JP2018136302A - Mechanical annual calendar - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a clock mechanical annual calendar having a small number of simple components.SOLUTION: A mechanical annular calendar comprises a shift seesaw 5 which can be driven around a seesaw turning shaft 28 so as to be turnable once every 24 hours. A claw arm 33 is connected to the shift seesaw around a shift claw shaft 32 so as to be turnable with an interval to a radial direction from the shift seesaw turning shaft. A shift claw 8 arranged at a claw arm with an interval from the shift claw shaft is engaged with 31 pieces of teeth of a date wheel 10. A month-end disc 16 coaxially connected to the date wheel comprises a circular outline 34 which draws a circle in a radial direction. A feeler tip 17 of a feeler arm 18 which is pivoted around a second turning shaft 35 so as to be turnable contacts with the circulation outline in a state that the tip is spring-elastically energized in advance.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a mechanical annual calendar for watches. The mechanical annual calendar includes a shift seesaw that can be driven to pivot about a seesaw pivot once every 24 hours. A claw arm is connected to the shift seesaw so as to be able to turn around the shift claw axis at a distance from the seesaw turning axis in the radial direction. Further, the mechanical annual calendar includes a shift claw disposed on the claw arm at a distance from the shift claw axis. The shift claw is engaged with the teeth of a date wheel provided with 31 teeth or an integer multiple of 31 in a state in which the shift claw is pre-spring-biased. The date wheel can be driven to rotate in a predetermined rotation direction by one tooth or two teeth corresponding to one or two days by a shift claw during the turning motion of the shift seesaw. The date display device can be driven by the date wheel. In addition, the mechanical annual calendar has a month-end disk concentrically connected to the date car. The end-of-month disk has a circular outline that describes the circumference in the radial direction. To the circular outline, the feeler tip of a feeler arm that is supported so as to be pivotable around the second pivot axis is brought into contact with a spring elastically biased in advance. The device for determining the turning angle of the shift seesaw for moving the date wheel forward by one or two days can be switched by the turning motion of the feeler arm.

  An object of the present invention is to provide a mechanical annual calendar for a timepiece of the above-described type with a simple configuration of parts with a reduced score.

  This problem is solved by the present invention by providing the circular outline of the end-of-month disk with a feeler gap directed radially inward. The feeler gap extends over two teeth of the date wheel at a constant depth in the circumferential direction, and then rises to a circular outline in a ramp shape in the direction opposite to the predetermined rotation direction of the date wheel.

  With this configuration, the mechanical annual calendar parts can be simply configured. Such parts are also easily manufacturable. This ease of manufacture increases the accuracy of the parts and thereby increases the reliability of the mechanical annual calendar function.

  On the 31st day of the month, the feeler tip of the feeler arm is located above the ramp-like rise of the feeler gap of the end-of-month disk. For this reason, a moment directed in the direction opposite to the predetermined rotation direction of the date wheel 10 firmly connected to the month-end disk is generated with respect to the month-end disk. In order to avoid the return rotation of the date wheel due to this, the return lock spring can lock the rotation of the date wheel in the direction opposite to the predetermined rotation direction of the date wheel.

  A structural part that is easily manufacturable and has reliable functionality is achieved as follows. In other words, the device for determining the 1st or 2nd advance of the date car includes a month sensing disk. The moon sensing disk can be driven to rotate so that it rotates once in 12 steps every year. The lunar outline that wraps around the radial direction of the lunar sensing disk has larger and smaller diameters depending on the long and short months. The shift seesaw feeler is biased against the monthly outline with spring force and can be removed from the monthly outline once every 24 hours.

  In this case, the feeler arm can be equipped with a lunar shift claw. The lunar shift pawl is engageable between the teeth of a lunar drive that is concentrically connected to the lunar sensing disk and comprises 12 teeth.

  When the feeler tip of the feeler arm falls into the feeler gap, the teeth to be switched for the lunar drive are jumped back. Subsequently, when the tip of the feeler slides up the ramp-like rise of the feeler gap, the month drive is advanced by one tooth.

  Preferably, the lunar detent is spring-elastically engaged between the lunar drive teeth and is still missing after reaching the correct new target position of the lunar drive after the lunar drive post-feed. Completes the switching of the route that is on.

