JP2006153834A - Electronic clock with calendar displaying function, and control method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To maintain operating sense, using a low load to a piezoelectric actuator. <P>SOLUTION: When driving a control wheel pinion 77 and a control wheel from a previous rotation holding position to the present rotation holding position, they are driven by a piezoelectric actuator 71 until reaching a predetermined drive switching position, and driven by an energizing force in the rotating direction of a positioning jumper 300 after reaching the drive switching position. Then, the control wheel driven to the present rotation holding position is held in that position by the energizing force in the radial direction of the positioning jumper 300. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electronic timepiece with a calendar display function and a control method thereof, and more particularly to a technique for improving the operational feeling and reducing power consumption when changing the calendar display.

  2. Description of the Related Art Conventionally, an electronic timepiece (electronic timepiece with a calendar display function) having a calendar display mechanism for displaying a calendar such as a day and a month is known. As a calendar display mechanism of this watch, for example, a ring-shaped display plate called a date wheel having numbers “1” to “31” arranged on the circumference is provided, and at the timing after time 0:00, A configuration is adopted in which the date wheel is rotated by an actuator for one day, and the calendar displayed on a display window provided on the watch is changed (date feeding) by one day (for example, see Patent Document 1). .

By the way, it is conceivable to use a piezoelectric actuator as an actuator for driving the date dial.
Specifically, when performing a calendar feeding operation using a piezoelectric actuator, detection is performed at 24:00, and when it is detected that the time has reached 24:00, the control device starts driving the piezoelectric actuator. It becomes.
The piezoelectric actuator drives the date wheel via the speed reduction wheel train.
In this case, the reduction gear train is provided with a gear (detection wheel) with a contact spring, and the circuit board is provided with a stop detection pattern electrode (conduction / non-conduction state depending on the rotation state of the contact spring). Circuit board). As a result, when the gear with the contact spring reaches a predetermined rotation position (corresponding to the drive stop position) and the contact spring enters a predetermined conduction state with respect to the stop detection pattern electrode, the control device stops driving the piezoelectric actuator. It becomes.
International Publication No. WO99 / 34264 JP 2003-255063 A

By the way, as described above, when detecting the drive stop timing of the piezoelectric actuator using the gear with the contact spring and the stop detection pattern electrode, it is necessary to perform phase matching between the detection spring and the detection wheel. Moreover, the incorporation property by providing a detection spring will deteriorate, and the problem that the manufacturing cost will raise as a whole will arise.
In addition, since the reduction gear train is provided with a gear with a contact spring, there is a problem that the layout freedom of the train wheel configuration is low.
Furthermore, even if a gear with a contact spring is provided at the tail end (most deceleration side) of the reduction gear train, there is a problem that the contribution ratio to the load torque is increased.

Furthermore, the layout of the stop detection pattern electrode has a relatively high degree of freedom, so the stop position can be set freely, but the rotation holding position (stop position) of the control car is caused by component variations. It is difficult to perform an operation in cooperation with a jumper for regulating, and there may be problems such as an increase in reverse load on the piezoelectric actuator and a decrease in user's feeling of daily feeding (a feeling of operation becomes worse).
SUMMARY OF THE INVENTION An object of the present invention is to provide a calendar display function-equipped electronic timepiece capable of maintaining a feeling of operation with a low load on a piezoelectric actuator and a control method thereof.

In order to solve the above problems, an electronic timepiece with a calendar display function for rotating a calendar display wheel by a tooth wheel train including a piezoelectric actuator and a control wheel is arranged in a radial direction or a rotation direction of the control vehicle according to the rotation state of the control vehicle. A jumper that applies an urging force and holds the control vehicle in the rotation holding position by the radial urging force when the control vehicle is in the rotation holding position; When driving to the rotation holding position, the calendar display wheel is rotated by driving the piezoelectric actuator against the biasing force until reaching the predetermined drive switching position, and after reaching the drive switching position, The calendar display wheel is rotated by a biasing force of the jumper in the rotation direction.
According to the above configuration, when the control vehicle is driven from the previous rotation holding position to the current rotation holding position, it is driven by the piezoelectric actuator up to a predetermined drive switching position, and after reaching the drive switching position, the rotation of the jumper Driven by the biasing force in the direction.
Then, the control vehicle driven to the current rotation holding position is held at the rotation holding position by the biasing force of the jumper in the radial direction.

