JP5467596B2 - Clock with calendar mechanism - Google Patents

Description

  The present invention relates to a timepiece with a calendar mechanism capable of displaying a date using large date characters. In particular, the present invention relates to a timepiece with a calendar mechanism that is configured to display dates from the 1st to the 31st by three date wheels and can display the date by using large date characters.

  In general, a machine body including a driving part of a timepiece is referred to as a “movement”. A state in which a dial and hands are attached to the movement and put into a watch case to make a finished product is called “complete” of the watch. Of the two sides of the main plate that constitutes the watch substrate, the side with the glass of the watch case, that is, the side with the dial is referred to as the “back side” or “glass side” or “dial side” of the movement. Called. Of the two sides of the main plate, the side with the back cover of the watch case, that is, the side opposite to the dial is referred to as the “front side” or “back side” of the movement. A train wheel incorporated on the “front side” of the movement is referred to as a “front train wheel”. The train wheel incorporated in the “back side” of the movement is called “back train wheel”.

In general, the “12 o'clock side” indicates a side of a dial in which a scale corresponding to 12:00 of the dial is arranged. The “12 o'clock direction” indicates a direction from the rotation center of the hands toward the “12 o'clock side” in an analog timepiece.
Further, “3 o'clock side” indicates the side of the analog timepiece on which the scale corresponding to 3 o'clock of the dial is arranged. “3 o'clock direction” indicates a direction from the rotation center of the hands toward “3 o'clock side” in an analog timepiece.
The “6 o'clock side” indicates the side of the analog timepiece on which the scale corresponding to 6 o'clock of the dial is arranged. “6 o'clock direction” indicates a direction from the rotation center of the hands toward “6 o'clock side” in an analog timepiece.
The “9 o'clock side” indicates the side of the analog timepiece on which the scale corresponding to 9 o'clock is arranged. “9 o'clock direction” indicates a direction from the center of rotation of the hands toward “9 o'clock side” in an analog timepiece.

  The configuration of a conventional timepiece with a calendar mechanism including a first date indicator that displays the first place of the date and a second date wheel that displays the tenth place of the date will be described below.

(1) Conventional first-type calendar mechanism In the conventional first-type calendar mechanism, the first date indicator for displaying one of the dates and the position of the first date indicator in the rotational direction are regulated. 1st day jumper for, 2nd date indicator for displaying the tenth place of the date, 2nd day jumper for setting the position of the second day indicator in the rotation direction, and 1st date indicator rotation And a date intermediate wheel capable of rotating the second date indicator according to the above. The first date indicator includes 31 first date indicator teeth portions formed as internal teeth and four calendar feed teeth formed as internal teeth. The calendar feed dog is composed of a first calendar feed dog, a second calendar feed dog, a third calendar feed dog, and a fourth calendar feed dog, which are used as the reference. A forward transfer portion for sending in the first direction and a reverse feed portion for sending the first date indicator in the second direction opposite to the first direction are provided (Patent Literature 1 and Patent Literature 2 below). reference).

(2) Conventional second-type calendar mechanism In the conventional second-type calendar mechanism, scales from “0” to “3” or from “1” to “3” are added. It includes a member that has four positions and displays the 10th place every 10 days, and a member that advances every 24 hours and displays the 1st place. The member for displaying the 1's place can take 31 positions, and three scales arranged continuously from “0” to “9” are attached in succession. One of the scales has an additional “1” inserted between “0” and “1” (see Patent Document 3 below).

(3) Conventional third-type calendar mechanism In the conventional third-type calendar mechanism, the first moving object displays the first place of the date as well as the complete date from 1 to 9, and the second moving object. Is configured to display the tens place of the date, and the 30 and / or 31 days remaining intact. The moving body of the first place ring is provided with a driving projection. By this driving protrusion, the moving body of the tens place ring can be operated (see Patent Document 4 below).

(4) Conventional fourth type calendar mechanism In the conventional fourth type calendar mechanism, the normal tenth scale that displays the tenth digit only in the tenth date display hole and the tenth position in the tenth date display hole. And a dual display scale for displaying the first number in the first date display hole. The 1st place date plate has 5 tenth place drive teeth. The tenth date indicator is driven to rotate by the tenth drive tooth (see Patent Document 5 below).

Japanese Patent Laying-Open No. 2005-214836 JP 2005-214837 A JP 2000-65957 A JP-T-2006-522323 JP 2009-250912 A

  Conventionally, in a timepiece with a calendar mechanism capable of displaying a larger date on a plurality of date indicators, for example, a first date indicator and a second date indicator, a display phase shift does not occur between the first date indicator and the second date indicator. Thus, the position of the 1st date indicator was regulated using the 1st date jumper, and the location of the 2nd date indicator was regulated using the 2nd date jumper. However, when the watch is dropped and subjected to a disturbance such as an impact, a display phase shift may occur between the first date indicator and the second date indicator. In a conventional watch with a calendar mechanism including a 1st date indicator and a 2nd date indicator, if a phase shift occurs between the 1st date indicator and the 2nd date indicator, the watch is disassembled and the 1st date There was a problem that the phase shift of the display between the car and the second day wheel had to be adjusted.

  An object of the present invention is to provide a calendar mechanism timepiece capable of displaying a date with a large number using a plurality of date dials, and even when a phase shift of the date display occurs, the phase of the date display is not disassembled. An object of the present invention is to provide a timepiece with a calendar mechanism that can be adjusted to a normal state.

  A timepiece with a calendar mechanism of the present invention includes a first date indicator that can display one of the dates, a first date jumper for setting the position of the first date indicator in the rotational direction, and a date. The second date indicator that can display the tenth position of the second date, the second date jumper for setting the rotational position of the second date indicator, and the specific date can be displayed independently. It is equipped with a third day wheel. The first date indicator has a first date letter display surface. On the first date letter display surface, “0”, “1”, “2”, “3”, “4”, “5”, “6”, Numbers “7”, “8”, “9” are provided. The second date indicator has a second date letter display surface. The second date letter display surface is provided with numbers for displaying the tens place “0”, “1”, “2” of the date. The third date indicator has a third date letter display surface.

  Numbers “30” and “31” are provided on the third date character display surface. The second date indicator is formed with a first date character display portion for displaying the first digit of the date by a number provided on the first date character display surface. On the third date indicator, the number of the date is indicated by a number provided on the first date character display surface, and the date is indicated by a number provided on the second date character display surface. A second date character display portion for displaying the tens place of is formed. The second date character display surface is disposed closer to the dial than the first date character display surface. The third date character display surface is disposed closer to the dial than the second date character display surface. The third date indicator can be rotated by rotating the first date indicator. The second date indicator can be rotated by the rotation of the third date indicator. The third date indicator is configured to rotate only when the first date indicator is at a position in a specific rotational direction in a state where the third date indicator is in a specific rotational direction. . With this configuration, it is possible to display the date using large date characters and adjust the phase of the date display without disassembling the clock even when the date display phase shift occurs.

  In the timepiece with a calendar mechanism of the present invention, the first date indicator is a first calendar for changing the position in the rotation direction of the second date indicator from “a state displaying 0” to “a state displaying 1”. A feed dog, a second calendar feed dog for changing the position in the rotation direction of the second date indicator from “a state displaying 1” to “a state displaying 2”, and the rotation direction of the second date indicator The third calendar feed dog for changing the position of “2” from “a state where 2 is displayed” to “a first state where nothing is displayed” and the position in the rotation direction of the second date indicator are “a state where nothing is displayed” The fourth calendar feed dog for changing from “1 state” to “second state in which nothing is displayed” and the rotational position of the second date indicator from “second state in which nothing is displayed” to “ And a fifth calendar feed dog for changing the state to “displaying 0”.

  The third date indicator is a first first date indicator meshing tooth for changing the position of the third date indicator in the rotational direction from “a state where 31 is displayed” to “a first state where nothing is displayed”. A second 1st date indicator meshing tooth for changing the position of the third date indicator in the rotational direction from "a first state in which nothing is displayed" to "a second state in which nothing is displayed"; A third 1st date indicator meshing tooth for changing the position in the rotation direction of the 3rd date indicator from a “second state in which nothing is displayed” to a “third state in which nothing is displayed”; A fourth 1st date indicator meshing tooth for changing the position in the rotation direction of the 3rd date indicator from "a third state in which nothing is displayed" to "a state in which 30 is displayed", and rotation of the third date indicator 5th 1st date indicator meshing tooth for changing the position of a direction from "state which displays 30" to "state which displays 31".

  The first first date indicator meshing tooth of the third date indicator cannot mesh with the first calendar feed tooth of the first date indicator, and the first first date of the third date indicator. The wheel meshing tooth cannot mesh with the second calendar feeding tooth of the first date indicator, and the first first date indicator meshing tooth of the third date indicator is the same as that of the first date indicator. The first date indicator meshing tooth of the third date indicator cannot be engaged with the third calendar feed dog, and the fourth calendar feed tooth of the first date indicator can be engaged. It should be configured so that it cannot. The first 1st date indicator meshing tooth may be configured to be able to mesh with the fifth calendar feed tooth.

  In the timepiece with a calendar mechanism of the present invention, the first date character display surface has “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”. , “9”, “0”, “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, “0”, “ The numbers “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9” are provided at an angular interval of (360/31) degrees. Is good. It is preferable that three sets of numbers “0”, “1”, and “2” are provided at an angular interval of (360/15) degrees on the second date letter display surface. The three “0” numbers are preferably provided at an angular interval of (360/3) degrees. The three “1” numbers may be provided at an angular interval of (360/3) degrees. The three “2” numbers may be provided at an angular interval of (360/3) degrees. It is preferable that a number “30” and a number “31” are provided on the third date letter display surface at an angular interval of (360/5) degrees. With this configuration, it is possible to realize a calendar clock that can display a date on a large date character.

  In the timepiece with a calendar mechanism according to the present invention, the first date indicator includes 31 first date indicator teeth portions formed as internal teeth and five calendar feed teeth formed as internal teeth. preferable. In this configuration, the first date indicator tooth portion is formed at an angular interval of (360/31) degrees. In this configuration, the calendar feed dog is formed at an angular interval of (360 * 10/31) degrees in the first direction with reference to the first calendar feed dog serving as a reference and the first calendar feed dog. The second calendar feed dog, the third calendar feed dog formed at an angular interval of (360 * 10/31) degrees in the first direction with reference to the second calendar feed dog, and the third calendar feed A fourth calendar feed dog formed at an angular interval of (360/31) degrees in the first direction with respect to the tooth, and a 360 (360/31) in the first direction with the fourth calendar feed dog as a reference. It is preferable to include a fifth calendar feed dog formed at an angular interval of 31) degrees.

  In the timepiece with a calendar mechanism of the present invention, it is preferable that the rotation center of the first date indicator and the rotation center of the second date indicator are arranged at the same position. The timepiece with a calendar mechanism of the present invention includes a date intermediate wheel that rotates based on the rotation of the third date indicator and can rotate the second date indicator, and the rotation center of the first date indicator, The rotation center of the third date indicator and the rotation center of the date intermediate wheel are preferably arranged on a straight line perpendicular to the rotation center axis of the winding stem. With this configuration, a date window is arranged in the 12 o'clock direction of the dial, and a small timepiece with a calendar mechanism can be realized with a small number of parts.

  In the timepiece with a calendar mechanism of the present invention, the second date indicator includes a third date indicator meshing tooth portion formed as an inner tooth, and the third date indicator is a first date indicator formed as an outer tooth. The first date indicator can directly rotate the second date indicator by engaging the third date indicator engagement tooth portion and the first date indicator engagement tooth. You may comprise as follows. With this configuration, a small timepiece with a calendar mechanism that can adjust the phase of the date display without disassembling the timepiece even when the date display phase shift occurs can be realized with a small number of components.

