SOLUTION: A timepiece calendar mechanism 1 of a movement 2 of a calendar timepiece 3 includes: a first calendar information display needle 87A for displaying a first calendar information per day in a first fan-shaped display area; a second calendar information display needle 87B for displaying a second calendar information per day in a second fan-shaped display area coaxial with the first fan-shaped display area; a first calendar information display shaft 81a rotatable around a first fan-shaped center shaft line B to which a tip end of the first calendar information display needle is attached; a second calendar information display shaft 81B whose tip end is attached with the second calendar information display needle and coaxial with the first calendar information display needle, and rotatable around the center shaft line B; and a center pipe 70 positioned between the first and the second calendar information display shafts 81A, 81B and allowed to be left at rest against a bottom board.

Description

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

  A calendar mechanism is well known in a timepiece, and a calendar mechanism that displays calendar information such as day of the week and day of the week in a fan-shaped display area is also known (for example, Patent Document 1 and Patent Document 2). ). In the fan-shaped display area, the time information display pointer is in one direction along the fan shape from the initial position of one end of the fan shape (position indicating the initial value) to the final position of the other end of the fan shape (position indicating the final value). After the hand is moved, it is configured to instantaneously return in the opposite direction from the final position (position representing the final value) to the initial position (position representing the initial value). In this specification, such display and display mechanism are also referred to as “retrograde display mechanism” and “retrograde display mechanism”, respectively.

  In addition, when displaying the date in a sector shape, it has been proposed to display the 1 digit and the 10 digit with separate display hands and to display the 1 digit display hand and the 10 digit display hand concentrically. (Patent Document 3).

  However, in the calendar mechanism of Patent Document 3, since the axis of the 1-digit display hand is in sliding contact with the cylindrical shaft of the 10-digit display hand, the 1-digit display hand is the maximum value or maximum swing of the fan. When returning from a position (for example, 0 position) to an initial value or an initial position (for example, 1 position) rapidly in a so-called retrograde manner, or when the 10-digit day hand is at the maximum value or maximum swing position of the fan (for example, 3 position) When quickly returning from the initial value to the initial position (for example, 0 position) in retrograde manner, high-speed sliding occurs between the axis of the 1-digit day indicator hand and the cylindrical axis of the 10-digit indicator hand, There is a possibility that the display torque becomes unstable due to a fluctuation in the other display needle and its display wheel train due to the rotational torque caused by the friction caused by the sliding.

JP-A-10-186061 Japanese Patent Laid-Open No. 11-6880 JP 2011-128027 A

  The present invention has been made in view of the above-described points, and provides a timepiece calendar mechanism capable of stably performing a fan-shaped display, and a movement and a calendar timepiece including the mechanism.

In order to achieve the above object, the timepiece calendar mechanism of the present invention has a first calendar information display hand for displaying the first calendar information in the display area of the first sector, and a second calendar information concentric with the first sector. A second calendar information display needle for displaying in a second sector-shaped display area; and a first calendar information display axis attached to the tip of the first calendar information display needle and rotatable about the central axis of the first sector. The second calendar information display needle is attached to the tip, the second calendar information display shaft is concentric with the first calendar information display needle and rotatable about the central axis, and the first and second calendars. And a vibration suppression member (center pipe) that is positioned between the information display shafts and placed stationary with respect to the ground plane.
In the timepiece calendar mechanism of the present invention, when one of the first calendar information display hand and the second calendar information display hand has a second angle larger than the first angle, The needle control mechanism for returning the needle to the first angle and the vibration suppressing unit suppress vibration generated when the one needle returns from the second angle to the first angle.

  In the timepiece calendar mechanism of the present invention, “a first calendar information display hand is attached to the tip portion and is rotatable around the central axis of the first sector, and the second calendar information display hand is at the tip. In addition to the “second calendar information display shaft that is concentric with the first calendar information display needle and is rotatable about the central axis”, the position between the first and second calendar information display shafts Since the center pipe stationary with respect to the ground plane is provided, the central pipe positioned between the first and second calendar information display axes and stationary with respect to the ground plane is displayed as the first calendar information. Since the shaft and the second calendar information display axis are separated from each other, it is possible to prevent the first and second calendar information display axes from sliding on each other and transmitting torque and the like between them, so that the fan-shaped display can be performed stably. I can. Further, when the first or second calendar information display axis rapidly returns retrogradely from the final position or maximum swing position of the fan to the initial position of the fan, the first or second calendar information display axis is rotated along with the rotation of the first or second calendar information display axis. Since there is no possibility that the rotational torque is transmitted to the second or first calendar information display shaft, there is little possibility that the second calendar information display shaft will fluctuate due to the friction torque when returning to the initial position. Therefore, in the timepiece calendar mechanism of the present invention, the fan-shaped display can be performed stably. Further, in the timepiece calendar mechanism of the present invention, the fan-shaped display is performed concentrically, so that the space occupied by the display area can be minimized. In the above, the first and second calendar information is typically information on a daily basis. However, it may be calendar information other than daily units.

  The timepiece calendar mechanism of the present invention typically includes a first calendar information small gear integral with the first calendar information display shaft, and a first calendar information operating cam that is rotated in one direction. The first calendar information cam surface has a shape in which the radius gradually increases from the minimum diameter to the maximum diameter and decreases rapidly from the maximum diameter to the above-mentioned small diameter, and the first calendar information cam surface. A first calendar information cam follower to be engaged at one end, and a first calendar information hammer having a first calendar information gear portion meshing with the first calendar information small gear on one side; and the second calendar A second calendar information small gear integral with the information display shaft, and a second calendar information operating cam rotated in one direction, the radius gradually increasing from the minimum diameter to the maximum diameter as it rotates. And a second calendar information cam follower that engages the second calendar information cam surface at one end, and a second calendar information cam follower that engages with the second calendar information cam surface. A second calendar information hammer is provided on one side with a second calendar information gear portion meshing with the second calendar information small gear.