In this case, a drive unit that drives the piezoelectric actuator, and a drive control unit that controls the drive unit and rotates the control vehicle held at the previous rotation holding position to the drive switching position. You may do it.
Further, the drive control unit may stop driving of the piezoelectric actuator when the rotational position of the control vehicle reaches the drive switching position.
Furthermore, a control wheel pinion may be integrally formed on the control wheel, and the jumper may be used to hold the control wheel at the predetermined rotational position via the control wheel pinion.
In addition, the control wheel is meshed with one or more intermediate wheels that transmit driving force from the piezoelectric actuator side, and the backlash between the tooth surface of the intermediate wheel and the tooth surface of the control wheel. The rotation amount of the corresponding control wheel may be set so as to correspond to the rotation amount of the control vehicle from the drive switching position to the current rotation holding position.

Furthermore, the drive control unit may include an operation state detection unit that detects a rotation state of the control vehicle according to an operation state of the jumper.
Furthermore, the operation state detection unit includes a fixed electrode unit, and the jumper includes a movable electrode unit electrically connected to the fixed electrode unit according to the operation state of the jumper, and the operation state detection unit May determine whether or not the rotational position of the control vehicle has reached the drive switching position based on whether or not the movable electrode portion and the fixed electrode portion are electrically connected.
In addition, the piezoelectric actuator performs intermittent driving, and the operation state detection unit drives the piezoelectric actuator to determine whether or not the movable electrode unit and the fixed electrode unit are electrically connected. You may make it prohibit during periods other than being done.
Furthermore, it may have a timetable time motor for driving a time display unit for performing time display, and the piezoelectric actuator may be driven during a non-drive period of the time display motor.
Furthermore, it has a secondary battery as a power source for driving the electronic timepiece with calendar display function, and the piezoelectric actuator is forced to drive when the voltage of the secondary battery falls below a predetermined reference voltage. It may be stopped.

  In addition, a method for controlling an electronic timepiece with a calendar display function that rotationally drives a calendar display wheel by a tooth wheel train including a piezoelectric actuator and a control wheel is controlled according to the rotation state of the control vehicle. A piezoelectric actuator that applies a biasing force in a radial direction or a rotational direction of the vehicle, and holds the control vehicle in the rotational holding position by the radial biasing force when the control vehicle is in the rotational holding position; To determine whether the rotation position of the control vehicle has reached the drive switching position, and a first drive process in which the control vehicle is driven from the previous rotation holding position toward the current holding position. And when the rotational position of the control vehicle reaches the drive switching position, the driving of the actuator is stopped and the jumper is driven by the urging force in the rotational direction. A second driving step of driving the car from above this holding position, is characterized by comprising a.

  According to the present invention, the driving time of the piezoelectric actuator is reduced, and the calendar display wheel is rotationally driven in a state in which the piezoelectric actuator and the jumper are operated in cooperation with each other, thereby reducing the load on the piezoelectric actuator with low power consumption. It is possible to maintain a feeling of operation while keeping it low.

Next, preferred embodiments of the present invention will be described with reference to the drawings. In the following description, the case where the present invention is applied to a wristwatch will be described.
FIG. 1 is a diagram illustrating an external configuration of a wristwatch according to the embodiment.
As shown in FIG. 1, the wristwatch 1 includes a timepiece main body 1a and a belt 1b connected to the timepiece main body 1a.
The timepiece main unit 1 a includes a housing 200 and a disk-shaped time display plate 202 provided on the housing 200, and a second hand 61, a minute hand (long hand) 62, and an upper surface of the time display plate 202. , Three indicator hands consisting of hour hand (short hand) 63 are provided.
On the time display board 202, numbers or symbols (including letters) indicating the time are arranged at equal intervals along the circumference, and the number or symbol indicated by each display pointer indicates the current The time is displayed.

The time display plate 202 is provided with a date display window 204, a 24-hour display unit 205, a month display unit 206, and a year display unit 208, which are hollowed out in a substantially rectangular shape. In the day display window 204, any one of “1” to “31” indicating the “day” of the calendar is displayed. In this case, as will be described later, the first digit and the tenth digit are attached to different date indicators (calendar display vehicles), and the “day” of the calendar is indicated by the number attached to each date indicator. The
On the 24-hour display portion 205, symbols indicating times divided into 24 are arranged at equal intervals along the circumference, and “time” is displayed by the symbol indicated by the display pointer 205a.
In addition, the month display unit 206 indicates the “month” of the calendar along the circumference, for example, any one symbol from “JAN” (in January) to “DEC” (in December). Are arranged at equal intervals, and the “month” of the calendar is displayed by a symbol indicated by the display pointer 206a.