  According to the present invention, it is possible to realize a small calendar mechanism-equipped timepiece having a large date display and easy to see with a small number of parts. Furthermore, according to the present invention, in a timepiece with a calendar mechanism capable of displaying a larger date on a plurality of date wheels, the phase of the date display can be adjusted without disassembling the timepiece even when a phase shift of the date display occurs. The effect that it is possible can be demonstrated. For example, in a state in which “31” is displayed by the third date indicator and the watch receives an impact and only the first date indicator is rotated by one pitch, the winding stem is set to the calendar correction state. The first date indicator meshing tooth of the third date indicator can be rotated by the specific calendar feed dog of the first date indicator and can be corrected so as to be in a normal calendar display state. it can.

FIG. 3 is a schematic plan view showing a structure when the movement is viewed from the dial side in the first embodiment of the timepiece with calendar mechanism of the invention. In 1st Embodiment of the timepiece with a calendar mechanism of this invention, it is a fragmentary sectional view which shows a part of a front wheel train and a calendar mechanism. In 1st Embodiment of the timepiece with a calendar mechanism of this invention, it is a top view which shows the 1st date indicator in the structure which has arrange | positioned the date window in the 12 o'clock direction of the dial. FIG. 3 is a plan view showing a second date indicator in a configuration in which a date window is arranged in the 12 o'clock direction of the dial in the first embodiment of the timepiece with calendar mechanism of the present invention. In 1st Embodiment of the timepiece with a calendar mechanism of this invention, it is a top view which shows the 3rd date indicator in the structure which has arrange | positioned the date window in the 12:00 direction of the dial. In 2nd Embodiment of the timepiece with a calendar mechanism of this invention, it is a top view which shows the 2nd date indicator in the structure which has arrange | positioned the date window in the 12:00 direction of the dial. In 2nd Embodiment of the timepiece with a calendar mechanism of this invention, it is a top view which shows the 3rd date indicator in the structure which has arrange | positioned the date window in the 12:00 direction of the dial. In the first embodiment of the timepiece with calendar mechanism of the present invention, the first date indicator is rotated from the state in which “2” is displayed by the second date indicator and “9” is indicated by the first date indicator. It is a partial top view which shows the structure of the back side of the movement seen from the dial plate side in the front state. In the first embodiment of the timepiece with calendar mechanism of the present invention, the structure on the back side of the movement viewed from the dial side in the state in which the first date indicator starts rotating in the forward direction from the state shown in FIG. FIG. In the first embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 9, the first date indicator rotates in the forward direction, and the third date indicator rotates counterclockwise by the first date indicator. FIG. 10 is a partial plan view showing the structure of the back side of the movement as viewed from the dial side in a state where the second date indicator is rotating clockwise by the third date indicator. In the first embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 8, the first date indicator rotates one pitch in the forward direction, the second date indicator rotates one pitch in the forward direction, It is a partial top view which shows the structure of the back side of the movement seen from the dial plate in the state which the date indicator is rotating 1 pitch in the forward direction and "30" is displayed by the third date indicator. In the first embodiment of the timepiece with a calendar mechanism of the present invention, it is viewed from the dial side in the state in which the third date indicator starts rotating in the forward direction by the first date indicator from the state shown in FIG. It is a fragmentary top view which shows the structure of the back side of a movement. In the first embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 12, the first date indicator rotates one pitch in the forward direction, the third date indicator rotates one pitch in the forward direction, It is a partial top view which shows the structure of the back side of the movement seen from the dial side in the state which the date indicator is rotating 1 pitch in the forward direction and "31" is displayed by the third date indicator. In the first embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 13, the first date indicator rotates in the forward direction, and the third date indicator rotates counterclockwise by the first date indicator. FIG. 10 is a partial plan view showing the structure of the back side of the movement as viewed from the dial side in a state where the second date indicator is rotating clockwise by the third date indicator. In the first embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 14, the first date indicator rotates one pitch in the forward direction, the second date indicator rotates one pitch in the forward direction, When the date indicator is rotated by 1 pitch in the forward direction, “0” is displayed by the second date indicator, and “1” is indicated by the first date indicator, the back side of the movement viewed from the dial side. It is a fragmentary top view which shows a structure. In 2nd Embodiment of the timepiece with a calendar mechanism of this invention, it is a schematic plan view which shows a structure when a movement is seen from the dial side. In 2nd Embodiment of the timepiece with a calendar mechanism of this invention, it is a fragmentary sectional view which shows a front wheel train and a part of calendar mechanism. In the second embodiment of the timepiece with calendar mechanism of the present invention, the first date indicator is rotated from the state in which “2” is displayed by the second date indicator and “9” is indicated by the first date indicator. It is a partial top view which shows the structure of the back side of the movement seen from the dial plate side in the front state. In the second embodiment of the timepiece with calendar mechanism of the present invention, the structure on the back side of the movement as viewed from the dial side in the state in which the first date indicator starts rotating in the forward direction from the state shown in FIG. FIG. In the second embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 19, the first date indicator rotates in the forward direction, and the third date indicator rotates counterclockwise by the first date indicator. FIG. 10 is a partial plan view showing the structure of the back side of the movement as viewed from the dial side in a state where the second date indicator is rotating clockwise by the third date indicator. In the second embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 18, the first date indicator rotates one pitch in the forward direction, the second date indicator rotates one pitch in the forward direction, It is a partial top view which shows the structure of the back side of the movement seen from the dial plate in the state which the date indicator is rotating 1 pitch in the forward direction and "30" is displayed by the third date indicator. In the second embodiment of the timepiece with calendar mechanism of the present invention, it is seen from the dial side in the state in which the third date indicator starts rotating in the forward direction by the first date indicator from the state shown in FIG. It is a fragmentary top view which shows the structure of the back side of a movement. In the second embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 22, the first date indicator rotates one pitch in the forward direction, the third date indicator rotates one pitch in the forward direction, It is a partial top view which shows the structure of the back side of the movement seen from the dial side in the state which the date indicator is rotating 1 pitch in the forward direction and "31" is displayed by the third date indicator. In the second embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 23, the first date indicator rotates in the forward direction, and the third date indicator rotates counterclockwise by the first date indicator. FIG. 10 is a partial plan view showing the structure of the back side of the movement as viewed from the dial side in a state where the second date indicator is rotating clockwise by the third date indicator. In the second embodiment of the timepiece with calendar mechanism of the present invention, from the state shown in FIG. 24, the first date indicator rotates one pitch in the forward direction, the second date indicator rotates one pitch in the forward direction, When the date indicator is rotated by 1 pitch in the forward direction, “0” is displayed by the second date indicator, and “1” is indicated by the first date indicator, the back side of the movement viewed from the dial side. It is a fragmentary top view which shows a structure. FIG. 2 is a block diagram showing a drive circuit, a front train wheel, a calendar mechanism, and the like in the first embodiment of the timepiece with calendar mechanism of the present invention. FIG. 6 is a block diagram showing a drive circuit, a front train wheel, a calendar mechanism, and the like in the second embodiment of the timepiece with calendar mechanism of the present invention. In embodiment of the timepiece with a calendar mechanism of this invention, it is a schematic plan view which shows a structure when a movement is seen from the back cover side. In embodiment of the timepiece with a calendar mechanism of this invention, it is a fragmentary sectional view which shows the part of a winding stem, a small iron wheel, and a 2nd wheel. In the embodiment of the timepiece with calendar mechanism of the present invention, it is an operation diagram for explaining the operation of the first date indicator, the second date indicator, and the third date indicator in a normal state. In the embodiment of the timepiece with calendar mechanism of the present invention, it is an operation diagram for explaining the operation of the first date indicator, the second date indicator, and the third date indicator in the first type of phase shift. In the embodiment of the timepiece with calendar mechanism of the present invention, it is an operation diagram for explaining the operation of the first date indicator, the second date indicator and the third date indicator in the second type of phase shift.

(1) Structure of timepiece with calendar mechanism of the present invention Hereinafter, a first embodiment of a timepiece with a calendar mechanism of the present invention of a timepiece with a calendar mechanism of the present invention will be described with reference to the drawings.

(1.1) Overall Configuration of Movement With reference to FIGS. 1, 2, 28 and 29, in the first embodiment of the timepiece with calendar mechanism of the present invention, the movement 100 is constituted by an analog electronic timepiece. The movement 100 includes a main plate 102 constituting a substrate of the movement 100 and a date indicator presser 502. A dial 104 is attached to the movement 100. The dial 104 is attached to the glass side of the movement 100. In the movement 100, the “front side” indicates the side farther from the dial plate 104, that is, the “back cover side” of both sides of the main plate 102. In the movement 100, “back side” indicates a side closer to the dial plate 104, that is, a “dial plate side” of both surfaces of the base plate 102.

  The date indicator presser 502 is disposed on the “back side” in the movement 100. A winding stem 410 is rotatably incorporated in the main plate 102. The pinion wheel 472 is disposed so as to have the same rotation axis as that of the winding stem 410. The setting wheel 474 is arranged on the rotation axis of the winding stem 410 so as to have a rotation center. The switching device / setting device includes a winding stem 410, a setting lever 468, and a winding stem positioning portion 662 f of the battery plus terminal 662. The switching device is arranged on the “front side” in the movement 100. The switching device can be arranged on the “back side” in the movement 100.

(1.2) Configuration on the Front Side of the Movement The configuration on the front side of the movement will be described below. Referring to FIGS. 2 and 28, in movement 100, battery 440 that constitutes the power source of the timepiece is arranged on the back cover side (front side) of main plate 102. A crystal unit 650 constituting the source oscillation of the timepiece is disposed on the back cover side of the main plate 102. For example, a crystal unit that oscillates at 32,768 Hz is accommodated in the crystal unit 650. An oscillation unit (oscillator) 602 that outputs a reference signal based on the vibration of the crystal unit, a frequency division control unit 604 that controls the operation of the step motor by dividing the output signal of the oscillation unit 602, and a frequency division A motor drive unit (driver) 606 that outputs a motor drive signal for driving the step motor based on the output signal of the control unit 604 is built in the integrated circuit (IC) 654. The integrated circuit 654 is configured by, for example, C-MOS or PLA. When the integrated circuit 654 is configured by C-MOS, the oscillation unit 602, the frequency division control unit 604, and the motor drive unit 606 are built in the integrated circuit 654. When the integrated circuit (IC) 654 is configured by PLA, the oscillation unit 602, the frequency division control unit 604, and the motor driving unit 606 are configured to operate according to a program stored in the PLA.

  The crystal unit 650 and the integrated circuit 654 are fixed to the circuit board 610. The circuit board 610, the crystal unit 650, and the integrated circuit 654 constitute a circuit block 612. The circuit block 612 is disposed on the back cover side of the main plate 102. Furthermore, in the timepiece with calendar of the present invention, external elements such as a resistor, a capacitor, a coil, and a diode can be used as necessary. The battery minus terminal 660 is provided for conducting the cathode of the battery 440 and the minus pattern of the circuit board 610. The battery plus terminal 662 is provided to connect the anode of the battery 440 and the plus pattern of the circuit board 610. A rotor 634 including a coil block 630 including a coil wire wound around a magnetic core, a stator 632 disposed so as to contact both end portions of the magnetic core of the coil block 630, and a rotor magnet 634b disposed in a rotor hole 632c of the stator 632 Are arranged on the back cover side of the main plate 102.

  The coil block 630, the stator 632, and the rotor 634 constitute a step motor. The fifth wheel & pinion 441 is configured to rotate by the rotation of the rotor 634. By the rotation of the fifth wheel & pinion 441, the fourth wheel & pinion 442 is configured to rotate. The third wheel & pinion 444 is configured to rotate by the rotation of the fourth wheel & pinion 442. The second wheel & pinion 446 is configured to rotate by the rotation of the third wheel & pinion 444. By the rotation of the center wheel & pinion 446, the minute wheel 448 is configured to rotate. The hour wheel 480 is configured to rotate by the rotation of the minute wheel 448.

  The fourth wheel & pinion 442 is configured to rotate once per minute. A second hand 460 is attached to the fourth wheel & pinion 442. The center wheel & pinion 446 is configured to rotate once per hour. A minute hand 462 is attached to the center wheel & pinion 446. A slip mechanism is provided in the center wheel & pinion 446. When the hands are aligned by the slip mechanism, the minute hand 462 and the hour hand 464 can be rotated by rotating the winding stem 410 while the second hand 460 is stopped. A setting lever 468 is provided for setting the gear portion of the fifth wheel & pinion 441 and stopping the rotation of the second hand 460 when the winding stem 410 is pulled out to the second stage to adjust the hand.