  In the timepiece calendar mechanism of the present invention, typically, the first calendar information hammer and the second calendar information hammer are arranged concentrically.

  In that case, it is possible to minimize the area occupied by the calendar mechanism.

  However, if desired, the rotation center axis of the first calendar information hammer can be different from the rotation center axis of the second calendar information hammer.

  In that case, the degree of freedom of the shape and structure of the related parts is increased, and restrictions on the shape of the calendar information operating cam are reduced, so the versatility of the parts is increased.

  In the timepiece calendar mechanism of the present invention, typically, the first calendar information operating cam and the second calendar information operating cam are arranged concentrically.

  In that case, it is possible to minimize the area occupied by the calendar mechanism. However, if desired, the rotation center of the first calendar information operating cam and the rotation center of the second calendar information operating cam may be arranged at different positions.

  In the timepiece calendar mechanism of the present invention, typically, the first calendar information rotating cam integrated with the first calendar information operating cam and the second calendar information rotating transmission integrated with the second calendar information operating cam are typical. A first calendar information turning claw for turning the first calendar information turning transmission wheel and a second calendar information turning claw for turning the second calendar information turning transmission wheel are concentrically provided.

  In that case, the space occupied by the calendar mechanism can be further reduced.

  In the timepiece calendar mechanism according to the present invention, the element parts or element mechanisms (for example, the first and second calendar information turning wheels and the claw, The first and second calendar information turning transmission wheels, the first and second calendar information operating cams, the first and second calendar information hammers, etc.) are arranged concentrically on both sides of the stationary plate (for example, the small date wheel receiver). Is done. In this case, it is possible to minimize the occupied space while avoiding complexity.

  In the timepiece calendar mechanism of the present invention, typically, the first calendar information is the day and the second calendar information is the day of the week.

  In that case, the date and day of the week can be displayed in retrograde with the space occupied by the calendar mechanism minimized.

  In the timepiece calendar mechanism of the present invention, typically, the second sector-shaped display area is within the range of the first sector-shaped display area.

  In that case, an easy-to-see display can be performed in a state where the space occupied by the calendar mechanism is minimized. However, if desired, even if the second fan-shaped display area and the first fan-shaped display area partially overlap and two fan-shaped display areas partially deviate from each other, The two fan-shaped display area and the first fan-shaped display area may be in different areas without overlapping each other.

  Further, the movement of the present invention has the timepiece calendar mechanism as described above in order to achieve the above object.

  Further, the calendar timepiece of the present invention has the timepiece calendar mechanism as described above in order to achieve the above object.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory plan view of a calendar timepiece having a movement according to a preferred embodiment of the present invention. FIG. 2 is an explanatory plan view showing the appearance of the calendar timepiece of FIG. 1. Sectional explanatory drawing of the calendar timepiece of FIG. The plane explanatory view which showed the daily change from the 1st to the 31st in the retrograde type date display mechanism among the calendar mechanisms of the calendar timepiece of FIG. Plane explanatory drawing which showed the daily change from the 31st to the 1st in the retrograde type date display mechanism of FIG. FIG. 3 is an explanatory plan view showing the day change from Sunday (SUN) to Saturday (SAT) in the retrograde day display mechanism of the calendar mechanism of the calendar watch of FIG. 1. FIG. 7 is an explanatory plan view showing a day change from Saturday (SAT) to Sunday (SUN) in the retrograde day display mechanism of FIG. 6. The plane explanatory view of the calendar timepiece of the 1st modification of the present invention which has the movement of the 1st modification of the present invention provided with the calendar mechanism of the 1st modification of the present invention.

  Next, a preferred embodiment of the present invention will be described based on a preferred example shown in the accompanying drawings.

  A calendar timepiece 3 having a timepiece movement 2 provided with a timepiece calendar mechanism 1 according to a preferred embodiment of the present invention is arranged around a central axis C as shown in the external view of FIG. An hour hand 21, a minute hand 22 and a second hand 23 are provided to rotate in the C1 direction. An hour wheel or hour wheel 24 provided with the hour hand 21 at the tip of the large-diameter cylindrical portion 24a, a minute wheel 26 provided with the minute hand 22 at the tip of the cylindrical pinion 25, and a second hand 23 provided at the tip of the fourth stem 27a. The second wheel 27 is rotatably supported around the central axis C by a stationary support substrate in the form of a train wheel bridge such as the main plate 4, the second receiver 5, and the first receiver 6. The minute gear 26a of the minute wheel 26 is meshed with a barrel wheel (not shown), the cylindrical gear 24b of the hour wheel 24 is meshed with the hour pinion 25 of the minute wheel 26 via the minute wheel 28, and the second wheel 27 is It is meshed with the minute wheel 26 via a third wheel (not shown). The second wheel 27 is meshed with a true gear 29a of a escape wheel 29 that forms a governor escapement together with an ankle (not shown) and a balance with a balance (not shown) by a second gear 27b. It should be noted that the above-mentioned wheel train 20 including the vehicles 24, 26, 27, 28 and the like may be different from the illustrated train wheel. 11 is a dial, 12 is a back cover, 13 is a case, 14 is a crown, and 15 is a band.

  Next, the calendar mechanism 1 including the retrograde day display mechanism 1A as a day display mechanism for performing sector display and the retrograde day display mechanism 1B as a day display mechanism for performing sector display will be described.

  In the illustrated example, the movement 2 is a stationary support substrate, in addition to the base plate 4, the second receiver 5, and the first receiver 6, a second base plate 7 that extends along the dial side surface of the base plate 4, and a dial plate 11. The second wheel train receiver 8 extending along the inner surface of the vehicle and the small date wheel receiver 9 positioned between the second main plate 7 and the second wheel train receiver 8 are provided.

