JP2005338099A - Clock device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a clock device which can perform a clock operation continuously and surely, by making a user known when the clock operation starts after a charge of a secondary battery of the clock device. <P>SOLUTION: A memory means 10 outputs a stop detection signal S3 to a modulation signal generation means 8 just after an operation stop of the clock device. And a power source voltage detection means 4 outputs a power source voltage detection signal S4 to a timer means 6 when a power source voltage value Vss of a power source means 2 becomes more than a first reference voltage value V2. The timer means 6 outputs a timer output signal S8 to the modulation signal generation means 8 after a predetermined counting time. The modulation signal generation means 8 outputs a modulation signal S5 to a display driving means 16 then drives a display means 20 with a modulation drive when the timer output signal S8 inputs from the timer means 6, during inputting of the stop detection signal S3 from the memory means 10. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a timepiece device equipped with a power generation mechanism.

  In a conventional timepiece device, a timepiece device equipped with a power generation mechanism that generates electric energy necessary for timepiece driving has been developed.

  As this power generation mechanism, a secondary battery is charged using a solar battery, or an automatic winding power generation mechanism that generates power by the natural movement of the user's arm, etc., and the secondary battery is charged by the output. There are things.

  In such a timepiece device, in order to notify the user of the timepiece device that the hand movement operation has started as the secondary battery is charged, for example, the so-called modulation hand movement is performed by increasing the speed of the hands. Something that works is considered.

  However, if the modulation operation with large power consumption is started immediately after the charging operation of the secondary battery is started, the storage amount is small immediately after the start of the charging operation of the secondary battery, so the voltage value of the secondary battery is immediately Thus, the voltage becomes less than the voltage required for operating the timepiece device, and the modulation hand movement operation is also stopped. That is, if the modulation hand movement is started immediately after the start of the charging operation of the secondary battery, the clock operation cannot be reliably continued.

  The present invention has been made in view of the above problems, and an object of the present invention is to reliably inform the user of the fact that the timepiece operation starts after the secondary battery of the timepiece device is charged, and An object of the present invention is to provide a timepiece device that can reliably and continuously operate.

(1) In order to solve the above problems, the present invention comprises a display means for displaying time information;
Display driving means for driving the display means;
When detecting the stop state of the display means, stop detection means for outputting a stop detection signal;
Storage means for storing and outputting a stop storage signal based on the stop detection signal from the stop detection means;
Power supply voltage detection means for outputting a power supply voltage detection signal when the power supply voltage value of the power supply means is equal to or higher than a first reference voltage value higher than the operation start voltage value;
When the power supply voltage detection signal is input from the power supply voltage detection means while the stop storage signal is input from the storage means, a modulation signal that generates a modulation signal for notifying the start of driving operation of the display means Generating means;
Have
The display driving means modulates and drives the display means based on the modulation signal.

  In this case, the modulation drive is different from normal timepiece drive and refers to timepiece drive that allows the user to visually or audibly recognize the start of the timepiece operation from the stop state.

  Preferably, the modulation signal generating means is configured to stop generating the modulation signal under a given condition. For example, as in the invention of (7), the modulation drive may be stopped based on the result of comparing the power supply voltage value and the reference voltage, and the modulation drive has elapsed for a given time as in the invention of (12). The modulation drive may be stopped at the time, or the modulation drive may be stopped on condition that the user operates a means for time adjustment.

  According to the present invention, the first reference voltage value at which the display means starts modulation driving is set to a value higher than the operation start voltage of the timepiece device, that is, a voltage value that can stably perform the timepiece operation. . Thereby, it is prevented that modulation driving with large power consumption is started immediately after the start of the clock operation accompanying the start of the charging operation of the power supply means, and at the stage where the charging has progressed to the extent that the clock operation can be performed stably, Modulation driving is performed to notify the start of the clock operation. As a result, it is possible to reliably notify the user of the start of the clock operation after charging the power supply means of the clock device, for example, the secondary battery, without adversely affecting the continuation of the clocking operation.

  Furthermore, according to the present invention, a configuration is adopted in which the storage means stores a stop storage signal and performs modulation driving only when the power supply voltage value reaches the first reference voltage value. As a result, when the power supply voltage value fluctuates in the vicinity of the first reference voltage value during the timepiece operation of the timepiece device, it is possible to reliably prevent the occurrence of a situation in which the modulation drive is repeatedly performed, and the timepiece device is in a stopped state. The modulation drive is performed only when the operation is started from this time, and the user can be informed accordingly.