  The center pipe 102c is fixed to the main plate 102. The center pipe 102 c extends from the back cover side of the main plate 102 to the dial side of the main plate 102. The center wheel & pinion 446 is rotatably supported in the hole of the center pipe 102c. The abacus ball of the fourth wheel & pinion 442 is rotatably supported in the hole of the second wheel & pinion 446. A train wheel bridge 458 is disposed on the back cover side of the main plate 102. The upper shaft portion of the rotor 634, the upper shaft portion of the fifth wheel 441, the upper shaft portion of the fourth wheel 442, the upper shaft portion of the third wheel 444, and the upper shaft portion of the sun wheel 448 are connected to the train wheel bridge 458. It is rotatably supported. The lower shaft portion of the rotor 634, the lower shaft portion of the fifth wheel & pinion 441, the lower shaft portion of the third wheel & pinion 444, and the lower shaft portion of the minute wheel 448 are rotatably supported by the main plate 102.

(1-3) Configuration of hour display train wheel The configuration of the hour display train wheel will be described below. Referring to FIGS. 2, 28 and 29, in movement 100, hour wheel 480 includes a cylindrical gear 480a and a date feeding gear 480b. The hour wheel 480 is configured to rotate once in 12 hours. An hour hand 464 is attached to the hour wheel 480. By the hour hand 464 attached to the hour wheel 480, “hour” is displayed in “12 hour system” in which one round is 12 hours.

(1/4) Configuration of Switching Mechanism and Needle-Aligning Mechanism The configuration of the switching mechanism and the needle-matching mechanism will be described below. 2 and 29, in the movement 100, a winding stem 410 is rotatably incorporated in the main plate 102. The winding stem 410 includes a tip shaft portion 410a, a first corner portion 410b, a first shaft portion 410c, a setting operation shaft portion 410d, a second shaft portion 410e, and a second corner portion formed in order from the tip side. 410f, the 3rd axial part 410g, the 1st abacus ball part 410h, the 2nd abacus ball part 410j, and the former axial part 410k are included. The tip shaft portion 410 a of the winding stem 410 is incorporated so as to be rotatable with respect to the winding stem tip hole of the main plate 402. The original shaft portion 410k of the winding stem 410 is incorporated so as to be rotatable with respect to the winding stem original hole of the main plate 402. The outer diameter of the first abacus ball portion 410h is preferably configured to be larger than the outer diameter of the second abacus ball portion 410j.

  The pinion wheel 472 is disposed so as to have the same rotation axis as that of the winding stem 410. When the winding stem 410 is at the 0th stage and the 1st stage, the interlocking square hole of the pinion wheel 472 is rotatable with respect to the first shaft portion 410c of the winding stem 410, and the winding stem 410 is rotated to be tangled. The vehicle 472 is configured not to rotate. When the winding stem 410 is in the second stage, the interlocking angular hole of the pinion wheel 472 is fitted with the first corner portion 410b of the winding stem 410 so that the pinion wheel 472 rotates based on the rotation of the winding stem 410. Composed. When the winding stem 410 is in the 0th stage, the winding stem positioning portion 662f of the battery plus terminal 662 is configured to be positioned between the main shaft portion 410k and the second abacus ball portion 410j.

  When the winding stem 410 is in the first stage, the winding stem positioning portion 662f of the battery plus terminal 662 is configured to be positioned between the first abacus ball portion 410h and the second abacus ball portion 410j. When the winding stem 410 is in the second stage, the winding stem positioning portion 662f of the battery plus terminal 662 is configured to be positioned between the first abacus ball portion 410h and the third shaft portion 410g. Therefore, in the switching device having the above configuration, the winding stem 410 can be positioned at three axial positions (the 0th stage, the first stage, and the second stage) by the winding stem positioning part 662f of the battery plus terminal 662. .

  When the winding stem 410 is in the 0th stage, and when the winding stem 410 is in the 1st stage, the setting lever 468 does not come into contact with the setting lever 468 so that the setting operation shaft portion 410d of the winding stem 410 does not contact the fifth wheel. It is comprised so that the gear part of 441 may not be regulated. When the winding stem 410 is in the second stage, the setting operation shaft portion 410 d of the winding stem 410 is configured to come into contact with the setting lever 468 to set the gear portion of the fifth wheel & pinion 441.

  First calendar correction wheel 590 is arranged to have the same rotation axis as that of winding stem 410. When the winding stem 410 is in the 0th stage, the interlocking round hole of the first calendar correcting wheel 590 can rotate with respect to the third shaft portion 410g of the winding stem 410, and even if the winding stem 410 is rotated, the first calendar The correction wheel 590 is configured not to rotate. When the winding stem 410 is in the first stage, the interlocking round hole of the first calendar correction wheel 590 is fitted with the second corner portion 410f of the winding stem 410, and the first calendar correction wheel 590 is moved based on the rotation of the winding stem 410. Configured to rotate. When the winding stem 410 is in the second stage, the interlocking round hole of the first calendar correcting wheel 590 can be rotated with respect to the second shaft portion 410e of the winding stem 410, and the first calendar can be rotated even if the winding stem 410 is rotated. The correction wheel 590 is configured not to rotate.

  The minute wheel 448 a of the minute wheel 448 is arranged to mesh with the small iron wheel 449. The small iron wheel 449 is disposed between the main plate 402 and the train wheel bridge 458. A minute wheel (not shown) of the minute wheel 448 is located on the dial side of the main plate 402 and is configured to mesh with the cylindrical gear 480a of the hour wheel 480. The hole portion of the hour wheel 480 is rotatably supported by the outer peripheral portion of the shaft portion of the center pipe 402c.

(1.7) Configuration of Calendar Mechanism The configuration of the calendar mechanism in the first embodiment of the timepiece with the calendar mechanism of the present invention will be described below. Referring to FIGS. 1 and 2, in movement 100, the date feeding mechanism includes a date indicator driving wheel 510 and a first date jumper 514. The date driving wheel 510 includes a date driving gear 510c and a date driving claw 510d. The date feeding gear 480b of the hour wheel 480 meshes with the date driving gear 510c. By rotating the hour wheel 480, the date driving wheel 510 is configured to rotate once in 24 hours. The center of rotation of the intermediate wheel 530 is arranged at “6 o'clock side”, or at a position between “5 o'clock side” and “6 o'clock side”, or “6 o'clock side” and “8” It is preferable to be disposed at a position between the “hour side”.

  A first date wheel 512 is rotatably incorporated in the main plate 102. The first day jumper 514 is incorporated in the main plate 102. The first day jumper 514 includes a spring part and a setting part provided at the tip of the spring part. The setting part of the first day jumper 514 sets the tooth part of the first date indicator 512. By rotating the date indicator driving wheel 510, the first date indicator 512 is configured to rotate once per day by one pitch (one tooth).

(1 · 7 · 1) Configuration of the first date indicator Hereinafter, in the first embodiment of the timepiece with calendar mechanism of the present invention, a configuration in which the date window 104f is formed at the 12 o'clock position of the dial 104 will be described. explain. However, the calendar mechanism of the timepiece with calendar mechanism of the present invention can also be applied to the case where the date window is formed at a position other than 12:00 on the dial 104.

  Referring to FIGS. 1 and 2, the movement 100 includes a date indicator driving wheel 510 that is rotated by the rotation of the hour wheel 480, a first date indicator 512 that can display one of the dates, and a first date. The first date jumper 514 for setting the rotational position of the car 512, the second date indicator 522 that can display the tenth place of the date, and the rotational position of the second date indicator 522 Second date jumper 524 for setting, third date indicator 532 capable of displaying a specific date alone, and second date indicator 522 by rotating based on the rotation of third date indicator 532 And an intermediate day wheel 530 that can be used. In the embodiment of the calendar mechanism of the timepiece with calendar mechanism of the present invention, specific dates that can be displayed by the third date indicator 532 are, for example, “30” and “31”.

  The first date wheel 512 is provided to be rotatable with respect to the main plate 102. The second date indicator 522 is provided to be rotatable with respect to the hour wheel 480. The rotation center of the first date indicator 512 and the rotation center of the second date indicator 522 are at the same position. That is, the rotation center of the first date indicator 512 and the rotation center of the second date indicator 522 are arranged at the same position as the rotation center of the hour hand 464 (that is, the rotation center of the hour wheel 480). The date intermediate wheel 530 is rotatably provided with respect to a date intermediate wheel pin (not shown) fixed to the date dial presser 502. The setting part of the first day jumper 514 can set the tooth part of the first date indicator 512. The center shaft 532p of the third date indicator 532 is preferably incorporated so as to be rotatable with respect to the main plate 102.

  The first date indicator 512 has a first date letter display surface 512f. Second date indicator 522 has second date character display surface 522f. The third date indicator 532 has a third date character display surface 532f. The second date character display surface 522f is disposed at a position closer to the dial 104 than the first date character display surface 512f. The third date character display surface 532f is disposed at a position closer to the dial 104 than the second date character display surface 522f. The third date indicator 532 is configured to be able to rotate by the rotation of the first date indicator 512. When the third date indicator 532 rotates, the second date indicator 522 is configured to be able to rotate. In a state where the third date indicator 532 is in a specific rotational direction, the third date indicator 532 is configured to rotate only when the first date indicator 512 is in a specific rotational direction. .

  Referring to FIG. 3, the first date indicator 512 includes a ring-shaped first date letter display surface 512f. The first date indicator 512 includes 31 first date indicator teeth portions 516 formed as internal teeth, and five calendar feed teeth 518a to 518e formed as internal teeth. The diameter of the tip circle of the first date wheel tooth portion 516 is smaller than the diameter of the tip circle of the calendar feed teeth 518a to 518e. The first date indicator teeth portion 516 is formed at an equal angular interval, that is, an angular interval of (360/31) degrees.

  The calendar feed dog has a first calendar feed dog 518a as a reference and an angular interval of (360 * 10/31) degrees in the first direction (ie, clockwise direction) with reference to the first calendar feed dog 518a. With reference to the formed second calendar feed dog 518b and the second calendar feed dog 518b, the first calendar is formed at an angular interval of (360 * 10/31) degrees in the first direction (ie, clockwise direction). A third calendar feed dog 518c and a fourth calendar feed dog 518d formed at an angular interval of (360/31) degrees in the first direction (ie, clockwise direction) with reference to the third calendar feed dog 518c; The fifth calendar feed dog 51 formed at an angular interval of (360/31) degrees in the first direction (that is, clockwise direction) with reference to the fourth calendar feed dog 518d. Configured to include an e. As will be described later, only the fifth calendar feed tooth 518e of the first date indicator 512 is configured to be able to mesh with the first first date indicator meshing tooth 534a of the third date indicator 532. . In other words, the fifth calendar feed dog 518e of the first date indicator 512 is formed longer than the other four calendar feed teeth 518a to 518d. The four calender feed teeth 518a to 518d are preferably formed to have the same tooth height.

  A first date character 512h composed of 29 numbers is provided on the first date character display surface 512f. That is, the first date letters 512h are “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, “0”, “ “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, “0”, “1”, “2”, “3” , “4”, “5”, “6”, “7”, “8”, “9”. The 29 numbers constituting the first date character 512h are arranged on the first date character display surface 512f at equal angular intervals, that is, (360/31) degree angular intervals. There is a portion where nothing is described between the first number “1” and the last number “9”. The portion where nothing is described is arranged on the first date letter display surface 512f so as to include an angular range in the circumferential direction of (360 * 2/31) degrees.

(1 · 7 · 2) Configuration of the second date indicator Referring to FIG. 4, in the first embodiment of the timepiece with calendar mechanism of the present invention, the second date indicator 522 is a disc provided with nine windows. A second date character display surface 522f having a shape is provided. The second date indicator 522 further includes 15 positioning tooth portions 526 formed as external teeth. The positioning teeth 526 are formed at equal angular intervals, for example, (360/15) degree angular intervals. The center through hole 522h of the second date indicator 522 is preferably incorporated so as to be rotatable with respect to the outer peripheral cylindrical portion of the second date indicator guide pipe provided in the date indicator holder 502. The setting portion of the second date jumper 524 can set the positioning tooth portion 526 of the second date indicator 522.