  The calendar mechanism 1 includes a sun-turning intermediate wheel 24c that rotates around the central axis C in the direction C1. The calendar mechanism 1 also includes a sun-turn wheel central shaft 31 extending in the thickness direction A of the timepiece 3 along the central axis D, and an operation extending in the thickness direction A of the timepiece 3 along the central axis E. A cam central shaft 34, a hammer lever central shaft 37 extending in the thickness direction A of the timepiece 3 along the central axis F, and a central pipe extending in the thickness direction A of the timepiece 3 along the central axis B 70 (an example of the vibration suppressing member of the present application).

  The Sunday turning intermediate wheel 24c is fitted to the hour wheel 24 and rotates around the central axis C in the C1 direction in 12 hours.

The Sunday turning wheel central shaft 31 is fitted into the corresponding hole 7a of the second main plate 7 at the large diameter portion 31a on one end side, passes through the outside of the extension area of the small date wheel support 9, and has a small diameter on the other end side. The portion 31b is fitted into the corresponding hole 8a of the second train wheel bridge 8. The operating cam central shaft 34 is fitted into the corresponding hole 7b of the second base plate 7 at the large-diameter portion 34a on one end side, and is loosely fitted into the corresponding hole 9b of the small date holder 9 so as to pass through the hole 9b. Then, the small diameter portion 34b on the other end side is fitted into the corresponding hole portion 8b of the second train wheel bridge 8. Similarly, the hammer center shaft 37 is fitted into the corresponding hole 7c of the second base plate 7 at the large-diameter portion 37a on one end side, and is loosely fitted into the corresponding hole 9c of the small date holder 9 so that the hole The portion 9c penetrates and is fitted into the corresponding hole portion 8c of the second train wheel bridge 8 by the small diameter portion 37c on the other end side.
The center pipe 70 is a pipe-shaped member having a hollow portion, and is fitted into the corresponding hole 9d of the small date wheel receiver 9 at the large-diameter portion 71 at one end and connected to one end of the large-diameter portion 71. The portion 72 is in contact with the dial-side surface 9e of the small date wheel receiver 9 on the peripheral wall of the hole 9d.

  A Sunday turning wheel 40 is fitted to the Sunday turning wheel central shaft 31 by a hub portion 41 so as to be rotatable. The Sunday turning wheel 40 includes a Sunday turning gear 42 fitted to the hub portion 41. The Sunday turning gear 42 is meshed with the intermediate turning wheel 24c on the Sunday, according to the rotation of the intermediate turning wheel 24c in the C1 direction. Rotate in the direction D1 around the central axis D in 24 hours. A sun-rotating claw 45A is fitted in the central hole 46A at the end of the hub portion 41 of the sun-rotating wheel 40 on the second train wheel bridge 8 side, and is rotated around the end of the second base plate 7 side. A claw 45B is fitted into the central hole 46B.

A hub portion 51A such as a date operating cam is rotatably fitted around the central axis E in a portion 34A between the second wheel train receiver 8 and the small date wheel receiver 9 of the operating cam central shaft 34. A date turning transmission wheel 52A and a date operation cam 53A as a first calendar information operation cam are fitted to the hub portion 51A at the center hole. The date turning transmission wheel 52A includes a number of claw portions or tooth portions (for example, 31 teeth (31 teeth)). Each time the date turning claw 45A is rotated around the central axis D, the tooth is rotated in the E1 direction by two teeth, and the day operating cam 53A is intermittently rotated in the E1 direction by one day in accordance with the intermittent rotation. The
Incidentally, the day operating cam 53A has a central axis E (the first calendar of the present application) from the minimum diameter portion 55A to the maximum diameter portion 56A in which the diameter of the cam surface portion that works effectively in the day operation cam 53A according to the rotation in the E1 direction. An example of the rotation center of the information actuating cam is provided with a snail-like or spiral-shaped cam surface 54A that expands (increases gradually) in the outer circumferential direction, and after reaching the maximum diameter portion 56A, a transition portion or step portion 57A. Through this, it falls (returns) to the minimum diameter portion 55A, enabling so-called fan-shaped display or retrograde display.
In other words, the day operating cam 53A includes a cam surface 54A that expands from the minimum diameter portion 55A in the outer circumferential direction of the central axis E to the maximum diameter portion 56A in the direction away from the central axis E, and the maximum diameter portion 56A. It includes a first calendar information cam surface (an example of the first calendar information cam surface of the present application) in which a stepped portion 57A connecting the minimum diameter portion 55A is formed.
Although the cam surface 54A will be described in detail later, in the fan-shaped small day display area 89A, a diameter difference divided by 31 is provided in order for the date hand 87A to display the date of 1-31 days every day. It has been.
Note that the rotation of the date turning transmission wheel 52A is greatly controlled by the date jumper 58A.

A hub portion 51B such as a day operating cam is rotatably fitted around the central axis E in a portion 34B between the small date indicator 9 and the second base plate 7 of the operating cam central shaft 34, and the hub portion 51B is fitted with a day driving wheel 52B and a day operating cam 53B as a second calendar information operating cam at the central hole. The day-turning transmission wheel 52B includes a plurality of claw portions or tooth portions (for example, 7 teeth, 14 teeth, or 21 teeth). Each time the day-turning claw 45B is rotated around the central axis D, it is rotated in the E1 direction by two teeth, and the day operation cam 53B is intermittently rotated in the E1 direction by one day according to the intermittent rotation. Is done.
The day operating cam 53B also has a center axis E (second calender of the present application) from the minimum diameter portion 55B to the maximum diameter portion 56B of the cam surface portion that works effectively in the day operation cam 53B according to the rotation in the E1 direction. An example of the rotation center of the information actuating cam is provided with a snail-like or spiral-shaped cam surface 54B that expands (increases gradually) in the outer circumferential direction, and after reaching the maximum diameter portion 56B, a transition portion or step portion 57B. This causes a drop (return) to the minimum diameter portion 55B via a so-called fan-shaped display or retrograde display.
In other words, the day operating cam 53B includes a cam surface 54B that expands from the minimum diameter portion 55B in the outer circumferential direction of the center axis E to the maximum diameter portion 56B in the direction away from the center axis E, and the maximum diameter portion 56B. A second calendar information cam surface (an example of the second calendar information cam surface of the present application) on which a stepped portion 57B that connects the minimum diameter portion 55B is formed.
The rotation of the day-turning transmission wheel 52B is greatly controlled by the day jumper 58B.