On the year display portion 208, any one of the numbers “0” to “3” is displayed at equal intervals along the circumference. If the year is a leap year, the display pointer 208a indicates the number “0”. After that, if “1”, “2”, and “3” are pointed out, it indicates the number of years from the leap year. Thereby, the user can know the “year” of the calendar.
A disc-shaped ground plate 303 (see FIG. 2) having substantially the same shape as the time display plate 202 is disposed in the watch main body 1a, and an auto-calendar mechanism (calendar display) is placed on the front side of the watch with the ground plate 303 interposed therebetween. Means) and a basic mechanism as a watch is arranged on the back side. The base plate 303 functions as a member that pivotally supports one end of each gear of the auto-calendar mechanism.

FIG. 2 is a perspective view of the movement as seen from the auto-calendar mechanism side. FIG. 3 is a view showing a main part of the auto calendar mechanism. FIG. 4 is an enlarged view of a main part of the auto calendar mechanism.
The auto calendar mechanism is supported on one surface of the main plate 303 corresponding to the front side of the timepiece 1 and is driven by the piezoelectric actuator 71.
The piezoelectric actuator 71 includes a piezoelectric element that is a vibrator. When the outer periphery of the rotor 72 is struck by the vibration of the piezoelectric element, a frictional force is generated to rotate the rotor 72.
The rotor 72 is integrally provided with a rotor pinion 72a, and an intermediate wheel 74 is engaged with the rotor pinion 72a. An intermediate wheel 75 is engaged with the intermediate wheel pinion 74a of the intermediate wheel 74, and an intermediate wheel 76 is engaged with the intermediate wheel pinion 75a. The intermediate wheel 76 meshes with a control wheel pinion 77, and the control wheel pinion 77 is formed integrally with the control wheel 78. Up to this point, the speed reducing wheel train is for turning the control wheel 78.
A positioning jumper 300 is slidably engaged with the control wheel pinion 77 and biased in the radial direction of the control wheel pinion 77 (and the control wheel 78), and the control wheel pinion 77 and thus the control wheel 78 are rotated by a predetermined amount. Holding in position.

FIG. 5 is a plan view of the positioning jumper. FIG. 6 is an external perspective view of the positioning jumper.
The positioning jumper 300 is broadly divided into a plate-like jumper main body 301 and an elastic portion 302 that extends to one end side of the jumper main body 301 and biases the jumper main body 301 toward the control wheel pinion 77 side. Yes.
At the center of the jumper main body 301, a rotary shaft 351 standing on the main plate 350 is provided with a rotary shaft hole 303 into which the jumper main body 301 is rotatably inserted.
A rib 304 is provided on a side portion of the jumper main body 301, and a movable electrode portion 305 functioning as a movable electrode is erected on one end of the rib 304 in a direction perpendicular to the surface of the jumper main body 301.
Further, on the side portion on the other end side of the jumper main body 301, a restricting projection 306 that engages with the control wheel pinion 77 and restricts the holding position of the control wheel pinion 77 is provided.

FIG. 7 is a plan view when the positioning jumper is incorporated in the watch.
As shown in FIG. 7, an overhang electrode portion 401 as a fixed electrode is formed at a position facing the movable electrode portion 305 of the wiring substrate 400. The overhang electrode 401 is formed so as to protrude from the resin portion constituting the wiring board 400, and one end thereof is connected to the wiring pattern 402 formed on the wiring board 400.
Further, the elastic portion 302 of the positioning jumper 300 is fixed to the main plate 350 by a fixing screw 352.

FIG. 8 is a schematic configuration diagram of a control system that controls the rotation of the control vehicle.
As shown in FIG. 8, the positioning jumper 300 is connected to a high potential side power source.
In addition, the wristwatch 1 includes a controller 410 that controls the entire wristwatch 1, and the controller 410 is connected to the overhang electrode portion 401 via the control input terminal 410 </ b> A and the wiring pattern 402. The actuator drive circuit 411 is controlled according to the potential state 401. Here, the control input terminal 410A is grounded via a voltage detection resistor (not shown) inside the controller 410, and is in the “L” level in a normal state.
When a drive instruction for driving the piezoelectric actuator 71 is given from the controller 410, the actuator drive circuit 411 applies a voltage to the piezoelectric actuator 71 in a predetermined voltage application pattern to set the drive state.