  The shift seesaw can be provided with a feeler cam. The feeler cam comes into contact with the stopper of the feeler arm when the tip of the feeler comes into contact with the circular outline of the end-of-month disk. This prevents the feeler from sinking radially into the short lunar region, which is the small diameter of the lunar outline of the lunar sensing disk. If the feeler tip is submerged in the feeler gap, the feeler cam will not abut the stopper and the feeler can sink radially into the short moon region, which is the small diameter of the lunar outline of the lunar sensing disk It is.

  This allows the shift seesaw feeler to sink into the short moon region only if the feeler tip is also submerged in the feeler gap.

  Embodiments of the present invention are described in detail below with reference to the drawings.

It is the schematic of the mechanical annual calendar of the timepiece in the 1st change position. FIG. 2 is a schematic view of the mechanical annual calendar of the timepiece of FIG. 1 in a second switching position. FIG. 6 is a schematic view of the mechanical annual calendar of the timepiece of FIG. 1 in a third switching position. FIG. 5 is a schematic view of the mechanical annual calendar of the timepiece of FIG. 1 in a fourth switching position. FIG. 6 is a schematic view of the mechanical annual calendar of the timepiece of FIG. 1 in a fifth switching position.

  The hour wheel 1 is driven to rotate in the rotation direction “a” by one rotation every 12 hours by a movement not shown, and drives the 24-hour wheel 2 by one rotation every 24 hours. The 24-hour wheel 2 includes a pin 3 protruding in the axial direction. When the 24-hour wheel 2 rotates, the pin 3 entrains a shift finger 4 disposed in the 24-hour wheel 2 that extends in a substantially radial direction with respect to the rotation axis of the 24-hour wheel 2.

  This shift finger 4 advances the date once a day. When the shift finger 4 comes into contact with the shift arm 25 of the shift seesaw 5 that can turn around the seesaw turning axis 28 parallel to the turning axis of the 24-hour wheel 2, date switching is started.

  When the hour wheel 1 rotates in the direction opposite to the rotation direction “a” and thereby drives the 24-hour wheel 2, the action portion of the shift finger 4 with respect to the shift arm 25 is elastically bent. Therefore, the shift seesaw does not turn in this wrong direction of rotation.

  After the shift finger 4 and the shift arm 25 of the shift seesaw 5 come into contact with each other, the shift seesaw 5 is turned from the basic position of the shift seesaw 5 against the force of the shift seesaw spring 6 biased in advance. The shift seesaw 5 includes a feeler 26 that is spaced radially from the seesaw pivot 28. The shift seesaw 5 is always pressed by the shift seesaw spring 6 against the moon outline 29 that describes the circumference in the radial direction of the moon sensing disk 7 that can rotate around the moon rotation axis 31 parallel to the seesaw pivot axis 28. . In the moon sensing disk 7 which can be driven to rotate clockwise in 12 steps every year, the moon outline 29 which draws a circumference in the radial direction is a circle around the radius of 31 days. With a large diameter and a small diameter 27 for a short month of 30 days.

  The shift seesaw 5 is provided with a pawl arm 33 that can pivot around a shift pawl shaft 32 that is parallel to the seesaw pivot shaft 28 at a radial distance from the seesaw pivot shaft 28. The claw arm 33 includes a shift claw 8 at one free end of the claw arm 33.

  The claw arm 33 receives an action from the pre-biased shift claw spring 9 together with the shift claw 8 of the claw arm 33 so as to engage with the tooth portion of the date wheel 10 having 31 teeth.

  During the date switching, the shift claw 8 is pulled in the tangential direction of the date wheel 10 by the shift seesaw 5. Thus, the shift claw 8 pulls the tooth portion of the date wheel 10 and rotates the date wheel 10 in a predetermined rotation direction, that is, counterclockwise.

  By this rotational movement, the intermediate gear 11 constituting the drive system from the date wheel 10 to the display wheel 12 having 31 teeth is also rotationally moved.

  The return lock spring 13 is elastically engaged between the teeth of the date wheel 10 and locks the rotation in the direction opposite to the driving direction of the date wheel 10. The display wheel detent 14 is spring-elastically engaged between the teeth of the display wheel 12. In the case described above, both the return lock spring 13 and the indicator wheel detent 14 are removed, after which they re-engage between each adjacent tooth.

  On the display wheel 12, hands not shown are arranged. The hand moves along the date itself on a date scale that is similarly provided with a 31-division not shown.

  After the date switching is completed, the shift arm 25 falls from the shift finger 4 again. In this case, the spring-biased shift pawl 8 engages behind the next tooth of the date wheel 10. The next tooth is then pulled again in the tangential direction of the date wheel 10 at the next date change.