  A date hammer lever hub portion 61A is rotatably fitted around the central axis F in a portion 37A between the second wheel train receiver 8 and the small date wheel receiver 9 in the hammer center shaft 37. A date hammer 62A is fitted to the hub 61A at the center hole. The date hammer 62A is pivoted about the center axis F in response to the swing of the date hammer main body 64A and the lever main body 64A, the tip of which serves as a cam follower 63A for the date operating cam 53A. And an arcuate gear portion 65A as a calendar information gear portion.

  On the portion 37B between the small date indicator 9 and the second base plate 7 of the hammer center shaft 37, a day hammer lever hub portion 61B is fitted around the central axis F so as to be rotatable. 61B is fitted with a day hammer 62B at the center hole. The day hammer hand 62B is rotated around the central axis F in response to the swing of the day hammer hand main body portion 64B and the lever main body portion 64B, the tip portion of which serves as a cam follower 63B with respect to the day operation cam 53B. And an arcuate gear portion 65B as a calendar information gear portion.

  A large-diameter cylindrical small date shaft 81A as a first calendar information display shaft extending along the central axis B is rotatably fitted to the central pipe 70 on the outside of the cylindrical main body 73 of the central pipe 70. A small-diameter small day shaft 81B as a second calendar information display shaft extending along the central axis B is rotatably fitted to the central pipe 70 inside the cylindrical main body 73 of the central pipe 70. . The small diameter small day shaft 81B is rotatably fitted in the hole 7d of the second base plate 7 at the base end portion 82B, and the protruding end of the base end portion 82B is loosely fitted in the hole 4a of the base plate 4. The large-diameter cylindrical small date shaft 81 </ b> A is rotatably supported by the bearing portion 8 d of the second train wheel bridge 8, and protrudes from the dial 11 through the bearing portion 8 d.

  A small date gear 84A is fitted or integrally formed on a base end portion 82A located on the small date indicator 9 side of the large-diameter cylindrical small date shaft 81A, that is, on the flange-shaped portion 72 side of the center pipe 70. . Similarly, a small day gear 84B is fitted or integrally formed in a portion 83B of the small diameter small day shaft 81B located on the small date indicator 9 side, that is, on the flange-like portion 72 side of the center pipe 70. The small date wheel 85A includes a large-diameter cylindrical small date shaft 81A and a small date gear 84A integrated with the shaft 81A. On the other hand, the small day wheel 85B includes a small-diameter small day shaft 81B and a small day gear 84B integrated with the shaft 81B.

  A date hand 87A as a first calendar information display hand is attached to the protruding end portion 86A on the dial plate 11 side of the large-diameter cylindrical small date shaft 81A, and a protruding end portion 86B on the dial plate 11 side of the small-diameter small day shaft 81B. Is attached with a day hand 87B as a second calendar information display hand.

  On the surface of the dial 11, a large-diameter fan-shaped small day display area 89A as a first fan-shaped display area centered on the central axis B and a second fan-shaped display area centered on the central axis B are provided. A small-diameter fan-shaped small day display area 89B is formed. The small day display area 89A displays the “date” from the initial value “1” day to the final value “31” day as a fan-shaped area, and the small day display area 89B displays the initial value “Sunday ( “SUN)” day to the final value “Saturday (SAT)” day “Day”, that is, “Day of the week” is displayed in a fan-shaped area.

  A small date indicator spring 88A is attached to the large-diameter cylindrical small date shaft 81A. The small date wheel spring 88A exerts a rotational biasing force on the shaft 81A so that the large-diameter cylindrical small date shaft 81A is rotationally biased in the B2 direction and the date hand 87A is set to an initial position indicating "1" day. Thus, the cam follower 63A of the date hammer 62A is pressed against the cam surface 54A of the date operating cam 53A. Similarly, a small day indicator spring 88B is attached to the small diameter small day shaft 81B. The small day wheel spring 88B exerts a rotational biasing force on the shaft 81B so that the small diameter small day shaft 81B is rotationally biased in the B2 direction and the day hand 87B is set to an initial position indicating “Sunday (SUN)”. As a result, the cam follower 63B of the day hammering lever 62B is pressed against the cam surface 54B of the day operating cam 53B.

  Next, the operation of the retrograde date display mechanism 1A and the retrograde day display mechanism 1B constituting the calendar mechanism 1 of the movement 2 of the timepiece 3 configured as described above will be described in detail with reference to FIGS.

  4 and 5 show a part of the retrograde date display mechanism 1A in the calendar mechanism 1. In FIG. 4, the sector-shaped small day display area from the "1" day to the "31" day is shown. 89A shows a state in which the date hand 87A rotates intermittently in the B1 direction every day. In the example shown in FIG. 4, the date hand 87 </ b> A indicates an angle indicating “1” day of the fan-shaped small day display area 89 </ b> A as an example of the first angle of the present application. In the example illustrated in FIG. 5, the date hand 87 </ b> A indicates the angle indicating “31” day of the fan-shaped small day display area 89 </ b> A as an example of the second angle of the present application.