The driving force of the piezoelectric actuator 71 is transmitted while being decelerated via the tooth wheel trains 72 to 76, and drives the control wheel pinion 77 to rotate in the direction of arrow A.
Accordingly, the restricting projection 306 of the positioning jumper 300 tries to get over the teeth 77A constituting the control wheel pinion 77, and the positioning jumper 300 rotates in the direction of arrow B about the rotation shaft 351 as the rotation center. It will be. As a result, the movable electrode portion 305 of the positioning jumper 300 rotates toward the overhang electrode portion 411 against the biasing force of the elastic portion 302, and thus is electrically connected to the overhang electrode portion 411. It will be.
Therefore, the potential of the control input terminal 410A becomes the high potential side power supply level, that is, the “H” level, and the controller 410 is in a state where the restricting projection 306 of the positioning jumper 300 gets over the teeth 77A of the control wheel pinion 77. You can know that there is.

Therefore, in the present embodiment, the controller 410 rotates the control wheel 78 by the piezoelectric actuator 71 via the reduction wheel trains 72 to 77, and monitors the change in the potential level of the control input terminal 410A. 77, that is, it is detected that the feed amount of the control wheel 78 has reached a feed amount that allows the calendar to be fed for one day, and the driving of the piezoelectric actuator 71 is stopped at the time of the detection.
Here, the feed amount of the control car 78 that can feed the calendar for one day is that the control car 78 is sent as much as the backlash between the control car 77 and the intermediate car 76. This is a feed amount until the control wheel pinion 77 is driven by the urging force of the positioning jumper 300 and it becomes possible to enter the positioning state at that position.

Therefore, if the piezoelectric actuator 71 is driven to such a feed amount that the control wheel 78 can feed the calendar for one day, even if the controller 410 stops driving the piezoelectric actuator 71 at that time, the positioning is performed. The control wheel pinion 77 is driven by the backlash between the tooth surface of the control wheel pinion 77 and the tooth wheel of the intermediate wheel 76 in the direction of arrow A by the urging force of the jumper 300 in the control wheel rotation direction. When the tooth surface and the tooth surface of the intermediate wheel 76 come into contact with each other, feeding of one calendar day is completed.
Therefore, it is not necessary to drive the piezoelectric actuator 71 until the tooth surface of the control wheel pinion 77 and the tooth surface of the intermediate wheel 76 come into contact with each other, and the operation in cooperation with the positioning jumper 300 can be performed, thereby reducing power consumption. Can do. Further, since the tooth surface of the control wheel pinion 77 and the tooth surface of the intermediate wheel 76 can be brought into contact with each other only by the urging force of the positioning jumper 300, the first date wheel and the 10th date wheel are driven to a predetermined position. It can be held at this position.

  In this case, the distance D (see FIG. 8) between the movable electrode portion 305 and the overhang electrode portion 411 at the initial position of the positioning jumper 300, that is, the position corresponding to the state where the control wheel 78 is held at a predetermined position. When the restricting projection 306 of the positioning jumper 300 gets over the teeth 77A of the control wheel pinion 77, the movable electrode portion 305 and the overhang electrode portion 411 are once electrically connected and then again disconnected. Is adjusted so as to be a position corresponding to the backlash between the tooth surface of the control wheel 77 and the tooth surface of the intermediate wheel 76.

Next, a specific operation will be described.
FIG. 9 is an explanatory diagram of an initial state before driving the piezoelectric actuator. FIG. 10 is a timing chart for explaining the operation state.
As shown in FIG. 9, the restriction projection 306 of the positioning jumper 300 is located between the teeth 77A0 and 77A1 of the control wheel pinion 77 and is in contact with both the teeth 77A0 and 77A1. The positioning jumper 300 holds the control wheel 77 and the control wheel 78 at the rotational position.
In this state, the movable electrode portion 305 and the overhang electrode portion 411 are in a state of being electrically separated from each other, and the controller 410 controls the control terminal 410A because the control terminal 410A is in a grounded state (indicated by “L” level in FIG. 10). It is recognized that the car pinion 77 and thus the control wheel 78 are held at a predetermined rotational position.

  In this state, when the controller 410 recognizes that the current time has reached 24:00, the controller 410 controls the actuator drive circuit 411 to drive the piezoelectric actuator 71 so as to send the calendar for one day.

FIG. 11 is a timing chart for explaining a more detailed operation state of the piezoelectric actuator.
In the present embodiment, the piezoelectric actuator 71 performs intermittent driving, and the controller 410 determines whether or not the movable electrode portion 305 and the overhang electrode portion 411 (fixed electrode portion) are electrically connected. In addition, the piezoelectric actuator 71 is prohibited except during the driving period.