  The second date indicator 522 has a second date character display surface 522f. On the second date character display surface 522f, the numbers “0”, “1”, and “2” for displaying the tenth digit of the date have an equal angular interval, that is, (360/15) degrees. Provided at angular intervals. In the illustrated embodiment, three sets of numbers “0”, “1”, and “2” are provided. The three “0” numbers are provided at an angular interval of (360/3) degrees. The three “1” numbers are provided at an angular interval of (360/3) degrees. The three “2” numbers are provided at an angular interval of (360/3) degrees. The numbers “0”, “1”, and “2” are arranged within an angle range of (360/30) degrees. Alternatively, instead of providing the number “0”, a configuration in which the position is a “blank” portion (that is, a plain portion where no number is provided) can be applied.

  On the second date character display surface 522f of the second date indicator 522, the first “0” number for displaying the tens place and the first “1” number for displaying the tens place A window portion 522k1 is formed between them. A window 522k2 is formed between the first “1” number for displaying the tens place and the first “2” number for displaying the tens place. A window portion 522k3 is formed between the first “2” number for displaying the tens place and the second “0” number for displaying the tens place. A window 522k4 is formed between the second “0” number for displaying the tens place and the second “1” number for displaying the tens place. A window portion 522k6 is formed between the second “1” number for displaying the tens place and the second “2” number for displaying the tens place. A window portion 522k6 is formed between the second “2” number for displaying the tens place and the third “0” number for displaying the tens place. A window portion 522k7 is formed between the third "0" number for displaying the tens place and the third "1" number for displaying the tens place. A window 522k8 is formed between the third "1" number for displaying the tens place and the third "2" number for displaying the tens place. A window 522k9 is formed between the third "2" number for displaying the tens place and the first "0" number for displaying the tens place.

  That is, in the second date indicator 522, a set of a window portion 522k1, a window portion 522k2, a window portion 522k3, a set of a window portion 522k4, a window portion 522k5, a window portion 522k6, a window portion 522k7, a window portion 522k8, a window portion 522k9. Are provided. The center of the window part 522k1 and the center of the window part 522k2 are formed at an angular interval of (360/15) degrees, for example. The angular range in the circumferential direction that forms the window 522k1 is formed to include an angular range of (360/30) degrees, for example. The angular range in the circumferential direction that forms the window 522k2 is formed to include an angular range of (360/30) degrees, for example. The angular range in the circumferential direction that forms the window portion 522k3 is formed to include an angular range of (360 * 2.5 / 15) degrees, for example. The set of the window portion 522k4, the window portion 522k5, and the window portion 522k6 is configured to have the same shape and arrangement as the set of the window portion 522k1, the window portion 522k2, and the window portion 522k3. Further, the set of the window portion 522k7, the window portion 522k8, and the window portion 522k9 is configured to have the same shape and arrangement as the set of the window portion 522k1, the window portion 522k2, and the window portion 522k3.

  Alternatively, instead of forming the window portion, a notch portion having the same shape can be formed on the second date character display surface 522f. Alternatively, instead of forming the window portion, the second date letter display surface 522f is formed of a transparent material (for example, transparent plastic such as acrylic), and the same shape as the window portion is maintained transparent, It can also be printed. In this configuration, the numbers can be printed so that the second date character display surface 522f excluding the window portion is white and the numbers are black characters. In the movement 100, one of the numbers on the first date letter display surface 512 f of the first date indicator 512 can be arranged under the window portion of the second date indicator 522. The second date character display surface 522f is disposed at a position closer to the dial 104 than the first date character display surface 512f. In the state shown in FIG. 4, the date window 104 f of the dial 104 is arranged with a number “2” for displaying the tenth place of the date on the second date character display surface 522.

(1 · 7 · 3) Configuration of the third date indicator Referring to FIG. 5, in the first embodiment of the timepiece with calendar mechanism of the present invention, the third date indicator 532 includes a third date plate 533, a first date indicator 533, and a first date indicator 533. A date wheel meshing gear 534 and a date intermediate wheel driving gear 535 are included. The center shaft 532p of the third date indicator 532 is preferably incorporated so as to be rotatable with respect to the main plate 102. Alternatively, a center hole may be provided in the third date indicator 532 and the center hole may be incorporated so as to be rotatable with respect to an axis fixed to the main plate 102. The center of rotation of the third date indicator 532 is preferably arranged on the “12 o'clock side”.

  The third date plate 533 includes a disk-shaped third date character display surface 532f. The third date character display surface 532f has a third date character print surface 532m formed so that the open angle with respect to the center is (360 * 2/5) degrees, and the open angle with respect to the center is (360 * 3/5). And a non-printing surface 532n formed to have a degree. On the third date character printing surface 532g, the third date characters “30” and “31” are printed with the background as a white background. The non-printing surface 532n is formed of a transparent material using a plastic such as acrylic. In this configuration, the numbers can be printed so that the second date character display surface 522f excluding the window portion is white and the numbers are black characters. Instead of providing the non-printing surface 532n, a notch portion formed so that the opening angle with respect to the center is 240 degrees can be formed.

The first date indicator meshing gear 534 includes five first date indicator meshing teeth 534a to 534e formed as external teeth. The first date wheel meshing teeth 534a to 534e are formed at an equal angular interval, for example, an angular interval of (360/5) degrees. The first first date indicator meshing teeth 534a are formed such that their tooth lengths are shorter than those of the other four first date indicator meshing teeth 534b to 534e . The four first date indicator meshing teeth 534b to 534e are preferably formed to have the same tooth height.

  The first first date indicator meshing tooth 534a is configured not to be able to mesh with the first calendar feed tooth 518a of the first date indicator 512. The first first date indicator meshing tooth 534a is configured not to be able to mesh with the second calendar feed tooth 518b of the first date indicator 512. The first first date indicator meshing tooth 534a is configured not to be able to mesh with the third calendar feed tooth 518c of the first date indicator 512. The first first date indicator meshing tooth 534a is configured so as not to mesh with the fourth calendar feed tooth 518d of the first date indicator 512. On the contrary. The first first date indicator meshing teeth 534a are configured to be able to mesh with the fifth calendar feed teeth 518e of the first date indicator 512.

  The second date indicator meshing tooth 534b is configured to be able to mesh with four calendar feed teeth other than the first calendar feed tooth 518a in the first date indicator 512. The third first date indicator meshing tooth 534c is configured to be able to mesh with four calendar feed teeth other than the first calendar feed tooth 518a in the first date indicator 512. The fourth first date indicator meshing tooth 534d is configured to be able to mesh with four calendar feed teeth other than the first calendar feed tooth 518a in the first date indicator 512. The fifth first date indicator meshing tooth 534e is configured to be able to mesh with four calendar feed teeth other than the first calendar feed tooth 518a in the first date indicator 512.

  On the third date character display surface 532f, numbers “30” and “31” for displaying a specific date independently are provided at equal angular intervals, that is, at an angular interval of (360/5) degrees. The two numbers “30” and “31” are arranged within an angle range of (360/5) degrees, respectively. The first date indicator meshing teeth 534a are arranged so as to be rotated by the calendar feed teeth of the first date indicator 512 in a state in which the numeral “31” is displayed.

  In the movement 100, below the non-printing surface 532n of the third date indicator 532, one of the numbers on the second date character display surface 522f of the second date indicator 522 and the first date character of the first date indicator 512 are displayed. One of the numbers on the display surface 512f can be arranged. The second date character display surface 522f is disposed at a position closer to the dial 104 than the first date character display surface 512f. The third date character display surface 532f is disposed at a position closer to the dial 104 than the second date character display surface 522f.

  The date intermediate wheel drive gear 535 includes ten date intermediate wheel meshing teeth formed as external teeth. The date intermediate wheel meshing tooth of the date intermediate wheel drive gear 535 is configured to mesh with the third date wheel meshing tooth of the date intermediate wheel 530 and transmit the rotation. The intermediate wheel meshing teeth are formed at an equal angular interval, for example, an angular interval of (360/10) degrees. The date intermediate wheel drive gear 535 is provided at a position closer to the dial 104 than the first date wheel meshing gear 534.

(1 · 7 · 4) Configuration of the date intermediate wheel Referring to FIG. 1 and FIG. 2, in the first embodiment of the timepiece with calendar mechanism of the present invention, the date intermediate wheel 530 has 10 pieces formed as external teeth. Including third day wheel meshing teeth. The third date indicator meshing teeth are formed at an equal angular interval, for example, an angular interval of (360/10) degrees. The date intermediate wheel drive gear 535 is provided at a position closer to the dial 104 than the first date wheel meshing gear 534. The third date indicator meshing tooth of the date intermediate wheel 530 is configured to mesh with the date intermediate date meshing tooth of the third date indicator 532 so as to transmit rotation. Further, the third date indicator meshing tooth of the date intermediate wheel 530 is configured to mesh with the positioning tooth portion 526 of the second date indicator 522 and transmit the rotation.

  A center shaft (not shown) of the date intermediate wheel 530 can be incorporated so as to be rotatable with respect to the main plate 102 and the date wheel holder. Alternatively, a center hole may be provided in the date intermediate wheel 530, and the center hole may be incorporated so as to be rotatable with respect to a shaft fixed to the main plate 102 or the date indicator holder. Alternatively, a center hole may be provided in the date intermediate wheel 530, and the date intermediate wheel 530 may be fixed to the date wheel holder so that the center hole can rotate with respect to an axis fixed to the date wheel holder. It is preferable that the center of rotation of the date intermediate wheel 530 is arranged at “12 o'clock side”. The rotation center of the first date indicator 512, the rotation center of the third date indicator 532, and the rotation center of the intermediate date wheel 530 are arranged on a straight line orthogonal to the rotation center axis of the winding stem 410. preferable.

(1.8) Action of calendar feeding (1, 8, 1) State before rotating the 1st date indicator in the forward direction Next, in the first embodiment of the timepiece with calendar mechanism of the present invention, The operation will be described. FIG. 8 shows the movement 100 as viewed from the dial side in the state before rotating the first date indicator 512 (that is, the state before date feeding) in the first embodiment of the timepiece with calendar mechanism of the present invention. It is a top view which shows the structure of a back side.

  Referring to FIGS. 2, 8, 26 and 29, the battery 440 constitutes the power source of the timepiece. The crystal resonator accommodated in the crystal unit 650 oscillates at, for example, 32,768 hertz. Based on the vibration of the crystal resonator, the oscillation unit 602 built in the integrated circuit 654 outputs a reference signal, and the frequency division control unit 604 divides the output signal of the oscillation unit 602. The motor drive unit 606 outputs a motor drive signal for driving the step motor to the coil block 630 based on the output signal of the frequency division control unit 604. When the coil block 630 receives a motor drive signal, the stator 632 is magnetized to rotate the rotor 634. For example, the rotor 634 rotates 180 degrees every second. Based on the rotation of the rotor 634, the fourth wheel & pinion 442 rotates through the rotation of the fifth wheel & pinion 441. The fourth wheel & pinion 442 rotates once per minute. The second hand 460 attached to the fourth wheel & pinion 442 displays “second” in the time information.

  The third wheel & pinion 444 rotates based on the rotation of the fourth wheel & pinion 442. The second wheel & pinion 446 rotates based on the rotation of the third wheel & pinion 444. A minute wheel may be used instead of the second wheel & pinion 446. The center wheel & pinion 446 makes one rotation per hour. The minute hand 462 attached to the center wheel & pinion 446 displays “minute” in the time information. A slip mechanism is provided in the center wheel & pinion 446. When the hands are aligned by the slip mechanism, the minute hand 462 and the hour hand 464 are rotated by rotating the winding stem 410 while the second hand 460 is stopped by setting the gear portion of the fifth wheel & pinion 442 by the setting lever 468. Can be rotated. The minute wheel 448 rotates based on the rotation of the center wheel & pinion 446. The hour wheel 480 rotates based on the rotation of the minute wheel 448. The hour wheel 480 rotates once every 12 hours. “Hour” in the time information is displayed by an hour hand 464 attached to the hour wheel 480.