  More specifically, as can be seen from FIG. 4, as the intermediate wheel 24 </ b> C, which is integrated with the hour wheel 24, rotates continuously in the direction C <b> 1 around the central axis C at a rotational speed of 2 revolutions / day, The Sunday turning wheel 40 having the Sunday turning gear 42 meshed with the Sunday turning intermediate wheel 24C is rotated continuously in the direction D1 around the central axis D at a rotation speed of 1 rotation / day. A date indicator claw that is integrated with the Sunday indicator wheel 42 and close to the dial plate 11 and close to the dial plate 11 (the dial plate 11 side of the small date holder 9) as the sun indicator wheel 40 rotates in the direction D1. 45A also rotates in the D1 direction, and the date turning claw 45A engages with the closest tooth of the gear of the date turning transmission wheel 52A only once a day to center the date turning transmission wheel 52A by one tooth. It is intermittently rotated around the axis E in the E1 direction. Since the date turning transmission wheel 52A is greatly controlled by the date jumper 58A, after intermittent feeding of one tooth, the date jumper 58A regulates the gear portion of the date turning transmission wheel 52A and stops at a predetermined intermittent rotation position. Let In addition, since the date turning transmission wheel 52A has a gear portion having 31 teeth so as to rotate once in 31 days, the diameter thereof includes 7 teeth so as to rotate once in one week (7 days). The day-turning wheel 45A has a larger diameter than the day-turning transmission wheel 52B having a gear portion, and accordingly, the date-turning claw 45A has a smaller diameter than the concentric day-turning claw 45B.

  As the date indicator driving wheel 52A is intermittently rotated in the E1 direction from one intermittent rotation position defined by the date jumper 58A to the next intermittent rotation position, the date operation integrated with the date indicator driving wheel 52A is integrated. The cam 53A is also intermittently rotated around the central axis E in the E1 direction, and is pressed against the spiral cam surface 54A of the date operating cam 53A by the cam follower 63A under the action of the small date indicator spring 88A. Is rotated or swung around the central axis F in the direction F1. That is, when the day changes from 1st to 31st, the radius of the effective cam surface portion with which the cam follower 63A comes into contact with the cam surface 54A gradually increases, so that the date hammer 62A is rotated in the E1 direction. Will be. As shown in FIG. 4, on the “1” day, the cam follower 63A is in contact with the minimum diameter portion 55A of the cam surface 64A.

  In response to the F1 direction rotation of the date hammer 62A, the arcuate gear portion 65A of the date hammer 62A is rotated in the F1 direction around the central axis F, and the small date gear 84A is moved to the gear portion 65A. The small date wheel 85A meshed with is intermittently rotated around the central axis B in the B1 direction for one day. Accordingly, the date hand 87A attached to the protruding end 86A of the large-diameter cylindrical small date shaft 81A of the small date indicator 85A is rotated in the B1 direction by one day in the fan-shaped small date display area 89A.

  The above operation is repeated from the “1” day to the “31” day, and the radial position of the portion of the cam surface 54A of the day operating cam 53A that the cam follower 63A of the date hammer 62A contacts is increased. Accordingly, the date hammer 62A is intermittently rotated in the F1 direction, and accordingly, the date hand 87A is intermittently rotated in the B1 direction.

  When the day changes from the 31st to the 1st, as shown in FIG. 5, the cam follower 63A of the date hammer 62A is positioned in the vicinity of the maximum diameter portion 56A of the cam surface 54A of the day operating cam 53A. In the state where the date hand 87A is at the position of the 31st day on the right end of the fan-shaped small day display area 89A, the sun turning wheel 45A of the turning wheel 40 in the direction of C1 of the intermediate wheel 24C rotates in the direction D1. It rotates and engages with the tooth portion of the date turning transmission wheel 52A to rotate the date turning transmission wheel 52A in the E1 direction by one tooth. In response, the cam follower 63A of the date hammer 62A under the action of the elastic biasing force of the small date indicator spring 88A causes the maximum diameter portion 56A of the cam surface 54A of the date operating cam 53A to rotate in the E1 direction. As a result, the hour hand lever 62A is pivoted in the F2 direction at a time while dropping to the minimum diameter portion 55A along the transition portion or step portion 57A. Accordingly, the small date wheel 85A meshed with the arcuate gear portion 65A of the date hammer 62A by the small date wheel 84A is suddenly rotated in the B2 direction, and the date hand 87A is at the initial position from the position of the "31" day. It is rotated at a stretch in the B2 direction to the position of “1” day. That is, the calendar mechanism 1 also functions as a needle control mechanism of the present application, and when the angle of the date hand 87A as an example of the first calendar information display needle becomes a second angle larger than the first angle, The needle is returned to the first angle. Thereby, the daily change from the 31st to the 1st is completed.

  6 and 7 show the part of the retrograde day display mechanism 1B in the calendar mechanism 1 as in FIGS. 4 and 5 relating to the retrograde day display mechanism 1A. In FIG. In the fan-shaped small day display area 89B from SUN) to Saturday (SAT), a state is shown in which the day hand 87B rotates intermittently in the B1 direction every day.

  More specifically, as can be seen from FIG. 6, the Sunday turning wheel 40 rotates substantially continuously around the central axis D in the direction D1 in response to the substantially continuous turning of the intermediate wheel 24C in the C1 direction. Accordingly, the day-turning claw 45B that is integrated with the Sunday-turning gear 42 and is located in the vicinity of the second main plate 7 provided in the direction of the back cover 12 (the back cover 12 side of the small date wheel receiver 9) is in the D1 direction. And the day-turning claw 45B engages with the closest tooth of the gear wheel of the transmission wheel 52B only once a day so that the day-turning wheel 52B is rotated about the central axis E by one tooth. To intermittently rotate in the E1 direction. Since the day turning wheel 52B is greatly controlled by the day jumper 58B, after intermittent feeding of one tooth, the day jumper 58B sets the gear portion of the day turning wheel 52B and stops at a predetermined intermittent rotation position. Let Since the day-turning transmission wheel 52B has a gear portion having 14 teeth so as to make one rotation in one week (7 days), the diameter thereof has 31 teeth so as to make one rotation in 31 days. Accordingly, the day turning claw 45B has a smaller diameter than the concentric day turning claw 45A. The day-turning transmission wheel 52B may be provided with seven teeth.