This is due to the following reasons.
The rotational speed of the rotor by the piezoelectric actuator 71 is 4 to 30 rps, although it depends on the power supply voltage and the train wheel load. For example, the calendar can be sent one day when the rotor turns 8.33 due to the reduction gear ratio of the reduction gear train. In this case, in order to drive the electromagnetic motor for displaying the time (output pulses P1 and P2), in order to reduce the load on the power source and avoid a system down due to a sudden power supply voltage drop, every second The driving of the actuator 71 is stopped for 6/16 seconds after counting.
In consideration of this, 0.28 seconds to 3.3 seconds are required in order to perform the daily feeding for the actual day.

Therefore, it is impossible to carry out date feeding in 10/16 seconds excluding 6/16 seconds counting from every second, and the electrical connection between the movable electrode part 305 and the overhang electrode part 411 (fixed electrode part) is impossible. This is because the connection may become unstable.
Therefore, in order to avoid processing complexity, the controller 410 interrupts the driving of the piezoelectric actuator and simultaneously maintains the detected electrical connection state between the movable electrode unit 305 and the overhang electrode unit 411 (fixed electrode unit). The composition is taken.

That is, as shown in FIG. 11, when the controller 410 recognizes that the detection signal at 24:00 becomes “H” level and the current time has reached 24:00, it detects 24:00 to send the calendar for one day ( After 1 + 6/16) seconds, the actuator drive circuit 411 is controlled to start driving the piezoelectric actuator 71.
The controller 410 drives an electromagnetic motor for displaying the time every second, but when driving the electromagnetic motor 2 seconds after detecting 24:00, the drive of the piezoelectric actuator 71 is temporarily stopped. To do.

At the same time, the controller 410 holds the feed amount detection signal at the “H” level and holds the detected electrical connection state between the movable electrode portion 305 and the overhang electrode portion 411 (fixed electrode portion). 410 resumes the driving of the piezoelectric actuator 71 again after 6/16 seconds, that is, in the state where the electromagnetic motor is not driven, and the electrical connection between the movable electrode portion 305 and the overhang electrode portion 411 (fixed electrode portion). The connection state is detected.

More specifically, the controller 410 provides a chattering prevention period of 16 ms to 32 ms both before and after the time when the feed amount detection signal is set to the “H” level, and detection is not performed during this period. . This is because the period in which the electrically connected state between the movable electrode portion 305 and the overhang electrode portion 411 (fixed electrode portion) is unstable may be long.
In the above description, the piezoelectric actuator 71 is driven during the non-drive period of the time display electromagnetic motor. However, when a secondary battery is used as a power source, the voltage of the secondary battery falls below a predetermined reference voltage. In addition, the drive may be forcibly stopped.

Now, when driving of the piezoelectric actuator 71 is started by the controller 410, the piezoelectric actuator 71 strikes the outer periphery of the rotor 72, thereby rotating the rotor 72.
When the rotor 72 rotates, the rotor pinion 72a also rotates together, and the intermediate wheel 74 that meshes with the rotor pinion 72 also rotates.
When the intermediate wheel 74 rotates, the intermediate wheel pinion 74a also rotates together, and the intermediate wheel 75 meshed with the intermediate wheel pinion 74a also rotates.
When the intermediate wheel 75 rotates, the intermediate wheel pinion 75a also rotates together, and the intermediate wheel 76 meshed with the intermediate wheel pinion 75a also rotates.
When the intermediate wheel 76 rotates, the control wheel pinion 77 meshing with the intermediate wheel 76 also rotates in the direction of arrow A.

FIG. 12 is an explanatory diagram when the control wheel kana starts to rotate.
As shown in FIG. 12, the restricting projection 306 of the positioning jumper 300 is located between the teeth 77A0 and 77A1 of the control wheel pinion 77 and overtakes the teeth 77A1 in a state of being in contact with only the teeth 77A1. I am trying to do.
In this state, the movable electrode portion 305 and the overhang electrode portion 411 are electrically connected, and the controller 410 has the control terminal 410A in the high potential side power supply connection state (in FIG. It is recognized that the control wheel 77 and thus the control wheel 78 have shifted to the rotating state.

FIG. 13 is an explanatory view when the control wheel kana further rotates and the restricting projection reaches the tip of the tooth.
As shown in FIG. 13, the restriction projection 306 of the positioning jumper 300 is about to get over the tooth 77 </ b> A <b> 1 at this moment in a state where it is located at the tip of the tooth 77 </ b> A <b> 1 of the control wheel pinion 77.
Even in this state, the movable electrode portion 305 and the overhang electrode portion 411 are in an electrically connected state, and the controller 410 has the control terminal 410A in the high potential side power supply connection state (= “H” level). ), It is recognized that the control wheel 77 and thus the control wheel 78 remain rotating.