  With reference to FIGS. 8 and 26, the date driving wheel 510 rotates based on the rotation of the hour wheel 480. As the date indicator driving wheel 510 rotates, the date indicator driving finger 510d of the date indicator driving wheel 510 rotates the first date indicator 512. Referring to FIG. 8, when the date indicator driving wheel 510 rotates in the direction indicated by the arrow (counterclockwise direction), the date indicator driving claw 510d feeds the first date indicator tooth portion 516, once a day, The date wheel 512 can be rotated in the clockwise direction.

  The setting portions 524 c and 524 d of the second date jumper 524 set the positioning tooth portion 526 of the second date indicator 522. The date driving wheel 510 includes one date driving claw 510d. The date driving wheel 510 can rotate in the direction indicated by the arrow (counterclockwise direction). The date intermediate wheel 530 includes ten date intermediate teeth 530a formed as external teeth. The date character displayed from the date window 104 f of the dial 104 by the second date indicator 522 is “2”, and the date character of the first date indicator 512 that can be seen through the window of the second date indicator 522 is “ 9 ”. On the non-printing surface 532 n of the third date indicator 532, a portion adjacent to the numeral “30” in the counterclockwise direction is disposed below the date window 104 f of the dial 104. That is, the second date indicator 522 and the first date indicator 512 display the current date “29” from the date window 104 f of the dial 104 through the non-printing surface 532 n of the third date indicator 532.

(1 · 8 · 2) State in which the first date indicator is going to rotate in the forward direction FIG. 9 shows the first date indicator 512 in the forward direction (counterclockwise) in the first embodiment of the timepiece with calendar mechanism of the present invention. It is a partial top view which shows the structure on the back side of the movement 100 seen from the dial side in the state (namely, state which started date feeding) which is going to rotate in the clockwise direction. Referring to FIG. 9, the setting portions 524 c and 524 d of the second date jumper 524 set the positioning tooth portion 526 of the second date indicator 522. When the date indicator driving wheel 510 rotates in the direction indicated by the arrow (counterclockwise direction), the date indicator driving claw 510d starts to feed the first date indicator tooth portion 516 and rotates the first date indicator 512 counterclockwise. . As the first date indicator 512 rotates counterclockwise, the third calendar feed dog 518c starts to rotate the fourth first date indicator meshing tooth 534d of the third date indicator 532. The second first date indicator meshing tooth 534b of the third date indicator 532 starts an operation of rotating the date intermediate wheel drive gear 535. The date intermediate wheel drive gear 535 operates to rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 starts an operation of rotating the positioning tooth portion 526 of the second date indicator 522.

(1 / 8.3) State in which the first date indicator is rotated in the forward direction FIG. 10 shows the first date indicator 512 in the forward direction (counterclockwise) in the first embodiment of the timepiece with calendar mechanism of the present invention. The first date indicator 512 is rotated in the forward direction in the middle of being rotated in the rotation direction), the tip of the tooth portion 516 of the first date indicator 512, and the setting portion 514c of the first date jumper 514, It is a fragmentary top view which shows the structure of the back side of the movement 100 seen from the dial side in the state which is trying to contact the front-end | tip part which 514d crosses. Referring to FIG. 10, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the third calendar feed dog 518 c rotates the fourth first date indicator meshing tooth 534 d of the third date indicator 532. The second 1st date indicator meshing tooth 534b of the 3rd date indicator 532 rotates the date intermediate wheel drive gear 535. The date intermediate wheel drive gear 535 operates to rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522.

  In the middle of the feeding state of the first date indicator 512, the tip portion of the tooth portion 516 of the first date indicator 512 and the tip portion where the setting portions 514c and 514d of the first date jumper 514 intersect each other are in contact with each other. become. Further, in the middle of the feeding state of the second date indicator 522, the tip portion of the positioning tooth portion 526 of the second date indicator 522 is in contact with the tip portion where the setting portions 524c and 524d of the second date jumper 524 intersect. become.

(1 · 8 · 4) State in which the first date indicator is rotated by one pitch in the forward direction FIG. 11 shows the first date indicator 512 in the forward direction (counterclockwise) in the first embodiment of the timepiece with calendar mechanism of the present invention. FIG. 6 is a partial plan view showing a structure on the back side of the movement 100 as viewed from the dial side in a state where it is rotated by one pitch (one tooth of the first date indicator, ie, (360/31) degrees) in the rotation direction). . Referring to FIG. 11, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 10, and the date indicator driving finger 510 d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. The second date indicator 522 is positioned at a position rotated (360/15) degrees in the clockwise direction from the state shown in FIG. 8 by the elastic force of the second date jumper 524. The third date indicator 532 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the numeral “30” provided on the printing surface 532 m of the third date indicator 532 is arranged below the date window 104 f of the dial 104. Since the second date indicator 522 and the first date indicator 512 are located below the third date indicator 532, they cannot be seen from the date window 104 f of the dial 104. That is, as shown in FIG. 11, the third date indicator 532 is in a state of displaying the current date “30” alone.

(1 · 8 · 5) State in which the first date indicator is further rotated in the forward direction FIG. 12 shows the first date indicator 512 in the forward direction in the first embodiment of the timepiece with calendar mechanism of the present invention ( In the state of being rotated in the counterclockwise direction), the first date indicator 512 is further rotated in the forward direction, and the tip portion of the tooth portion 516 of the first date indicator 512 and the first date jumper 514 It is a fragmentary top view which shows the structure of the back side of the movement 100 seen from the dial plate in the state which the front-end | tip part which 514d and 514d cross | intersect is going to contact. Referring to FIG. 12, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the fourth calendar feed dog 518d rotates the fifth first date indicator meshing tooth 534e of the third date indicator 532. The third first date indicator meshing tooth 534c of the third date indicator 532 rotates the date intermediate wheel drive gear 535. The date intermediate wheel drive gear 535 operates to rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522.

(1.86) State in which the 1st date indicator is further rotated by one pitch in the forward direction FIG. 13 shows the first date indicator 512 in the forward direction (counterclockwise) in the first embodiment of the timepiece with calendar mechanism of the present invention. Partial plan view showing the structure of the back side of the movement 100 as viewed from the dial side in a state in which it is further rotated by one pitch (clockwise direction) (one tooth of the first date indicator, ie, (360/31) degrees). It is. Referring to FIG. 13, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 12, and the date indicator driving claw 510d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. Further, the second date indicator 522 is positioned at a position rotated clockwise (360/15) degrees from the state shown in FIG. 11 by the elastic force of the second date jumper 524. The third date indicator 532 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the number “31” provided on the printing surface 532 m of the third date indicator 532 is arranged below the date window 104 f of the dial 104. Since the second date indicator 522 and the first date indicator 512 are located below the third date indicator 532, they cannot be seen from the date window 104 f of the dial 104. That is, as shown in FIG. 13, the third date indicator 532 is in a state of displaying the current date, “31” day alone.

(1 · 8 · 7) State in which the 1st date indicator is further rotated in the forward direction FIG. 14 shows the first date indicator 512 in the 1st embodiment of the timepiece with calendar mechanism of the present invention. In the middle of rotating in the direction (counterclockwise direction), the first date indicator 512 further rotates in the forward direction, and the tip of the tooth portion 516 of the first date indicator 512 and the first date It is a fragmentary top view which shows the structure of the back side of the movement 100 seen from the dial side in the state which the front-end | tip part where the setting part 514c and 514d of the jumper 514 cross | intersect is going to contact. Referring to FIG. 14, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the fifth calendar feed dog 518e rotates the first first date indicator meshing tooth 534a of the third date indicator 532. The fourth first date indicator meshing tooth 534d of the third date indicator 532 rotates the date intermediate wheel drive gear 535. The date intermediate wheel drive gear 535 operates to rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522.

(1 · 8 · 8) State in which the 1st date indicator is further rotated by one pitch in the forward direction FIG. 15 shows a first embodiment of the timepiece with calendar mechanism according to the first embodiment of the present invention. Partial plane showing the structure of the back side of the movement 100 as viewed from the dial side in a state in which it is further rotated by one pitch (counterclockwise in the counterclockwise direction) (one tooth of the first date wheel, ie, (360/31) degrees). FIG. Referring to FIG. 15, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 14 and the date indicator driving finger 510 d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. Further, the second date indicator 522 is positioned at a position rotated clockwise (360/15) degrees from the state shown in FIG. 13 by the elastic force of the second date jumper 524. The third date indicator 532 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the date character displayed from the date window 104 f of the dial 104 by the second date indicator 522 is “0”, and the date of the first date indicator 512 that can be seen through the window portion of the second date indicator 522. The character is “1”. On the non-printing surface 532 n of the third date indicator 532, a portion adjacent in the clockwise direction from the number “31” is disposed below the date window 104 f of the dial 104. That is, the second date indicator 522 and the first date indicator 512 display the current date, “01” date, from the date window 104 f of the dial 104 through the non-printing surface 532 n of the third date indicator 532.

(1 · 8 · 9) Operation Changing from “01 Day” to “02 Day” In the first embodiment of the timepiece with calendar mechanism of the present invention, date display by the first date indicator 512 and the second date indicator 522 is performed. When the date changes from “01 day” to “02 day”, the date indicator driving wheel 510 rotates, so that the first date indicator 512 rotates counterclockwise. At this time, the third date indicator 532 does not rotate. As a result, the date letter displayed from the date window 104 f of the dial 104 by the second date indicator 522 remains “0” and can be viewed through the window portion of the second date indicator 522. The date letter of “1” changes from “1” to “2”. That is, the second date indicator 522 and the first date indicator 512 can display the current date “02” from the date window 104 f of the dial 104 through the non-printing surface 532 n of the third date indicator 532.

(1 · 8 · 10) Operation Changing from “09th” to “10th” In the first embodiment of the timepiece with calendar mechanism of the present invention, date display by the first date indicator 512 and the second date indicator 522 is performed. When the “9th” is changed to “10th”, the date indicator driving wheel 510 is rotated so that the first date indicator 512 is rotated counterclockwise. As the first date indicator 512 rotates, the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 532. The date intermediate wheel drive gear 535 of the third date indicator 532 rotates the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522. As a result, the date character displayed from the date window 104f of the dial 104 by the second date indicator 522 changes from “0” to “1”, and the first date that can be seen through the window portion of the second date indicator 522. The date character of the car 512 changes from “9” to “0”. That is, the second date indicator 522 and the first date indicator 512 can display the current date “10” from the date window 104 f of the dial 104 through the non-printing surface 532 n of the third date indicator 532. The same applies to the operation changing from the “19” day to the “20” day.

(1.9) Calendar Correction Mechanism In the first embodiment of the timepiece with calendar mechanism of the present invention, the configuration of the calendar correction mechanism and the operation for correcting the calendar will be described below.

(1.9.1) Configuration of Calendar Correction Mechanism In the first embodiment of the timepiece with a calendar mechanism of the present invention, the configuration of the calendar correction mechanism and the operation for correcting the calendar will be described below. Referring to FIGS. 1, 2, 28, and 29, in movement 100, the calendar correction mechanism includes a first calendar correction wheel 590, a second calendar correction wheel 591, and a date correction lever 593. The second calendar correction wheel 591 is configured to be able to rotate around a second calendar correction wheel pin provided on the main plate 102. The date correction lever pin 593b is fixed to the second calendar correction wheel 591. The rotation center axis of the date correction lever pin 593b is disposed at a position eccentric from the rotation center axis of the second calendar correction wheel 591. The date correction lever 593 is configured to be rotatable with respect to the shaft portion of the date correction lever pin 593b.