  As the day-turning wheel 52B is intermittently rotated in the E1 direction from one intermittent rotation position defined by the day jumper 58B to the next intermittent rotation position, the day-of-week operation integrated with the day-turning wheel 52B is integrated. The cam 53B is also intermittently rotated in the direction E1 around the central axis E, and the day hammering lever 62B is pressed against the spiral cam surface 54B of the day operating cam 53B by the cam follower 63B under the action of the small day indicator spring 88B. Is rotated or swung around the central axis F in the direction F1. That is, when changing from Sunday (SUN) to Saturday (SAT), the radius of the effective cam surface portion with which the cam follower 63B contacts the cam surface 54B gradually increases. It is rotated in the E1 direction. As shown in FIG. 6, on Sunday (SUN), the cam follower 63B is in contact with the minimum diameter portion 55B of the cam surface 64B.

  In response to the F1 direction rotation of the day hammer 62B, the arcuate gear portion 65B of the day hammer 62B is rotated in the F1 direction around the central axis F, and the small day gear 84B is moved to the gear portion 65B. The small day wheel 85 </ b> B meshed with is intermittently rotated in the B <b> 1 direction around the central axis B for one day. Accordingly, the day hand 87B attached to the protruding end 86B of the small-diameter small day shaft 81B of the small day wheel 85B is rotated in the B1 direction by one day in the fan-shaped small day display area 89B.

  The operation as described above is repeated from Sunday (SUN) to Saturday (SAT), and the radial position of the portion of the cam surface 54B of the day operating cam 53B where the cam follower 63B of the day hammer 62B contacts is increased. Accordingly, the day hammer hand 62B is intermittently rotated in the F1 direction, and the day hand 87B is intermittently rotated in the B1 direction accordingly.

  When changing the day from Saturday (SAT) to Sunday (SUN), as shown in FIG. 7, as in the case of changing from the 31st to the 1st shown in FIG. The cam follower 63B is positioned in the vicinity of the maximum diameter portion 56B of the cam surface 54B of the day operation cam 53B, and the day hand 87B is positioned at the rightmost Saturday (SAT) of the fan-shaped small day display area 89B. In accordance with the rotation of the intermediate wheel 24C in the C1 direction, the Sunday rotation wheel 45B of the vehicle 40 rotates in the D1 direction and engages with the tooth portion of the rotation wheel 52B to rotate the transmission wheel 52B. Rotate in the E1 direction by the amount. Accordingly, the cam follower 63B of the day hammering lever 62B under the action of the elastic biasing force of the small day indicator spring 88B causes the maximum diameter portion 56B of the cam surface 54B of the day operating cam 53B to rotate in the E1 direction. As a result, it falls all the way to the minimum diameter portion 55B along the transition or step 57B, and the day hammer 62B is rotated in the F2 direction all at once. Accordingly, the small day wheel 85B meshed with the arcuate gear portion 65B of the day hammering lever 62B by the small day gear 84B is suddenly rotated in the B2 direction, and the day hand 87B is at the initial position from the position of Saturday (SAT). It is rotated at a stretch in the B2 direction to the position of Sunday (SUN). This completes the day change from Saturday (SAT) to Sunday (SUN).

  In the calendar timepiece 3 having the movement 2 equipped with the calendar mechanism 1 according to a preferred embodiment of the present invention constructed as described above, various types of the retrograde date display mechanism 1A and the retrograde day display mechanism 1B constituting the calendar mechanism 1 are shown. The elements are arranged separately in the thickness direction of the timepiece 3 on the dial 11 side or the second wheel train receiver 9 side and the back cover 12 side or the second base plate 7 side with the small date wheel receiver 8 as a boundary, and Similar functional elements of the retrograde date display mechanism 1A and the retrograde day display mechanism 1B are arranged concentrically along the respective central axes 31, 34, and 37, and the rotation center axis B of the date hands 87A and the day hands 87B is also provided. Since they coincide with each other, they can be compactly formed with a minimum occupied space. Therefore, if desired, other functions can be incorporated in the space.

  Moreover, in the calendar mechanism 1, the large-diameter cylindrical small date shaft 81A that forms the rotation center of the date hand 87A and the small-diameter small day shaft 81B that forms the rotation center of the day hand 87B are not simply arranged concentrically. Since the central pipe 70 is disposed between the large-diameter cylindrical small day shaft 81A and the small-diameter small day shaft 81B, there is no possibility that the small day shaft 81B will shake due to the B1 and B2 direction rotation of the small date shaft 81A. Further, there is no possibility that the small date axis 81A is shaken by the B1, B2 direction rotation of the small day axis 81B. In particular, the date display mechanism 1A and the day display mechanism 1B of the calendar mechanism 1 are retrograde, and the date hand 87A is rotated in the B2 direction to return to the initial position, and the day hand 87B is rotated in the B2 direction. Since the returning operation to return to the initial position is performed at a high speed at a stroke, it is difficult to avoid the rotational friction and impact at that time from being transmitted to the train wheel member. However, in this calendar mechanism 1, the center pipe 70 has a large diameter cylindrical shape. Since the small date axis 81A and the small diameter small day axis 81B are separated from each other, there is little possibility that the other retrograde display is disturbed by high-speed rotation, impact, or the like when the retrograde mechanism is restored. Further, in this calendar mechanism 1, since the center pipe 70 is configured to be supported in a stationary state by the small date wheel receiver 8 or the like, the center pipe 70 is less likely to shake, so the needles 87A and 87B There is little risk that the display or operation will be disturbed by the friction and impact at the time of return being transmitted to other parts. Since the center pipe 70 is supported by the small date wheel receiver 8 in a stationary state, the large-diameter cylindrical small date shaft 81A can be supported by the second train wheel bridge 9 and the center pipe 70. Since the support of the cylindrical small date shaft 81A becomes more stable and the small diameter small day shaft 81B can be supported by the second main plate 7 and the center pipe 70, the support of the small diameter small day shaft 81B becomes more stable.