(2) Further, the present invention relates to (1),
A reference signal generating means for generating a reference signal when a voltage capable of driving the display driving means is stored in the power supply means;
The stop detection means outputs the stop detection signal when the reference signal is not output from the reference signal generation means.

  According to the present invention, it is possible to accurately detect whether or not a timepiece operation is performed using a signal that is a reference for the operation of the timepiece device.

(3) Moreover, this invention is either (1) or (2),
The storage means is reset according to a predetermined condition after the power supply voltage detection signal is input from the power supply voltage detection means.

  Here, it is preferable that the predetermined condition is, for example, that the modulation drive starts or ends. With the above configuration, it is possible to prevent the stop memory signal from being reset before the start of modulation driving, and to reset the stop memory signal after the end of modulation driving. It is possible to realize a timepiece device that reliably drives.

  As a more specific example of the predetermined condition, it is considered that the storage state of the stop storage signal of the storage unit is reset when the power supply voltage detection signal is continuously input from the power supply voltage detection unit for a predetermined time. It is done.

(4) Moreover, this invention in any one of (1)-(3),
The power supply unit includes a power generation unit and a power storage unit, and the power generation unit charges the power storage unit.

  Thereby, a charging operation can be easily performed.

(5) Moreover, this invention in any one of (1)-(4),
The display means includes at least two hands of a minute hand and an hour hand,
In the timepiece device, at least one of the two hands is driven to be modulated.

  As described above, a timepiece device that performs analog display, for example, a wristwatch device that performs time display with two hands, for example, a wristwatch device that modulates at least one of the minute hand and hour hand, The user can be surely notified of the start of the hand movement operation.

  That is, when the timepiece device has two hands, the movement of the hour hand and the minute hand is very slow and difficult to recognize, but according to the present invention, at least one of the minute hand and the hour hand is modulated by a different movement from the normal hand. Thus, it is possible to reliably notify the user that the operation of the timepiece device has started.

(6) Moreover, this invention in any one of (1)-(5),
The modulation signal generation means outputs the modulation signal after the power supply voltage detection signal from the power supply voltage detection means is continuously input for a predetermined time.

  For example, the charging voltage of the timepiece device does not always increase with the charging operation, and often increases as a whole while moving up and down irregularly. Depending on the type of secondary battery used, the apparent charge voltage may differ from the true charge voltage. In such a case, the apparent charge voltage directly reflects the true charge state. May not.

  Even in such a case, according to the present invention, by adopting the configuration that performs the modulation driving on condition that the power supply voltage value has continuously exceeded the first reference voltage value for a predetermined time, the charging voltage can be reduced. Modulation driving can be performed without being affected by irregular rise.

(7) Moreover, this invention in any one of (1)-(6),
The modulation signal generation means stops outputting the modulation signal after a predetermined time has elapsed when the power supply voltage detection means detects a power supply voltage value equal to or lower than a second reference voltage value.

  With the above-described configuration, the modulation driving is continuously performed for at least the predetermined time, thereby more reliably informing the user of the start of the clock operation. Here, it is preferable that the predetermined time is set to a minimum time necessary for notifying the user of the modulation driving, for example, about 4 seconds.

  In addition, the second reference voltage value may be set to an arbitrary value as necessary, but is the same voltage value as the first reference voltage value or higher than the operation start voltage value, and the first reference voltage value. It is preferable to set the voltage value lower than the voltage value. As a result, the modulation drive is continuously performed for an optimal time that is neither too long nor too short, and does not interfere with the normal timekeeping operation, so that the timepiece operation associated with charging of the timepiece device can be performed. The user can be surely notified of the start.

(8) Moreover, this invention in any one of (1)-(7),
It includes display control means for outputting a display control signal for adjusting time information displayed on the display means for time adjustment to the display driving means.

  In many cases, the display means displays a time different from the true time information due to the modulation drive. However, according to the present invention, after the modulation drive ends, the display means displays the time information different from the true time information. Can be automatically adjusted to display accurate time information.