FIG. 14 is an explanatory diagram of the case where the control wheel kana further rotates and the restricting projection exceeds the tooth tip.
As shown in FIG. 14, the restricting projection 306 of the positioning jumper 300 is in a state beyond the tip of the tooth 77A1 of the control wheel pinion 77, and the movable electrode portion 305 and the overhang electrode portion 411 are electrically connected. Immediately before becoming disconnected.
When the control wheel pinion 77 further rotates and the restriction projection 306 of the positioning jumper 300 moves toward the rotation center of the control wheel pinion 77, the movable electrode portion 305 and the overhang electrode portion 411 are not electrically connected. It becomes.
As a result, the controller 410 shifts the control terminal 410A from the high-potential-side power supply connection state to the ground state (in FIG. 10, from “H” level to “L” level). Is determined to have reached a feed amount that can be fed for one day, and the actuator drive circuit 411 is controlled to stop driving the piezoelectric actuator 71.
At this point, the backlash between the tooth surface of the control wheel pinion 77 and the tooth surface of the intermediate wheel 76 is separated.

Therefore, the control wheel pinion 77 is in a free state, and the restricting projection 306 of the positioning jumper 300 is a biasing force for biasing the jumper body 301 by the elastic portion 302 toward the control wheel pinion 77 and the control wheel pinion. Due to the urging force of 77 in the rotational direction, it will slide toward the tooth 77A2 side while being in contact with the tooth 77A1 of the control wheel pinion 77.
As a result, when the control wheel pinion 77 is rotated in the direction of arrow A and rotated by the backlash between the tooth surface of the control wheel pinion 77 and the intermediate wheel 76, the tooth surface of the control wheel pinion 77. Contacts the tooth surface of the corresponding intermediate wheel 76, and the rotation is stopped at that position.

FIG. 15 is an explanatory diagram of a state after the rotation of the control wheel is stopped.
As shown in FIG. 15, the restriction projection 306 of the positioning jumper 300 is located between the teeth 77A1 and 77A2 of the control wheel pinion 77 and is in contact with both the teeth 77A1 and 77A2. The positioning jumper 300 holds the control wheel 77 and the control wheel 78 at the rotational position.
Even in this state, the movable electrode portion 305 and the overhang electrode portion 411 are electrically separated, and the controller 410 is a control vehicle because the control terminal 410A is in the grounded state (= “L” level). 77. As a result, it will be recognized again that the control wheel 78 is held at a predetermined rotational position (calendar display position).

Next, a specific example of the calendar display operation will be described.
In the 24-hour display unit 205, the driving force is taken from the driving source of the timepiece moving mechanism arranged on the back side of the main plate 303, unlike the driving source of the auto-calendar mechanism. That is, the cylindrical vehicle body 93 is integrated with the hour wheel (the hour wheel (short hand) 63 supporting the hour hand 63) of the hand movement mechanism E, and the 24-hour detection wheel 94 is engaged with the cylindrical vehicle body 93. The 24-hour wheel 95 is engaged with the 24-hour detection wheel 94, and the display pointer 205a of the 24-hour display unit 205 is rotated by the rotation of the 24-hour wheel 95. This display indicator 205a is sent once per hour.
The 24-hour detection wheel 94 is provided with a spring switch 310, and the spring switch 310 detects that the display pointer 205a indicates “midnight”.

On the other hand, the control wheel 78 includes a plurality of hook wheels having different numbers of claws, and any one of the wheel wheels is located above the control wheel 78 in FIG. Display wheel)) and a date indicator driving wheel 87 for turning 89, a date indicator driving wheel 90 for turning the tenth date indicator (10th indicator (calendar indicator)) 92, and a control wheel 78 in the lower right in the figure. , And the month display intermediate wheel 79 which rotates the month wheel (calendar display wheel) 82, respectively.
Here, numbers “0” to “9” are displayed at equal intervals in the circumferential direction on the outer peripheral surface of the first date wheel 89, and “empty area” and “ Numbers “1” to “3” are displayed at equal intervals in the circumferential direction. Note that the “empty area” is an area where there is no numerical description, and when the corresponding day corresponds to a single-digit “day” (that is, 1st to 9th), it is ranked 10th.
In the date display window 204 described above, numbers “0” to “9” on the first date wheel 89 and “empty area” or numbers “1” to “3” on the tenth date wheel 92 are displayed. Depending on the combination, any number from “1” to “31” indicating the “day” of the calendar is displayed.