  The month sensing disk 7 restricts the path of the shift seesaw 5 over the entire month. Therefore, always only one tooth, and thus only one day, is switched every 24 hours.

  The month end disk 16 is concentric with the date wheel 10 and is firmly connected to the date wheel 10. The end-of-month disk 16 includes a circular outline 34 that describes the circumference in the radial direction. The feeler tip 17 of the feeler arm 18 supported so as to be able to turn around the second turning shaft 35 is in contact with the circular outline 34 in a state in which it is biased elastically in advance.

  The circular outline 34 comprises a feeler gap 15 directed radially inward at the position of the date of the month after the 30th day of the month. The feeler gap 15 extends in a direction opposite to a predetermined rotation direction of the date wheel 10 at first at a certain depth over two days corresponding to the two divided portions, and then again at the ramp-like rising 30, the circular outline 34 is again formed. Get up to.

  On the 30th day of each month, the feeler gap 15 of the end-of-month disk 16 is located below the feeler tip 17 of the feeler arm 18 (see FIG. 2). The feeler arm 18 is pressed against the feeler gap 15 of the end-of-month disk 16 by the spring force of the pre-biased feeler spring 19. The lunar drive 22 having 12 teeth is concentrically connected to the lunar sensing disk 7.

  When the feeler tip 17 falls into the feeler gap 15, the month shift claw 20 that engages the month drive 22 in the feeler arm 18 is further moved by one tooth. The month shift claw 20 is always pressed against the tooth portion of the month drive 22 by the spring arm 21.

  On the 31st day of the month, the feeler tip 17 of the feeler arm 18 is positioned on the ramp-like rise 30 of the feeler gap 15 of the month end disk 16 (see FIG. 3). As a result, an opposite driving moment is generated for the date wheel 10. The return lock spring 13 prevents the end-of-month disk 16 from returning and rotating in the direction opposite to the predetermined rotation direction.

  When switching from the 30th day to the 31st day of the month, the empty path for the tooth 23 of the month drive 22 of the month shift claw 20 was reduced. When the date wheel 10 is switched from the 31st day to the first day of the following month at night, the date wheel 10 rotates so that the feeler arm 18 is further removed. In this case, the month shift claw 20 pushes the teeth 23 of the month drive 22. Thereby, the month drive 22 is rotated. In this case, the lunar detent 24 that engages the lug drive teeth in a springy manner in the radial direction is disengaged and completes the switching of the still missing path of the lunar drive 22. As a result, only January was postponed. While the month is postponed, the shift seesaw 5 is removed to switch the date. Therefore, the shift seesaw 5 is not elastically mounted on the moon outline 29 of the moon sensing disk 7. Therefore, it is only the spring force of the moon detent 24 that can be overcome to switch the moon.

  From the first day to the 29th day of the short month, the shift seesaw 5 can always be engaged behind only one tooth of the date wheel 10, and therefore only one tooth can be advanced (see FIG. 4). ). This is because the feeler tip 17 of the feeler arm 18 is in contact with the circular outline 34 of the end-of-month disk 16 in a spring-biased state. In fact, the shift seesaw 5 may collide the feeler 26 of the shift seesaw 5 on the small diameter 27 of the lunar outline 29 of the lunar sensing disk 7 in a spring-biased state. This is prevented by first contacting the feeler cam 36 of the shift seesaw 5 with the stopper 37 of the feeler arm 18. This prevents the feeler 26 from colliding with the small diameter 27 of the lunar outline 29.

  On the 30th day of the short month, the feeler tip 17 of the feeler arm 18 falls into the feeler gap 15 of the month end disk 16 (see FIG. 5). The feeler tip 17 of the feeler arm 18 can run deeper. Therefore, it is now possible for the shift seesaw 5 to fall on the small diameter 27 of the lunar outline 29 of the lunar sensing disk 7 at the feeler 26 of the shift seesaw 5. As a result, the shift claw 8 can now jump back two teeth in the date wheel 10 instead of just one tooth. As a result, the shift claw 8 can now rotate the date wheel 10 by two teeth, and therefore can be switched from the 30th day of the month to the 1st day of the month.