  The date correction lever 593 is configured to move eccentrically by the rotation of the second calendar correction wheel 591 so that the correction leading end of the date correction lever 593 can contact the first date wheel tooth portion 516. . The first date indicator 512 can be rotated by one pitch by the movement of the correction leading end of the date correction lever 593. In a state where the winding stem 410 is in the first stage, the interlocking hole of the first calendar correction wheel 590 is fitted with the second corner portion 410f of the winding stem 410, and the first calendar correction wheel 590 is moved based on the rotation of the winding stem 410. Configured to rotate.

  In this state, when the winding stem 410 is rotated in the first direction, for example, in the counterclockwise direction, the second calendar correction wheel 591 is rotated based on the rotation of the first calendar correction wheel 590. The The date correction lever 593 is moved based on the rotation of the second calendar correction wheel 591 so that the correction leading end of the date correction lever 593 can rotate the first date wheel 512 counterclockwise by one pitch. Configured. When the winding stem 410 is rotated in the first direction (direction to rotate counterclockwise) with the winding stem 410 pulled out to the first stage, the correction leading end of the date correction lever 593 causes the first date indicator 512 to be counterclockwise. By rotating the first date indicator 512 in the counterclockwise direction and the first date indicator 512 rotating counterclockwise, the third calendar feed tooth 518c is the fourth first date indicator meshing tooth 534d of the third date indicator 532. The intermediate date wheel driving gear 535 of the third date indicator 532 rotates the intermediate date indicator 530, and the third date indicator meshing tooth portion 530a of the intermediate date indicator 530 is positioned on the positioning tooth portion of the second date indicator 522. It is comprised so that 526 can be rotated.

  In the calendar correcting mechanism of the present invention, when the winding stem 410 is in the first stage, the “date correction” can be performed by rotating the winding stem 410 in the first direction (direction to rotate counterclockwise). Even if the winding stem 410 is rotated in the direction opposite to the first direction (direction to rotate clockwise), “date correction” cannot be performed.

(1.9.2) Operation when correcting from "01 day" to "02 day" In the first embodiment of the timepiece with calendar mechanism of the present invention, the date by the first date indicator 512 and the second date indicator 522. When the display of “01” is corrected to “02”, if the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise) with the winding stem 410 being pulled out to the first stage, The correction leading end of the correction lever 593 rotates the first date indicator 512 by one pitch in the counterclockwise direction. At this time, the 1st date indicator 512 rotates counterclockwise. As a result, the date letter displayed from the date window 104 f of the dial 104 by the second date indicator 522 remains “0” and can be viewed through the window portion of the second date indicator 522. The date letter of “1” changes from “1” to “2”.

(1 · 9 · 3) Operation when correcting from “09th” to “10th” In the first embodiment of the timepiece with calendar mechanism of the present invention, the date by the first date indicator 512 and the second date indicator 522 When the display is changed from “9 days” to “10 days”, if the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise) with the winding stem 410 pulled out to the first stage, the date The correction leading end of the correction lever 593 rotates the first date indicator 512 by one pitch in the counterclockwise direction. At this time, the first date indicator 512 rotates, so that the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 532. The date intermediate wheel drive teeth 535 of the third date indicator 532 rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522. As a result, the date character displayed from the date window 104f of the dial 104 by the second date indicator 522 changes from “0” to “1”, and the first date that can be seen through the window portion of the second date indicator 522. The date character of the car 512 changes from “9” to “0”. The same applies to the operation that changes from “19” to “20”.

(1.94) Operation when correcting from "29 days" to "30 days" In the first embodiment of the timepiece with calendar mechanism of the present invention, the date by the first date indicator 512 and the second date indicator 522 When the display of “29 days” is corrected and the display of the date is corrected to “30 days”, the winding stem 410 is pulled out to the first stage, and the winding stem 410 is rotated in the first direction (left rotation). , The correction leading end of the date correction lever 593 rotates the first date indicator 512 counterclockwise by one pitch. At this time, the 1st date indicator 512 rotates counterclockwise. As the first date indicator 512 rotates, the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 532. The first date indicator meshing tooth of the third date indicator 532 rotates the date intermediate wheel drive gear 535. The date intermediate wheel drive gear 535 rotates the positioning tooth portion 526 of the second date indicator 522. As a result, the third date indicator 532 alone can display the current date, “30” day.

(1.95) Operation when correcting from "30 days" to "31 days" In the first embodiment of the timepiece with calendar mechanism of the present invention, the date by the first date indicator 512 and the second date indicator 522 When the display of “30 days” is corrected to “31 days”, when the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise) with the winding stem 410 being pulled out to the first stage, the date The correction leading end of the correction lever 593 rotates the first date indicator 512 by one pitch in the counterclockwise direction. At this time, the 1st date indicator 512 rotates counterclockwise. As the first date indicator 512 rotates, the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 532. The date intermediate wheel drive teeth 535 of the third date indicator 532 rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522. As a result, the date character displayed from the date window 104 f of the dial 104 by the third date indicator 532 is changed from “30” to “31”.

(1.96) Operation when correcting from "31st" to "01th" In the first embodiment of the timepiece with calendar mechanism of the present invention, the date by the first date indicator 512 and the second date indicator 522 When the display is changed from “31 days” to “01 days”, if the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise) while the winding stem 410 is pulled out to the first stage, The correction leading end of the correction lever 593 rotates the first date indicator 512 by one pitch in the counterclockwise direction. At this time, the 1st date indicator 512 rotates counterclockwise. As the first date indicator 512 rotates, the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 532. The date intermediate wheel drive teeth 535 of the third date indicator 532 rotate the date intermediate wheel 530. The third date indicator meshing tooth portion 530a of the date intermediate wheel 530 rotates the positioning tooth portion 526 of the second date indicator 522. As a result, the date character “0” is displayed from the date window 104 f of the dial 104 by the second date indicator 522, and the date character “1” is displayed by the first date indicator 512 through the window portion of the second date indicator 522. be able to. In other words, the second date indicator 522 and the first date indicator 512 can display the current date “01” from the date window 104 f of the dial 104 through the non-printing surface 532 n of the third date indicator 532.

(1 · 10) Operation for correcting the phase shift of the date indicator due to calendar correction (1 · 10 · 1) Regular calendar display state Referring to FIG. 30, in the regular calendar display state, the first date indicator 512, the second date indicator A combination of numbers displayed by the date indicator 522 and the third date indicator 532 is shown. For example, in a state where “31” is displayed by the third date indicator 532, the second date indicator is displayed below the “31” number of the third date indicator 532 below the date window 104 f of the dial 104. There is no number for 522, and there is no number for the first date indicator 512.

(1 · 10 · 2) State in which the first phase is shifted Referring to FIG. 31, an impact is applied to the watch while “31” is displayed by the third date indicator 532, and only the first date indicator 512 is displayed. Is rotated by one pitch in the clockwise direction, there is no number for the second date indicator 522 under the number 31 for the third date indicator 532 under the date window 104f of the dial 104. The number “1” of the first date wheel 512 is arranged. In such a case, even if the clock advances so that the actual date becomes “1”, “31” displayed by the third date indicator 532 does not change, and thereafter, an inappropriate calendar display state is continued. The In the conventional timepiece, the timepiece is disassembled so that the combination of numbers displayed by the first date indicator 512, the second date indicator 522, and the third date indicator 532 is in the regular calendar display state shown in FIG. I had to fix it.

  According to the embodiment of the present invention, as shown in FIG. 31, an impact is applied to the timepiece while “31” is displayed by the third date indicator 532, and only the first date indicator 512 is clockwise. When the winding stem 410 is rotated in the first direction when rotated by one pitch and the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise), the date correction lever 593 is actuated for the first day. The car 512 can be rotated counterclockwise.

  When the third date indicator 532 is disposed at the position shown in FIG. 13 (provided that only the first date indicator 512 is rotated by one pitch in the clockwise direction), the winding stem 410 is rotated. Even if the first date indicator 512 is rotated, the second date indicator meshing teeth 534 b to the fifth date indicator engagement teeth 534 e of the third date indicator 532 are engaged with the first date indicator of the third date indicator 532. The teeth cannot be rotated. As described above, only the first date indicator meshing tooth 534a of the third date indicator 532 can mesh with the fifth calendar feed tooth 518e of the first date indicator 512. Therefore, the winding stem 410 is continuously rotated in the first direction (the direction in which it is rotated counterclockwise), and the first date indicator meshing of the third date indicator 532 is performed by the fifth calendar feed dog 518e of the first date indicator 512. By rotating the tooth 534a, it can be corrected to a normal calendar display state shown in FIG.

(1 · 10 · 3) State in which the second phase is shifted Referring to FIG. 32, an impact is applied to the watch while “31” is displayed by the third date indicator 532, and only the first date indicator 512 is displayed. Is rotated by 1 pitch in the counterclockwise direction, there is no number for the second date indicator 522 under the number 31 for the third date indicator 532 under the date window 104f of the dial 104. Although there is no number for the first date indicator 512, the first date indicator 512 is rotated by one pitch in the counterclockwise direction. In such a case, even if the clock advances so that the actual date is “1”, “1” cannot be displayed by the first date indicator 512. In such a case, “11” is displayed when the next “02” is to be displayed, and thereafter, an inappropriate calendar display state is continued. In the conventional timepiece, the timepiece is disassembled, and the combination of numbers displayed on the first date indicator 512, the second date indicator 522, and the third date indicator 532 is corrected so as to be in the normal state shown in FIG. I had to.

  According to the embodiment of the present invention, as shown in FIG. 32, only the first date indicator 512 is rotated by one pitch in the counterclockwise direction while “31” is displayed by the third date indicator 532. In this state, when the winding stem 410 is rotated in the first direction (the direction in which the winding stem 410 is rotated counterclockwise) with the winding stem 410 pulled out to the first stage, the first date indicator 512 is counteracted by the operation of the date correcting lever 593. It can be rotated in the clockwise direction.

  When the third date indicator 532 is disposed at the position shown in FIG. 13 (provided that only the first date indicator 512 is rotated by one pitch in the counterclockwise direction), the winding stem 410 rotates. Even if the first date indicator 512 is rotated by the second date indicator 512, the second date indicator meshing teeth 534b to the fifth date indicator engagement teeth 534e of the third date indicator 532 are engaged with the first date indicator of the third date indicator 532. I can't rotate my teeth. As described above, only the first date indicator meshing tooth 534a of the third date indicator 532 can mesh with the fifth calendar feed tooth 518e of the first date indicator 512. Therefore, the winding stem 410 is continuously rotated in the first direction (the direction in which it is rotated counterclockwise), and the first date indicator meshing of the third date indicator 532 is performed by the fifth calendar feed dog 518e of the first date indicator 512. By rotating the tooth 534a, it can be corrected to a normal calendar display state shown in FIG.

(2) Second embodiment:
Next, a second embodiment of the present invention will be described. In the following description, the difference between the second embodiment of the present invention and the first embodiment of the present invention will be mainly described. Therefore, the description of the first embodiment of the present invention described above applies mutatis mutandis to the portions not described below.

(2.1) Configuration of Calendar Mechanism The configuration of the calendar mechanism in the second embodiment of the timepiece with the calendar mechanism of the present invention will be described below. Referring to FIGS. 16 and 17, in movement 700, the date feeding mechanism includes a date indicator driving wheel 510 and a first date jumper 514. By rotating the hour wheel 480, the date driving wheel 510 is configured to rotate once in 24 hours. A first date wheel 512 is rotatably incorporated in the main plate 102. In the second embodiment of the timepiece with calendar mechanism of the present invention, the date indicator driving wheel 510, the first date jumper 514, and the first date indicator 512 can be configured in the same manner as in the first embodiment described above.

(2.2) Configuration of the second date indicator Referring to Fig. 6, in the second embodiment of the timepiece with calendar mechanism of the present invention, the second date indicator 722 has a disk shape provided with nine windows. A second date character display surface 722f is provided. In the second embodiment of the timepiece with calendar mechanism of the present invention, the second date character display surface 722f can be configured similarly to the second date character display surface 522f in the first embodiment described above. That is, on the second date letter display surface 522f of the second date indicator 722, the window portion 722k1 to the window portion 722k9 are formed. The second date character display surface 722f is disposed at a position closer to the dial 104 than the first date character display surface 512f.