When it is detected by the spring switch 310 of the 24-hour detection wheel 94 that the display pointer 205 a indicates “midnight,” the controller 410 drives the actuator drive circuit 411 and the piezoelectric actuator 71 reduces the speed reduction train 72. ˜77 are driven to rotate the control wheel 78.
When the control wheel 78 is driven to rotate, first, the date indicator driving wheel 87 and the 1st date pinion 88 are rotated via the 1st position feeding claw of the gear body corresponding to the 1st date wheel 89, and integrally therewith. The first date wheel 89 rotates, and the numbers “0” to “9” on the outer peripheral surface thereof are sent in the circumferential direction once a day in principle. In accordance with the rotation of the control wheel 78, the rotation of the 1st date wheel 89 advances, and when the 10th position is reached, the 10th position feed claw of the gear body corresponding to the 10th date wheel 92 is reached. , The date indicator driving wheel 90 and the tenth date pinion 91 are rotated, and the tenth date indicator 92 is rotated integrally therewith, and the “empty area” or the numbers “1” to “3” on the outer peripheral surface thereof. Are sent in the circumferential direction once every 10 days.

In response to the rotation of the control wheel 78, the rotation of the 1st date indicator 89 and the 10th date indicator 92 advances, and when the date on which the indication of “month” is advanced, this time, the month indicator 82 is displayed. The month display intermediate wheel 79 and the month detection wheel 80 are rotated through the corresponding month feeding claws of the gear body, and the month wheel 82 is rotated integrally therewith. Then, the display pointer 206a rotates, and any one of the symbols “JAN” (for January) to “DEC” (for December) indicating the “month” of the calendar on the month display unit 206 indicates. The calendar “month” is displayed.
The year detection intermediate wheel 83 is engaged with the month detection wheel 80, and the year feed wheel 84 is engaged with the year display intermediate wheel 83. An annual wheel (calendar display wheel) 85 meshes with the year feeding wheel 84, and a display pointer 208a indicating the “year” of the calendar is connected to the year wheel 85.

In this case, the annual feeding wheel 84 is configured to rotate the year wheel 85 by 90 ° for the first time after a period of one year. Accordingly, the display pointer 208a is sent once a year. And if it is a leap year, if the display pointer 208a points to the number “0” and then points to “1”, “2”, “3”, for example, it displays the year from the leap year, Thereby, the “year” of the calendar is displayed.
That is, the auto-calendar mechanism decelerates the rotation of the rotor 72 via the reduction wheel trains 72 to 77 to rotate the control wheel 78, and the rotation of the control wheel 78 causes the date wheel (first date wheel 89 and The 10th place date wheel 92), the month wheel 82 and the year wheel 85 are each configured to rotate, and the calendar display is changed.

  As described above, according to the present embodiment, the piezoelectric actuator 71 and the positioning jumper 300 are operated in cooperation, and the piezoelectric actuator 71 is in a state where the positioning jumper 300 gets over the teeth of the control wheel pinion 77. After that, the control wheel 77 and the control wheel 78 are driven by the urging force of the elastic portion 302 of the positioning jumper 300. Therefore, power consumption can be reduced, and an operational feeling can be maintained without applying unnecessary load to the piezoelectric actuator 71.

It is a figure which shows the external appearance structure of the wristwatch which concerns on one Embodiment of this invention. It is the perspective view which looked at the movement from the auto-calendar mechanism side. It is a figure which shows the principal part of an auto calendar mechanism. It is an enlarged view of the principal part of an auto calendar mechanism. It is a top view of the jumper for positioning. It is an external appearance perspective view of the positioning jumper. It is a top view at the time of incorporating the jumper for positioning in a timepiece. It is a schematic block diagram of the control system which controls rotation of a control vehicle. It is explanatory drawing of the initial state before a piezoelectric actuator drive. It is a timing chart for demonstrating an operation state. It is a timing chart for explaining the detailed operation state of a piezoelectric actuator. It is explanatory drawing when a control vehicle kana begins to rotate. It is explanatory drawing when a control projection part reaches the tip of a tooth. It is explanatory drawing when a control protrusion part exceeds the protrusion of a tooth | gear. It is state explanatory drawing after rotation stop of a control wheel kana.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Wristwatch 10, 20 ... Stepping motor, 71 ... Piezoelectric actuator, 72 ... Rotor, 77 ... Control wheel, 77A, 77A0, 77A1, 77A2 ... Teeth, 78 ... Control wheel, 89 ... First place date wheel, 92 ... 10th date indicator, 300 ... Positioning jumper (jumper), 301 ... Jumper body, 302 ... Elastic part, 303 ... Rotating shaft hole, 304 ... Rib, 305 ... Movable electrode part, 306 ... Restriction projection part, 351 ... Rotating shaft, 400, wiring board, 401, overhang electrode section, 402, wiring pattern, 410, controller, 410A, control input terminal, 411, actuator driving circuit.