1 hour wheel 2 24 hour wheel 3 pin 4 shift finger 5 shift seesaw 6 shift seesaw spring 7 moon sensing disk 8 shift claw 9 shift claw spring 10 date wheel 11 intermediate wheel 12 indicator wheel 13 return lock spring 14 indicator car detent 15 feeler gap End of 16 Disc 17 Feeler tip 18 Feeler arm 19 Feeler spring 20 Moon shift claw 21 Spring arm 22 Moon drive 23 Tooth 24 Moon detent 25 Shift arm 26 Feeler 27 Small diameter 28 Seesaw pivot 29 Moon outline 30 Ramp-shaped rising 31 Moon rotation Shaft 32 Shift claw shaft 33 Claw arm 34 Circular outline 35 Second turning shaft 36 Feeler cam 37 Stopper

Claims (6)

A mechanical annual calendar for watches:
A shift seesaw (5) that can be driven to pivot about a seesaw swivel axis (28) once every 24 hours, the shift seesaw (5) being spaced radially from the seesaw swivel axis (28). And a shift seesaw (5) in which a claw arm (33) is pivotally connected around a shift claw shaft (32);
A shift claw (8) disposed on the claw arm (33) at a distance from the shift claw shaft (32), and the shift claw (8) is spring-elastically biased in advance. In the state, it engages with the teeth of the date wheel (10) having 31 teeth or an integral multiple of 31 teeth, and the date wheel (10) is used for the turning motion of the shift seesaw (5). In this case, the shift claw (8) can be driven to rotate in a predetermined rotation direction by one tooth or two teeth corresponding to one or two days, and the date indicator (10) can be used to drive a date display device. Can be driven;
The end-of-month disk (16) is concentrically connected to the date wheel (10), and the end-of-month disk (16) includes a circular outline (34) that surrounds in a radial direction. The circular outline (34) includes A feeler tip (17) of a feeler arm (18) supported so as to be pivotable about the second pivot axis (35) contacts the feeler arm (18) in a state in which the feeler elastically biased in advance. In a mechanical annual calendar that is switchable, the device for determining the turning angle of the shift seesaw (5) for advancing the date wheel (10) by one or two days by a turning movement of
The circular outline (34) of the end-of-month disk (16) includes a feeler gap (15) directed radially inward, the feeler gap (15) having a constant depth in the circumferential direction with the date wheel (10 ) Extending over two teeth, and then rising up to the circular outline (34) in a ramp shape in a direction opposite to the predetermined rotational direction of the date wheel (10). .   The mechanical annual calendar according to claim 1, wherein the return lock spring (13) locks rotation of the date wheel (10) in a direction opposite to a predetermined rotation direction of the date wheel (10). A mechanical annual calendar.   The mechanical annual calendar according to claim 1 or 2, wherein the device for determining the advance of one or two days of the date wheel (10) comprises a month sensing disk (7), the month sensing disk ( 7) can be driven to rotate so as to rotate once in 12 steps every year, and the moon outline (29) describing the circumference of the moon sensing disk (7) in the radial direction has a long moon and a short moon. Depending on the moon, with a larger and smaller diameter (27), the feeler (26) of the shift seesaw (5) is biased against the moon outline (29) by spring force and 24 hours Mechanical annual calendar characterized in that it is possible to deviate from the monthly outline (29) once every time.   4. A mechanical annual calendar according to claim 3, wherein the feeler arm (18) comprises a lunar shift pawl (20), the lunar shift pawl (20) concentrically connected to the lunar sensing disk (7). A mechanical annual calendar characterized in that it is engageable between the teeth of a lunar drive (22) comprising 12 teeth.   5. A mechanical annual calendar as claimed in claim 4, characterized in that the lunar detent (24) engages between the teeth of the lunar drive (22) spring-elastically inwardly. Mechanical annual calendar.   It is a mechanical annual calendar as described in any one of Claims 3-5, Comprising: The said shift seesaw (5) is provided with the feeler cam (36), and this feeler cam (36) is said feeler tip (17). ) Abuts on the circular outline (34) of the end-of-month disk (16), abuts on the stopper (37) of the feeler arm (18), so that the feeler (26) is in contact with the lunar sensing disk (7). ) Of the moon outline (29) in the short moon region, which is a small diameter (27), and the feeler tip (17) is submerged in the feeler gap (15), The feeler cam (36) is not in contact with the stopper (37), and the feeler (26) is in front of the lunar sensing disk (7). Mechanical annual calendar, wherein the region of the short month a small diameter (27) of the month outline (29) can be submerged in the radial direction.