(9) Further, the present invention provides (8),
After the output of the modulation signal is stopped, the display control means reversely displays the time information displayed on the display means until the time advanced by the modulation drive coincides with the time displayed by the normal drive. A drive signal is output to the display drive means.

(10) Further, the present invention provides (8),
The display control means outputs a display control signal for stopping the drive of the display means to the display drive means until the time advanced by the modulation drive coincides with the time displayed by the normal drive. To do.

  The inventions of (9) and (10) are specific embodiments of the invention of (8).

  The display means often performs a clock operation in the future direction by modulation driving. However, according to the invention of (9), after the modulation driving is completed, the display means is automatically driven by driving in the past direction, that is, in the reverse direction. Therefore, it is possible to automatically adjust the time so that the display means displays accurate time information.

  Further, in the invention of (10), after the modulation driving is completed, the display means is stopped until the time advanced by the modulation driving coincides with the time displayed by the normal driving, thereby automatically adjusting the time. True time information can be displayed automatically.

(11) Moreover, the present invention provides any one of (1) to (10),
Including switch means for outputting a switch signal;
The modulation signal generating means stops output of the modulation signal when a switch signal from the switch means is input.

  The switch means is preferably formed as a so-called crown device that allows the user of the timepiece device to arbitrarily operate the hands of the display means. As a result, the user of the timepiece device stops the modulation signal when the time is adjusted using the crown device, and thus performs a normal timepiece operation so that the time is accurately displayed after the time is adjusted by the crown device. be able to.

(12) Moreover, this invention in any one of (1)-(11),
Timer means for measuring an elapsed time of the modulation drive,
The modulation signal generating means stops output of the modulation signal when the modulation drive has passed for a given time.

  Here, the timer means may be formed integrally with the modulation signal generating means, or may be formed separately.

(13) Moreover, this invention in any one of (1)-(12),
When the stop storage signal is stored in the storage means, the display drive means includes a drive start control means for controlling the display drive means to a normal drive prohibited state until the end of the modulation drive.

  That is, when the drive start control means is not provided, normal drive is started immediately when the power supply voltage value exceeds the operation start voltage due to the start of the charging operation of the power supply means, and the operation may become unstable due to power consumption due to this. There is. On the other hand, in the present invention, charging at the start of the charging operation is effective by prohibiting normal driving and suppressing power consumption until the charging of the power supply means reaches a sufficient stage, that is, until modulation driving is completed. In addition, after the start of charging, the timepiece device can be promptly brought into a stable driving state.

  In particular, in the present invention, normal driving is started for the first time when modulation driving is completed, so that the occurrence of a situation where modulation driving is suddenly performed immediately after the start of normal driving is prevented, and it is more adapted to the sense of the user. Can be obtained.

  Here, the drive start control means may be formed integrally with the modulation signal generation means, or may be formed separately as required.

(14) Furthermore, the present invention provides any one of (1) to (11),
The display means electronically displays time.

  Thus, as a display means of this timepiece device, in addition to an analog timepiece device having a plurality of hands, a digital timepiece device that digitally displays time information also notifies the start of the charging operation by modulation driving. be able to.

  Furthermore, the display means is not limited to a visual display, and may be an auditory display using an alarm or the like, for example.

  Next, preferred embodiments of the present invention will be described with reference to the drawings.

First Embodiment FIG. 1 shows a schematic block diagram of an embodiment of a timepiece device according to the present invention, and FIG. 2 shows a timing chart of each signal in the timepiece device shown in FIG. .

  This timepiece device displays time information in an analog manner, for example, and the display means 20 for displaying time information is specifically composed of two hands indicating hours and minutes. That is, one of the two hands is an hour hand indicating the hour, and the other hand is a minute hand indicating the minute.

  The power supply means 2 of the timepiece device includes a power generation means and a power storage means, and the power generation means charges the power storage means. Therefore, when this timepiece device is, for example, a wristwatch device worn by a person, the power generation means generates power by the natural operation of the person who wears it, and the power storage means including the secondary battery is charged. The power supply voltage stored in the power supply means 2 is input to the reference signal generating means 14.

  The reference signal generating means 14 includes, for example, an oscillation circuit and the like, and generates an oscillation circuit output pulse S1 which is a reference signal. The oscillation circuit output pulse S1 is a reference pulse for driving the timepiece device, and is input to the stop detection means 12, the timer means 6, and the display drive means 16.