  The second date indicator 722 further includes 15 third date indicator meshing teeth 725 formed as internal teeth. The third date indicator meshing tooth portions 725 are formed at an equal angular interval, for example, an angular interval of (360/15) degrees. The tooth tip portion of the third date indicator meshing tooth portion 725 is preferably incorporated so as to be rotatable with respect to the second date indicator guide portion provided on the date indicator holder 762.

  The second date indicator 722 further includes 15 positioning teeth 726 formed as internal teeth. The positioning teeth 726 are formed at an equal angular interval, for example, an angular interval of (360/15) degrees. The inner diameter of the tooth tip portion of the third date indicator meshing tooth portion 725 is formed to be larger than the inner diameter of the tooth tip portion of the positioning tooth portion 726. The setting portion of the second date jumper 574 can set the positioning tooth portion 726 of the second date indicator 722. The positioning tooth portion 726 of the second date indicator 722 is disposed at a position closer to the dial plate 104 than the third date indicator meshing tooth portion 725. It is preferable that the number of positioning teeth 726 provided be equal to the number of third date indicator meshing teeth 725 provided.

(2.3) Configuration of the third date indicator Referring to FIG. 7, in the second embodiment of the timepiece with calendar mechanism of the present invention, the third date indicator 732 includes a third date plate 733 and a first date indicator. A meshing gear 734 and a second date indicator driving gear 735 are included. The center shaft 732p of the third date indicator 732 is preferably incorporated so as to be rotatable with respect to the main plate 702. The third date plate 733 includes a disk-shaped third date character display surface 732f. The third date character display surface 732f has a third date character print surface 732m formed so that the open angle with respect to the center is (360 * 2/5) degrees, and the open angle with respect to the center is (360 * 3/5). And a non-printing surface 732n formed to have a degree. In the second embodiment of the timepiece with calendar mechanism of the present invention, the third date character display surface 732f can be configured in the same manner as the third date character display surface 532f in the first embodiment described above.

  The first date indicator meshing gear 734 includes five first date indicator meshing teeth 734a to 734e formed as external teeth. In the second embodiment of the timepiece with calendar mechanism of the present invention, the first date indicator meshing teeth 734a to 734e are configured in the same manner as the first date indicator meshing teeth 534a to 534e in the first embodiment described above. be able to.

  The drive gear 735 includes five second date indicator meshing teeth 735a to 735e formed as external teeth. The second date indicator meshing teeth are formed at an equal angular interval, for example, an angular interval of (360/5) degrees. The date intermediate wheel drive gear 735 is provided at a position closer to the dial 104 than the first date wheel meshing gear 734. In this configuration, the third date indicator 732 is configured to be able to directly rotate the second date indicator 722.

(2.4) Calendar feed action (2.4.1) State before rotating the first date indicator in the forward direction Next, in the second embodiment of the timepiece with calendar mechanism of the present invention, the calendar feed The operation will be described. FIG. 18 is a plan view showing a structure on the back side of the movement 700 as viewed from the dial side in a state before the first date indicator 512 is rotated (that is, a state before date feeding).

  18, 27, and 29, the date driving wheel 510 rotates based on the rotation of the hour wheel 480. As the date indicator driving wheel 510 rotates, the date indicator driving finger 510d of the date indicator driving wheel 510 rotates the first date indicator 512. Referring to FIG. 18, the second date indicator 722 and the first date indicator 512 display the current date, “29” date, from the date window 104 f of the dial 104 through the non-printing surface 732 n of the third date indicator 732. ing.

(2 ・ 4 ・ 2) State in which the first date indicator is about to be rotated in the forward direction FIG. 19 shows the first date indicator 512 in the forward direction (counterclockwise) in the second embodiment of the timepiece with calendar mechanism of the present invention. It is a partial top view which shows the structure of the back side of the movement 700 seen from the dial side in the state (namely, the state which started date feeding) which is going to rotate in the clockwise direction. Referring to FIG. 19, the setting portion of the second date jumper 724 sets the positioning tooth portion 726 of the second date indicator 722. When the date indicator driving wheel 510 rotates in the direction indicated by the arrow (counterclockwise direction), the date indicator driving claw 510d starts to feed the first date indicator tooth portion 516 and rotates the first date indicator 512 counterclockwise. . As the first date indicator 512 rotates counterclockwise, the third calendar feed dog 518c starts to rotate the fourth first date indicator meshing tooth 734d of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 starts an operation of rotating the third date indicator meshing tooth portion 725 of the second date indicator 722.

(2 ・ 4 ・ 3) State in which the first date indicator is rotated in the forward direction FIG. 20 shows the first date indicator 512 in the forward direction (counterclockwise) in the second embodiment of the timepiece with calendar mechanism of the present invention. The first date indicator 512 is rotated in the forward direction in the middle of being rotated in the rotation direction), and the leading end portion of the tooth portion 516 of the first date indicator 512 and the leading end portion of the setting portion of the first date jumper 514 are rotated. It is a fragmentary top view which shows the structure of the back side of the movement 700 seen from the dial side in the state which is going to contact a part. Referring to FIG. 20, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the third calendar feed dog 518 c rotates the fourth first date indicator meshing tooth 734 d of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 rotates the third date indicator meshing tooth portion 725 of the second date indicator 722.

  In the middle of the feeding state of the first date indicator 512, the tip portion of the tooth portion 516 of the first date indicator 512 and the tip portion of the setting portion of the first date jumper 514 come into contact with each other. Further, in the middle of the feeding state of the second date indicator 522, the tip end portion of the positioning tooth portion 526 of the second date indicator 722 and the tip end portion of the setting portion of the second date jumper 724 are brought into contact with each other.

(2, 4, 4) First date indicator rotated by one pitch in the forward direction FIG. 21 shows a second embodiment of the timepiece with calendar mechanism of the present invention. FIG. 6 is a partial plan view showing a structure on the back side of the movement 700 viewed from the dial side in a state in which the pitch is rotated by one pitch (one tooth of the first date wheel, ie, (360/31) degrees) in the rotation direction). . Referring to FIG. 21, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 20, and the date indicator driving finger 510d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. Further, the second date indicator 722 is positioned at a position rotated clockwise (360/15) degrees from the state shown in FIG. 18 by the elastic force of the second date jumper 724. The third date indicator 732 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the numeral “30” provided on the printing surface 732 m of the third date indicator 732 is arranged below the date window 104 f of the dial 104. Further, for the second date indicator 722, the first date indicator and the third date indicator display window 722k3, 722k6, or 722k9 are arranged below the date window 104f of the dial 104. Since the first date indicator 512 is located below the third date indicator 732, it cannot be seen from the date window 104 f of the dial 104. That is, as shown in FIG. 21, the third date indicator 732 alone is in a state of displaying the current date, “30” day. In the second embodiment of the timepiece with calendar mechanism of the present invention, the second date indicator 722, the third date indicator 732, and the first date indicator 512 are arranged in this order from the side close to the dial 104.

(2 ・ 4 ・ 5) State in which the first date indicator is further rotated in the forward direction FIG. 22 is a diagram showing a second embodiment of the timepiece with calendar mechanism of the present invention. In the state of being rotated in the counterclockwise direction), the first date indicator 512 is further rotated in the forward direction, and the tip portion of the tooth portion 516 of the first date indicator 512 and the first date jumper 514 It is a fragmentary top view which shows the structure of the back side of the movement 700 seen from the dial side in the state which is trying to contact the front-end | tip part of a setting part. Referring to FIG. 22, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the fourth calendar feed dog 518d rotates the fifth first date indicator meshing tooth 734e of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 rotates the third date indicator meshing tooth portion 725 of the second date indicator 722.

(2 · 4 · 6) State in which the 1st date indicator is further rotated by one pitch in the forward direction FIG. 23 shows a second embodiment of the timepiece with calendar mechanism of the present invention. Partial plan view showing the structure of the back side of the movement 700 as viewed from the dial side in a state in which it is further rotated by one pitch (clockwise direction) (one tooth of the first date wheel, ie, (360/31) degrees). It is. Referring to FIG. 23, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 22, and the date indicator driving claw 510d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. The second date indicator 722 is positioned at a position rotated (360/15) degrees in the clockwise direction from the state shown in FIG. 21 by the elastic force of the second date jumper 724. The third date indicator 732 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the number “31” provided on the printing surface 732 m of the third date indicator 732 is arranged below the date window 104 f of the dial 104. Since the first date indicator 512 is located below the third date indicator 732, it cannot be seen from the date window 104 f of the dial 104. Further, for the second date indicator 722, the first date indicator and the third date indicator display window 722k3, 722k6, or 722k9 are arranged below the date window 104f of the dial 104. That is, as shown in FIG. 23, the third date indicator 732 alone is in a state of displaying the current date, “31” day.

(2 · 4 · 7) State in which the 1st date indicator is further rotated in the forward direction FIG. 24 shows a second embodiment of the timepiece with calendar mechanism of the present invention. In the middle of rotating in the direction (counterclockwise direction), the first date indicator 512 further rotates in the forward direction, and the tip of the tooth portion 516 of the first date indicator 512 and the first date It is a partial top view which shows the structure of the back side of the movement 700 seen from the dial side in the state which the front-end | tip part of the setting part of the jumper 514 is going to contact. Referring to FIG. 24, the date indicator driving wheel 510 rotates in the direction indicated by the arrow, whereby the first date indicator 512 rotates in the counterclockwise direction. As the first date indicator 512 rotates, the fifth calendar feed tooth 518e rotates the first first date indicator meshing tooth 734a of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 rotates the third date indicator meshing tooth portion 725 of the second date indicator 722.

(2, 4, 8) State in which the first date indicator is further rotated by one pitch in the forward direction. FIG. 25 shows the second embodiment of the timepiece with calendar mechanism of the present invention. Partial plane showing the structure of the back side of the movement 700 as viewed from the dial side in a state in which the pitch is further rotated by one pitch (counterclockwise in the counterclockwise direction) (by (360/31) degrees). FIG. Referring to FIG. 25, when the date indicator driving wheel 510 further rotates in the direction indicated by the arrow from the state shown in FIG. 24 and the date indicator driving claw 510d rotates the first date indicator 512 in the direction indicated by the arrow, Due to the elastic force of the jumper 514, the first date indicator 512 is positioned at a position rotated (360/31) degrees counterclockwise from the state shown in FIG. Further, the second date indicator 722 is positioned at a position rotated (360/15) degrees in the clockwise direction from the state shown in FIG. 23 by the elastic force of the second date jumper 724. The third date indicator 732 is positioned at a position rotated (360/5) degrees counterclockwise from the state shown in FIG. As a result, the date character displayed from the date window 104 f of the dial 104 by the second date indicator 722 is “0”, and the date of the first date indicator 512 that can be seen through the window portion of the second date indicator 722. The character is “1”. On the non-printing surface 732 n of the third date indicator 732, a portion adjacent to the number “31” in the clockwise direction is disposed below the date window 104 f of the dial 104. That is, in the state shown in FIG. 25, the second date indicator 722 and the first date indicator 512 pass through the non-printing surface 732n of the third date indicator 732 from the date window 104f of the dial 104 to the current date, “01” date. Is displayed.

(2.5) Operation for Correcting Calendar Hereinafter, the operation for correcting the calendar in the second embodiment of the timepiece with calendar mechanism of the present invention will be described.

(2.5.1) Operation when correcting from "01 day" to "02 day" Referring to FIGS. 16, 28, and 29, in movement 700, winding stem 410 is moved in the first direction, for example, When rotated counterclockwise, the second calendar correction wheel 591 is configured to rotate based on the rotation of the first calendar correction wheel 590. The date correction lever 593 is moved based on the rotation of the second calendar correction wheel 591 so that the correction leading end of the date correction lever 593 can rotate the first date wheel 512 counterclockwise by one pitch. Configured.