Claims (11)

In an electronic timepiece with a calendar display function for rotating a calendar display wheel by a tooth wheel train including a piezoelectric actuator and a control wheel,
A biasing force is applied in the radial direction or the rotation direction of the control vehicle according to the rotation state of the control vehicle, and when the control vehicle is at the rotation holding position, the control vehicle is moved to the rotation holding position by the biasing force in the radial direction. Equipped with a jumper to hold
When driving the control wheel from the previous rotation holding position to the current rotation holding position, the calendar display wheel is rotated by driving the piezoelectric actuator against the biasing force until reaching the predetermined drive switching position. , After reaching the drive switching position, the calendar display wheel is rotated by the urging force of the jumper in the rotation direction.
An electronic timepiece with calendar display function. The electronic timepiece with calendar display function according to claim 1,
A drive unit for driving the piezoelectric actuator;
A drive control unit that controls the drive unit to rotate the control vehicle held at the previous rotation holding position to the drive switching position;
An electronic timepiece with a calendar display function. The electronic timepiece with calendar display function according to claim 2,
The electronic control timepiece with calendar display function, wherein the drive control unit stops driving of the piezoelectric actuator when the rotational position of the control vehicle reaches the drive switching position. The electronic timepiece with calendar display function according to any one of claims 1 to 3,
The control vehicle is integrally formed with a control vehicle kana,
An electronic timepiece with a calendar display function, wherein the jumper holds the control wheel at the predetermined rotational position via the control wheel pinion. The electronic timepiece with calendar display function according to claim 4,
One or more intermediate wheels that transmit driving force from the piezoelectric actuator side are meshed with the control wheel.
The amount of rotation of the control wheel corresponding to the backlash between the tooth surface of the intermediate wheel and the wheel surface of the control wheel is the amount of rotation of the control wheel from the drive switching position to the current rotation holding position. Set to correspond to the amount of rotation,
An electronic timepiece with calendar display function. The electronic timepiece with a calendar display function according to any one of claims 2 to 5,
The electronic control timepiece with calendar display function, wherein the drive control unit includes an operation state detection unit that detects a rotation state of the control vehicle according to an operation state of the jumper. The electronic timepiece with calendar display function according to claim 6,
The operating state detection unit includes a fixed electrode unit,
The jumper includes a movable electrode portion that is electrically connected to the fixed electrode portion according to an operation state of the jumper,
The operation state detection unit determines whether or not the rotation position of the control vehicle has reached the drive switching position based on whether or not the movable electrode unit and the fixed electrode unit are electrically connected. An electronic timepiece with a calendar display function. The electronic timepiece with calendar display function according to claim 7,
The piezoelectric actuator performs intermittent driving,
The calendar display characterized in that the operation state detection unit prohibits determination of whether or not the movable electrode unit and the fixed electrode unit are electrically connected except during a period in which the piezoelectric actuator is driven. Electronic clock with function. The electronic timepiece with calendar display function according to claim 8,
It has a timetable time motor that drives a time display unit that displays time,
The electronic timepiece with calendar display function, wherein the piezoelectric actuator is driven during a non-drive period of the time display motor. In the electronic timepiece with calendar display function according to claim 8 or 9,
A secondary battery as a power source for driving an electronic timepiece with a calendar display function,
The electronic timepiece with calendar display function, wherein the piezoelectric actuator is forcibly stopped when the voltage of the secondary battery falls below a predetermined reference voltage. In a control method of an electronic timepiece with a calendar display function for rotationally driving a calendar display wheel by a tooth wheel train including a piezoelectric actuator and a control wheel,
The calendar display function-equipped electronic timepiece applies an urging force in the radial direction or the rotation direction of the control vehicle according to the rotation state of the control vehicle, and the urging force in the radial direction when the control vehicle is in the rotation holding position. A jumper for holding the control vehicle in the rotation holding position by
A first driving process for driving the piezoelectric actuator to drive the control vehicle from the previous rotation holding position to the current holding position;
A determination process for determining whether or not the rotational position of the control vehicle has reached the drive switching position;
When the rotation position of the control vehicle reaches the drive switching position, the drive of the actuator is stopped, and the control vehicle is driven to the current holding position by driving with the biasing force of the jumper in the rotation direction. A second driving process to
A method for controlling an electronic timepiece with calendar display function, comprising:

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