  Further, the reference signal generator 14 generates a drive timing signal S7 at a predetermined interval based on the oscillation circuit output pulse S1, and outputs it to the display driver 16.

  The display driving means 16 generates a motor driving pulse S10 for normal hand movement based on the input oscillation circuit output pulse S1 and driving timing signal S7, and outputs the motor driving pulse S10 to the motor 18. The motor 18 is driven based on this motor drive pulse S10.

  The display means 20 is connected to the motor 18, and when the motor 18 is driven, the needle of the display means 20 is driven, that is, moved.

  Normally, when the secondary battery of the power supply means 2 is sufficiently charged, the needle of the display means 20 is driven at a normal speed. Normally, a driving operation at this normal speed, that is, a so-called normal hand movement operation is performed.

  In addition, although the timepiece device does not move when the entire device is in a stationary state, the charging operation is not performed, but the normal hand movement operation of the display unit 20 is continuously performed, so that the power of the power source unit 2 continues to be consumed. It will be. As a result, the power supply voltage value of the power supply means 2 continues to decrease, the reference signal generating means 14 cannot generate the oscillation circuit output pulse S1 and the drive timing signal S7, and finally the normal hand movement operation becomes impossible.

  In this case, when the power generation mechanism is operated by shaking the entire timepiece device to move the power supply unit 2 and the power supply unit 2 is charged, the timepiece device starts moving. In the two-hand timepiece device as in the present embodiment, since the movement of the minute hand and hour hand is relatively small even when the hand movement is started, the user often cannot recognize this. For this reason, in the present embodiment, when the timepiece operation associated with charging is started, a so-called modulation hand movement operation is performed in which the hands are driven at a different speed from the normal speed so as to notify the user of the start of the timepiece operation. It is configured.

  In order to perform this modulation driving, the timepiece device detects the stop state of the display unit 20 and outputs a stop detection unit 12 that outputs a stop detection signal, and the stop detection signal from the stop detection unit 12. Based on the storage means 10 for storing and outputting the stop storage signal based on this, and the power supply voltage value of the power supply means 2 is equal to or higher than the first reference voltage value higher than the operation start voltage value, the power supply voltage detection signal is output. When the power supply voltage detection signal from the power supply voltage detection means 4 is input during the input of the stop storage signal from the power supply voltage detection means 4 and the storage means 10, the drive operation of the display means 20 is started. Modulation signal generation means 8 for generating a modulation signal for notification, and the display driving means 16 modulates and drives the display means 20 based on the modulation signal.

  Here, the operation start voltage value is V1, and the first reference voltage value is V2. That is, the first reference voltage value V2 is higher than the operation start voltage value V1 so as to ensure the subsequent normal operation even if there is a temporary increase in power consumption accompanying the start of the modulation operation. Set as a value.

  With this configuration, the timepiece device has a power supply voltage value of the power supply means 2 that is equal to or less than the operation start voltage value V1, and the two-hand movement operation of the display means 20 is in a stopped state. When the power supply voltage value increases and becomes equal to or higher than the operation start voltage value V1, a normal hand movement operation is performed. When the power supply voltage value becomes equal to or higher than the first reference voltage value V2, for example, the minute hand is moved in the normal hand movement operation. Modulation drive is performed at a high speed different from the speed. By performing the modulation hand movement operation by this modulation drive, it is possible to notify the user that the hand movement operation accompanying the charging of the power supply means 2 of this timepiece device has been started.

  In particular, in the present embodiment, when the power supply means 2 of the timepiece device that has been in the hand movement stop state is charged to the hand movement operation start voltage value V1 by charging, it does not immediately perform modulation driving, and is higher than this voltage V1. By adopting a configuration in which modulation operation is performed after charging to the reference voltage value V2 of 1, even if there is a temporary voltage drop caused by modulation operation, the operation of the timepiece device can be reliably ensured. Is possible.

  The timepiece device is configured to terminate the modulation hand movement and resume the normal hand movement operation when the power supply voltage value Vss of the power supply means 2 again becomes equal to or lower than the first reference voltage value V1.

  The configuration for performing modulation hand movement will be described in detail below.