  However, if desired, at least some of the elements performing the same function may not be arranged concentrically. In particular, by setting the rotation center of the date hammer lever and the rotation center of the day hammer lever at different locations, the concentric small day display area 89A and the small day display area 89B are used even if they are the same. It is possible to increase the degree of freedom of the shape of the operating cam.

  FIG. 8 shows a calendar mechanism including a retrograde date display mechanism 1Aα and a retrograde day display mechanism 1Bα in which the rotation center axis Fα of the date hammer 62Aα is different from the rotation center axis Fβ of the day hammer 62Bα. A calendar timepiece 3α with a movement 2α having 1α is shown. In the calendar mechanism 1α of FIG. 8, the same elements as those of the calendar mechanism 1 of FIG. 1 are denoted by the same reference numerals, and corresponding but different elements are denoted by the same numerals followed by α.

  In the calendar mechanism 1α, a Sunday turning intermediate wheel 24c turning around the central axis C in the C1 direction, a sun turning wheel 45A equipped with a day turning claw 45A and a day turning claw 45B around the central axis D in the D1 direction, the central axis The date turning wheel 52A and the day turning wheel 52B, the day jumper 58A and the day jumper 58B, and the small date wheel 85A and the small day wheel 85B which are rotated around the central axis B. The hands 87A and the day hand 87B, the small date wheel spring 88A and the small day wheel spring 88B are practically the same as the corresponding elements of the calendar mechanism 1.

  On the other hand, in the calendar mechanism 1α, for example, the shapes 55Aα and 56Aα of the cam surface 54Aα of the day operation cam 53Aα and the shapes 55Bα and 56Bα of the cam surface 54Bα of the day operation cam 53Bα can be different. Further, not only the rotation center axis Fβ but also the shape of the cam follower 63Bα and the arcuate gear portion 65Bα can be different from the corresponding elements of the day hammer lever 62B of the calendar mechanism 1 for the day hammer lever 62Bα.

  In the example of FIG. 8, a particularly significant difference is, for example, the date hammer 62Aα. In other words, in the example of FIG. 8, the date hammer 62Aα is shifted from the position of the rotation center axis F, unlike the day hammer 62Bα, which has the rotation center axis Fβ at a position substantially coincident with the position of the rotation center axis F. An arcuate gear portion 65Aα having a rotational center axis Fα at a position and having a much smaller radius than the cam follower 63Aα is provided. Therefore, in this case, even if the variation in the radius of the cam surface 54Aα of the day operation cam 53Aα is relatively large, the circumferential movement length of the arcuate gear portion 65Aα is compared with the circumferential rotation length of the cam follower 63Aα. Even if the diameter of the small date indicator 85A is relatively large, the date hand 87A can be rotated within the limited sector area 89A.

  In the retrograde day display mechanism 1Aα and the retrograde day display mechanism 1Bα constituting the calendar mechanism 1α of FIG. 8, the other points are substantially the same as those described with reference to FIGS. Accordingly, it is possible to minimize the possibility that interference between the two shafts 81A and 81B due to the retrograde operation will occur when the center pipe 70 is interposed between the large-diameter cylindrical small day shaft 81A and the small-diameter small day shaft 81B. . Moreover, despite the fact that the retrograde fast return operation occurs in various relative phases that can be said to be practically random, the day and the day in a stable state without being affected by the fast return operation. It is the same that retrograde display can be performed for.

In the above description, only the case where the two retrograde displays are day and day has been described. However, the calendar information to be displayed in a retrograde manner is daily information such as “day” or “day of the week”. is there. However, if desired, it may be any other than daily units (year, month, week, day, day, age, hour (24-hour display), hour (12-hour display), minute, etc.).
In the above-described example, the center pipe 70 is a pipe-shaped member having a hollow portion. However, the present invention is not limited to this. A rectangular tubular member can also be applied.
Further, as the material of the center pipe 70, a metal such as iron, a resin material such as ABS, acrylic, or PC, a hard rubber, an elastomer, or the like can be applied.
In the above-described example, as an example of the first angle of the present application, the date indicating the day “1” in the fan-shaped small day display area 89A is displayed as the first angle, and the date hand 87A is displayed in the fan-shaped small day. Although the angle indicating “31” day in the region 89A is the second angle, the present invention is not limited to this, and any angle indicated by an arbitrary hand such as the date hand 87A may be the first angle or the second angle.