  For example, in the second embodiment of the timepiece with calendar mechanism of the present invention, when the date display by the first date indicator 512 and the second date indicator 522 is corrected from “01 day” to “02 day”, the winding stem 410 When the winding stem 410 is rotated in the first direction (the direction in which it is rotated counterclockwise) with the first hand pulled out to the first stage, the correction leading end of the date correction lever 593 causes the first date indicator 512 to rotate counterclockwise. Rotate one pitch at a time. At this time, the 1st date indicator 512 rotates counterclockwise. As a result, the date letter displayed from the date window 104 f of the dial 104 by the second date indicator 522 remains “0” and can be viewed through the window portion of the second date indicator 522. The day letter of “1” changes to “2”.

(2.5.2) Operation when correcting from "09th" to "10th" In the second embodiment of the timepiece with calendar mechanism of the present invention, the first date indicator 512 and the second date indicator 522. When the date display is corrected from “09” to “10”, if the winding stem 410 is rotated in the first direction (the direction to rotate counterclockwise) with the winding stem 410 being pulled out to the first stage, The correction leading end of the date correction lever 593 rotates the first date indicator 512 counterclockwise by one pitch. At this time, the first date indicator 512 rotates, so that the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 rotates the third date indicator meshing tooth portion 725 of the second date indicator 722. As a result, the date character displayed from the date window 104 f of the dial 104 by the second date indicator 722 changes from “0” to “1”, and the first date that can be seen through the window portion of the second date indicator 722. The date character of the car 512 changes from “9” to “0”. The same applies to the operation when changing from the “19” day to the “20” day.

(2.5.3) Operation when correcting from "29 days" to "30 days" In the second embodiment of the timepiece with calendar mechanism of the present invention, the first date indicator 512 and the second date indicator 722 When the display of the date by “29 days” is to be corrected to “30 days”, the winding stem 410 is pulled out in the first direction with the winding stem 410 being pulled out to the first stage ( In the counterclockwise direction, the correction leading end of the date correction lever 593 rotates the first date indicator 512 counterclockwise by one pitch. At this time, the 1st date indicator 512 rotates counterclockwise. As the first date indicator 512 rotates, the calendar feed dog rotates the first date indicator meshing tooth of the third date indicator 732. The second date indicator meshing tooth 735 of the third date indicator 732 rotates the third date indicator meshing tooth portion 725 of the second date indicator 722. As a result, the third date indicator 732 alone can display the current date, “30” day.

(2.6) Operation for correcting phase shift of date indicator by calendar correction In the second embodiment of the present invention, the operation for correcting phase shift of date indicator is the above-described first embodiment of the present invention. This is the same as the operation of. As shown in FIG. 31, in a state where “31” is displayed by the third date indicator 532 and only the first date indicator 512 is rotated by one pitch in the clockwise direction, the winding stem 410 is moved to the first step. When the winding stem 410 is rotated in the first direction (direction to rotate counterclockwise) in the state of being pulled out, the first date indicator 512 is rotated counterclockwise by the operation of the date correction lever 593. As described above with respect to the first embodiment of the present invention, the winding stem 410 is continuously rotated in the first direction (the direction in which it is rotated counterclockwise), and the third calendar feed tooth 518e of the first date indicator 512 is By rotating the first 1st date indicator meshing tooth 734a of the date indicator 732, it can be corrected to be in the normal calendar display state shown in FIG.

(3) Other embodiments of the calendar mechanism of the present invention The first and second embodiments of the present invention described above are embodiments in which the calendar mechanism-equipped timepiece is composed of an analog electronic timepiece. The present invention can be applied not only to an analog electronic timepiece but also to a mechanical timepiece. That is, the concept of “timepiece with calendar mechanism” in this specification is a concept that includes “mechanical timepieces”, includes “analog electronic timepieces”, and includes analog timepieces of all other operating principles.

  In the embodiment of the mechanical timepiece, the rotation of the barrel gear that is rotated by the power of the mainspring is controlled by the speed control device and the escapement device. By rotation of the barrel wheel, the fourth wheel rotates once per minute through the rotation of the second and third wheels. In addition, the minute wheel rotates once per hour by the rotation of the barrel wheel. With the rotation of the minute wheel, the hour wheel rotates once every 12 hours through the rotation of the minute wheel. The date indicator wheel can be rotated by the rotation of the hour wheel, and the first date indicator can be rotated by the date feeding claw that is rotated by the rotation of the date indicator wheel. In the embodiment of the mechanical timepiece, the structure and operation of the calendar mechanism are the same as the structure and operation of the embodiment when the above-described timepiece with calendar mechanism is constituted by an analog electronic timepiece.

  In this invention, it is comprised so that the date from the 1st to the 31st can be displayed with a big number using three date dials. According to the present invention, it is possible to manufacture a timepiece with a calendar mechanism that has a large date display and is easy to see. In addition, according to the present invention, a small timepiece with a calendar mechanism configured to be able to adjust the phase of the date display without disassembling the timepiece even when the date display phase shift occurs is reduced in the number of parts. Can be manufactured.

100 Movement 102 Base plate 104 Dial plate 410 Wind truth 442 Fourth wheel 444 Third wheel 446 Second wheel 480 Hour wheel 510 Day-turning wheel 512 First day wheel 514 First day jumper 522 Second day wheel 524 Second day jumper 530 Sino-Japanese car 532 Third car

Claims (5)

1. A watch with a calendar mechanism including three date wheels,
   A first date wheel (512) capable of displaying one of the dates,
   A first date jumper (514) for setting the rotational position of the first date indicator (512);
   A second date wheel (522, 722) capable of displaying the tenth place of the date;
   A second date jumper (524, 724) for setting the rotational position of the second date indicator (522, 722);
   A third date wheel (532, 732) capable of displaying a specific date alone,
   The first date indicator (512) has a first date letter display surface,
   On the first date letter display surface, “0”, “1”, “2”, “3”, “4”, “5”, “6”, The numbers "7", "8", "9" are provided,
   The second date indicator has a second date letter display surface,
   The second date character display surface is provided with numbers “0”, “1”, “2” for displaying only the tenth digit of the date,
   The third date indicator has a third date letter display surface,
   On the third date character display surface, numbers "30" and "31" are provided,
   The second date indicator is formed with a first date character display portion for displaying one of the dates by a number provided on the first date character display surface,
   On the third date indicator, the number of the date is indicated by a number provided on the first date character display surface, and the date is indicated by a number provided on the second date character display surface. The second date character display part for displaying the tens place of is formed,
   The second date character display surface is disposed closer to the dial (104) than the first date character display surface,
   The third date character display surface is disposed closer to the dial (104) than the second date character display surface,
   The third date indicator can be rotated by rotating the first date indicator,
   The second date indicator can be rotated by rotating the third date indicator,
   In a state in which the third date indicator is in the position of a specific rotational direction, only when the first date indicator is in the position of a specific rotational direction, the third date indicator is configured to be able to rotate And
   The first date wheel (512) is
   A first calendar feed dog (518a) for changing the position in the rotational direction of the second date indicator from "a state displaying 0" to "a state displaying 1";
   A second calendar feed dog (518b) for changing the position in the rotation direction of the second date indicator from "a state displaying 1" to "a state displaying 2";
   A third calendar feed dog (518c) for changing the position in the rotation direction of the second date indicator from "a state where 2 is displayed" to "a first state where nothing is displayed";
   A fourth calendar feed dog (518d) for changing the position in the rotation direction of the second date indicator from "a first state in which nothing is displayed" to "a second state in which nothing is displayed";
   A fifth calendar feed dog (518e) for changing the position in the rotation direction of the second date indicator from "second state in which nothing is displayed" to "state in which 0 is displayed";
   The third date indicator (532)
   A first first date indicator meshing tooth (534a) for changing the position of the third date indicator in the rotational direction from "a state where 31 is displayed" to "a first state where nothing is displayed";
   A second first date indicator meshing tooth (534b) for changing the position in the rotation direction of the third date indicator from "a first state in which nothing is displayed" to "a second state in which nothing is displayed"; ,
   A third 1st date indicator meshing tooth (534c) for changing the position of the third date indicator in the rotational direction from "a second state in which nothing is displayed" to "a third state in which nothing is displayed"; ,
   A fourth date indicator meshing tooth (534d) for changing the position of the third date indicator in the rotational direction from "a third state in which nothing is displayed" to "a state in which 30 is displayed";
   A fifth date indicator meshing tooth (534e) for changing the position of the third date indicator in the rotational direction from "a state of displaying 30" to "a state of displaying 31";
   The tooth height of the fifth calendar feed dog (518e) of the first date indicator (512) is greater than the tooth lengths of the other four calendar feed teeth (518a to 518d) of the first date indicator (512). Formed long,
   The first first date indicator meshing tooth (534a) of the third date indicator (532) has the same height as the other four first date indicator meshing teeth of the third date indicator (532). (534b-534e) is formed to be shorter than the tooth height,
   The first date indicator meshing tooth (534a) of the third date indicator cannot mesh with the first calendar feed tooth (534a) of the first date indicator,
   The first date indicator meshing tooth (534a) of the third date indicator cannot mesh with the second calendar feed tooth (534b) of the first date indicator,
   The first date indicator meshing tooth (534a) of the third date indicator cannot mesh with the third calendar feed tooth (534c) of the first date indicator,
   The first date indicator meshing tooth (534a) of the third date indicator is configured so as not to engage with the fourth calendar feed tooth (534d) of the first date indicator,
   The first date indicator meshing teeth (534a) of the third date indicator (532) can mesh with the fifth calendar feed teeth (518e) of the first date indicator (512). Composed,
   A watch with a calendar mechanism.
2. The timepiece with a calendar mechanism according to claim 1 ,
   On the first date character display surface, “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, “0”, “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, “0”, “1”, “2”, “3” ”,“ 4 ”,“ 5 ”,“ 6 ”,“ 7 ”,“ 8 ”,“ 9 ”are provided at angular intervals of (360/31) degrees,
   Three sets of numbers “0”, “1”, “2” are provided at an angular interval of (360/15) degrees on the second date character display surface,
   The three “0” numbers are provided at an angular interval of (360/3) degrees,
   The three “1” numbers are provided at an angular interval of (360/3) degrees,
   The three “2” numbers are provided at an angular interval of (360/3) degrees,
   On the third day character display surface, a number of “30” and a number of “31” are provided at an angular interval of (360/5) degrees.
   A watch with a calendar mechanism.
3. The timepiece with a calendar mechanism according to claim 2 ,
   The first date indicator (512) includes 31 first date indicator teeth formed as inner teeth and five calendar feed teeth formed as inner teeth, and the first date indicator teeth Are formed at an angular interval of (360/31) degrees,
   The calendar feed dog is
   A first calendar feed dog (518a) as a reference;
   A second calendar feed dog (518b) formed at an angular interval of (360 * 10/31) degrees in the first direction with reference to the first calendar feed dog (518a);
   A third calendar feed dog (518c) formed at an angular interval of (360 * 10/31) degrees in the first direction with reference to the second calendar feed dog (518b);
   A fourth calendar feed dog (518d) formed at an angular interval of (360/31) degrees in the first direction with reference to the third calendar feed dog (518c);
   A fifth calendar feed dog (518e) formed at an angular interval of (360/31) degrees in the first direction with respect to the fourth calendar feed dog (518d).
   A watch with a calendar mechanism.
4. The timepiece with a calendar mechanism according to claim 1,
   The rotation center of the first date indicator (512) and the rotation center of the second date indicator (522) are arranged at the same position,
   A date intermediate wheel (530) capable of rotating based on the rotation of the third date indicator (532) and rotating the second date indicator (522);
   The rotational center of the first date indicator (512), the rotational center of the third date indicator (532), and the rotational center of the intermediate date wheel (530) are relative to the rotational center axis of the winding stem (410). Arranged on an orthogonal straight line,
   A watch with a calendar mechanism.
5. The timepiece with a calendar mechanism according to claim 1,
   The second date indicator (722) includes a third date indicator meshing tooth portion (725) formed as an internal tooth,
   The third date indicator (732) includes first date indicator meshing teeth (734a to 734e) formed as external teeth,
   The first date indicator (512) is engaged with the second date indicator (722) by meshing the third date indicator engagement tooth portion (725) with the first date indicator engagement teeth (734a to 734e). ) Configured to be able to rotate directly,
   A watch with a calendar mechanism.

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