  As described above, the reference signal generation means 14 outputs the oscillation circuit output pulse S1 and the drive timing signal S7 only when the power supply voltage Vss of the power supply means 2 is equal to or higher than the operation start voltage value V1.

  Specifically, since the power supply voltage value Vss of the power supply means 2 is equal to or lower than the operation start voltage value V1 between time points t1 and t2 in FIG. 2, the oscillation circuit output pulse S1 is not output. After time t2, the power supply voltage value Vss becomes equal to or higher than the operation start voltage value V1, and the oscillation circuit output pulse S1 and the drive timing signal S7 are output from the reference signal generating means 14.

  The oscillation circuit output pulse S1 generated by the reference signal generation means 14 is output to the stop detection means 12, the timer means 6, and the display drive means 16, respectively.

  The stop detection means 12 detects the output stop of the oscillation circuit pulse S1 between t1 and t2, and outputs a stop detection signal S2 to the storage means 10.

  The storage means 10 stores and holds the input stop detection signal S2, and outputs a stop storage signal S3 indicating that the stop detection signal S2 has been input to the modulation signal generation means 8.

  On the other hand, the power supply voltage detection means 4 detects whether or not the power supply voltage value Vss of the power supply means 2 is equal to or higher than the first reference voltage value V2, and the power supply voltage value Vss becomes equal to or higher than the first reference voltage value V2. If the power is detected, the power supply voltage detection signal S4 is output to the timer means 6.

  The timer means 6 detects the time when the power supply voltage detection signal S4 is input, that is, the time when the power supply voltage value Vss is equal to or higher than the first reference voltage value V2, and this power supply voltage detection signal S4 is the predetermined time. If it is detected that the input is continued, the timer output signal S8 is output to the modulation signal generating means 8 and the storage means 10.

  Specifically, the timer means 6 includes a flip-flop, and the input time of the power supply voltage detection signal S4 is counted by this flip-flop. For example, the power supply voltage value Vss is equal to or higher than the first reference voltage value V2 between the time points t3 and t4 and between the time points t5 and t6 shown in FIG. ing. This power supply voltage detection signal S4 is input to the flip-flop of the timer means 6. In the flip-flop, timing signals Q1, Q2, and Q3 are generated, the input time of the power supply voltage detection signal S4 is counted, and it is detected whether or not the power supply voltage detection signal S4 is continuously input for a predetermined time. Specifically, in FIG. 2, when the H level outputs of the pulses of the timing signals Q1, Q2, and Q3 coincide with each other, it is detected that the power supply voltage detection signal S4 is continuously input for a predetermined time.

  In FIG. 2, since the time between time t3 and t4 and between time t5 and t6 is shorter than the predetermined time, the timer output signal S8 is not output, but the power supply voltage detection signal S4 is continuously input after time t7. At time t8, the H level outputs of the pulses of the timing signals Q1, Q2, and Q3 coincide with each other, and the predetermined time T10 is detected. As a result, the timer means 6 outputs a pulse of the timer output signal S8 at time t8. This timer output signal S8 is input to the modulation signal generating means 8 and the storage means 10.

  The storage means 10 resets the state of storing the stop storage signal S3 at the time t9 when the pulse input as the timer output signal S8 falls, and stops the output of the stop storage signal S3.

  The modulation signal generation means 8 generates the modulation signal S5 on condition that the timer output signal S8 from the timer means 6 is input while the stop storage signal S3 from the storage means 10 is being input. This modulation signal S5 is output to the display driving means 16.

  The display driving means 16 generates a motor driving pulse S10 for driving the motor 18 on the basis of the driving timing signal S7 inputted from the reference signal generating means 14 when the modulation signal S5 is not inputted. The clock display of the normal hand movement is performed.

  When the modulation signal S5 is input to the display driving means 16, the display driving means 16 generates a motor driving pulse S10 for driving the motor 18 based on the modulation signal S5. The display is performed. That is, the display driving means 16 generates a motor driving pulse S10 for driving the motor 18 based on the modulation signal S5.