1,1α Clock calendar mechanism 1A, 1Aα Retrograde date display mechanism 1B, 1Bα Retrograde day display mechanism 2, 2α Clock movement 3, 3α Calendar clock 4 Base plate 4a Hole 5 Second receiver 6 First receiver 7 Second base plate 7a, 7b, 7c, 7d Hole portion 8 Second wheel train receiver 8a, 8b, 8c Hole portion 8d Bearing portion 9 Small date holder 9b, 9c, 9d Hole portion 9e Dial side surface 11 Dial plate 12 Back cover 13 Case 14 Crown 15 Band 20 Operating wheel train 21 Hour hand 22 Minute hand 23 Second hand 24 Hour wheel 24a Large-diameter cylindrical portion 24b Tube gear 24c Sunday turning intermediate wheel 25 Cylinder pinion 26 Minute wheel 26a Minute gear 27 Second wheel 27a Fourth true 27b Second Gear 28 Day wheel 29 29 escape wheel 29a escape gear 31 Sunday turning wheel central shaft 31a, 34a, 37a large diameter portion 31b, 34b, 37c small diameter portion 34 operating cam central shaft 4A Part 34B between the second wheel train receiver and the small date wheel receiver 37B between the small date wheel receiver and the second base plate 37A Reversing lever central axis 37A Between the second wheel train receiver and the small date wheel receiver Part 37B Part 40 between the small date wheel receiver and the second base plate Sunday turning wheel 41 Hub part 42 Sunday turning gear 45A Day turning claw 45B Day turning claw 46A, 46B Central hole 51A Day working cam hub part 51B Operating cam hub portion 52A Day rotation transmission wheel 52B Day rotation transmission wheel 53A, 53Aα Day operation cam 53B, 53Bα Day operation cam 54A, 54B, 54Aα, 54Bα Cam surface 55A, 55B, 55Aα, 55Bα Minimum diameter portion 56A, 56B 56Aα, 56Bα Maximum diameter part 57A, 57B Transition part (step part)
58A date jumper 58B day jumper 61A date hammer lever hub portion 61B day hammer lever hub portion 62A, 62Aα date hammer lever 62B, 62Bα day hammer lever 63A, 63B, 63Aα, 63Bα cam follower 64A, 64Aα date hammer lever body Portions 64B, 64Bα Day hammer lever main body portions 65A, 65B, 65Aα, 65Bα Arc-shaped gear portion 70 Center pipe (an example of a vibration suppressing member)
71 Large-diameter portion 72 Flange-shaped portion 73 Tubular body portion 81A Large-diameter cylindrical small date shaft 81B Small-diameter small-day shaft 82A, 82B Base end portion 83B Part 84A Small date gear 84B Small date gear 85A Small date wheel 85B Small date wheel 86A, 86B Projection end 87A Day hand 87B Day hand 88A Small day wheel spring 88B Small day wheel spring 89A Small day display area 89B Small day display area A Thickness direction B, C, D, E, F, Fα, Fβ Central axis C1, D1, E1, Fα1, Fβ1 direction

Claims (12)

A first calendar information display needle for displaying the first calendar information in a first fan-shaped display area;
A second calendar information display needle for displaying second calendar information in a display area of a second sector concentric with the first sector;
A first calendar information display shaft attached to the tip of the first calendar information display needle and rotatable about the central axis of the first sector;
A second calendar information display shaft attached to the tip of the second calendar information display needle, concentric with the first calendar information display needle and rotatable about the central axis;
A vibration suppressing member positioned between the first and second calendar information display shafts and stationary with respect to the main plate;
A calendar mechanism for a timepiece having: The timepiece calendar mechanism according to claim 1,
A needle control mechanism for returning one of the first calendar information display needle or the second calendar information display needle to the first angle when the angle of the first calendar information display needle becomes a second angle larger than the first angle. When,
The timepiece calendar mechanism, wherein the vibration suppression unit suppresses vibration generated when the one hand returns from the second angle to the first angle. The timepiece calendar mechanism according to claim 1 or 2,
A first calendar information small gear integral with the first calendar information display shaft;
A first calendar information operating cam that is rotated in one direction, from a minimum diameter portion to an outer circumferential direction of the rotation center of the first calendar information operating cam, in a direction away from the rotation center of the first calendar information operating cam. A first calendar information cam surface having a cam surface that expands to a maximum diameter portion and a step portion that connects the maximum diameter portion and the minimum diameter portion; and the first calendar information cam surface A first calendar information cam follower that engages at one end, and a first calendar information hammer that has a first calendar information gear portion that meshes with the first calendar information small gear on one side;
A second calendar information small gear integral with the second calendar information display shaft;
A second calendar information operating cam rotated in one direction, from the smallest diameter portion toward the outer circumference of the rotation center of the second calendar information operating cam, and in a direction away from the rotation center of the second calendar information operating cam. A cam surface that expands to a maximum diameter portion, and a second calendar information cam surface formed with a step portion that connects the maximum diameter portion and the minimum diameter portion;
A second calendar information cam follower that engages with the second calendar information cam surface is provided at one end, and a second calendar information gear portion that meshes with the second calendar information small gear is provided on one side. A timepiece calendar mechanism comprising a hand lever. A timepiece calendar mechanism according to claim 3,
The timepiece calendar mechanism, wherein the first calendar information hammer and the second calendar information hammer are arranged concentrically. A timepiece calendar mechanism according to claim 3,
A timepiece calendar mechanism, characterized in that a rotation center axis of the first calendar information hammer is different from a rotation center axis of the second calendar information hammer. A timepiece calendar mechanism according to any one of claims 3 to 5,
A timepiece calendar mechanism, wherein the first calendar information operating cam and the second calendar information operating cam are arranged concentrically. A timepiece calendar mechanism according to any one of claims 3 to 6,
The first calendar information operating cam and the first calendar information rotating transmission wheel integrated with the second calendar information operating cam and the second calendar information rotating transmission vehicle integrated with the second calendar information operating cam, and the first calendar information rotating cam. A timepiece calendar mechanism comprising a first calendar information turning claw for turning a transmission wheel and a second calendar information turning claw for turning the second calendar information turning transmission wheel. A timepiece calendar mechanism according to any one of claims 1 to 7,
A timepiece calendar mechanism, wherein the first calendar information is a day and the second calendar information is a day of the week. A timepiece calendar mechanism according to any one of claims 1 to 8,
The timepiece calendar mechanism, wherein the display area of the second sector is within the range of the display area of the first sector. A timepiece calendar mechanism according to any one of claims 1 to 9,
The timepiece calendar mechanism, wherein the vibration suppressing member is a pipe-shaped member having a hollow portion.   A movement comprising the timepiece calendar mechanism according to any one of claims 1 to 10.   A calendar timepiece comprising the timepiece calendar mechanism according to any one of claims 1 to 10.

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