  Specifically, the display driving means 16 performs a normal hand movement operation synchronized with the drive timing signal S7 when the power supply voltage value Vss is not less than the operation start voltage value V1 and not more than the first reference voltage value V2. Motor drive pulse S10 is output, and when the power supply voltage value Vss is equal to or higher than the first reference voltage value V2 and the modulation signal S5 is input, the motor for the modulation hand movement operation synchronized with the modulation signal S5 Drive pulse S10 is output. Corresponding to the change in the output of the motor drive pulse S10, the drive speed of the motor 18 is also changed, and the hand movement operation of the display means 20 driven by the motor 18 is modulated.

  Here, the relationship between the power supply voltage value Vss stored in the power supply means 2 of the timepiece device and the time T is shown in FIG.

  FIG. 3 shows a change in the power supply voltage value Vss corresponding to the passage of time when the timepiece device is moved by shaking or the like to be charged up to the point b and then discharged without moving the timepiece device. ing.

  First, for example, when the timepiece device is left unattended for a long time, the power supply voltage value Vss of the power supply means 2 is a value close to 0V, and when the hand movement operation of the timepiece device is just after stopping. The power supply voltage value Vss is a voltage value lower than the operation start voltage value V1. This operation start voltage value V1 is, for example, 0.45V.

  By continuing to move the clock device by shaking it or the like, the power supply means 2 starts the charging operation, and the power supply voltage value Vss reaches the operation start voltage value V1 at the point p, so that the normal hand movement operation is resumed. .

  Thereafter, the power supply voltage value Vss is further increased by continuously moving the timepiece device, and reaches the first reference voltage value V2 at the time point a. The first reference voltage value V2 is, for example, 1.0V.

  At this point a, when the power supply voltage value Vss continues for a predetermined time and is equal to or higher than the first reference voltage value V2, a modulation signal S5 is output from the modulation signal generating means 8 and modulated from the display driving means 16. Since the motor drive pulse S10 for the hand movement operation is output, the modulation hand movement operation is started.

  As described above, when the modulation hand movement operation is started immediately after the point p at which the power supply voltage value Vss becomes the operation start voltage value V1, the power supply voltage value Vss immediately decreases below the operation start voltage value V1, and the modulation hand movement operation is performed. In this embodiment, the modulation operation is started from the point of time point a when the power supply voltage value Vss reaches the first reference voltage value V2 at which the modulation operation can be continuously performed. Start operation. Thereby, a stable modulation hand movement operation can be performed.

  In the timepiece device of FIG. 1, the power supply voltage value Vss continues for a predetermined time to determine whether or not it is equal to or higher than the first reference voltage value V2, and adopts a configuration in which modulation hand movement is performed. Although the influence of fluctuations in the value Vss is reduced, depending on the type of the power supply means 2, there may be a small fluctuation in the power supply voltage value Vss during charging. In such a case, the modulation signal S5 may be generated immediately when the power supply voltage value Vss reaches the first reference voltage value V2, and the modulation hand movement operation may be started.

  In FIG. 3, the timepiece device continues to move to the point b. As a result, the power supply means 2 continues to be charged and the power supply voltage value Vss continues to increase. Therefore, when the power supply voltage value Vss is 0 V, when the timepiece device is continuously moved to the time point b, the time T1 becomes the charging time. Further, when the power supply voltage value Vss is the operation start voltage value V1, when the timepiece device is continuously moved to the time point b, the time T2 becomes the charging time.

  In FIG. 3, after the time point b, the movement of the timepiece is stopped and charging is stopped. Even if the charging is stopped, the modulation hand movement operation is continuously performed after the time point b, so that the power supply voltage value Vss decreases.

  The timepiece device is configured to terminate the modulation hand movement and resume the normal hand movement operation when the power supply voltage value Vss of the power supply means 2 again becomes equal to or lower than the first reference voltage value V1.

  That is, when the power supply voltage value Vss becomes equal to or lower than the first reference voltage value V2, the power supply voltage detection means 4 outputs a power supply voltage detection signal S4 indicating that to the timer means 6, and the timer means 6 detects this power supply voltage detection. When the signal S4 is continuously input for a predetermined time T3, a timer output signal S8 instructing the end of the modulation operation is output to the modulation signal generating means 8.

  Thereby, the modulation signal generating means 8 stops the output of the modulation signal S5, and the modulation operation ends.

  As described above, in the present embodiment, the modulation hand movement operation is stopped at the time point d when the predetermined time T3 has elapsed from the time point c at which the power supply voltage value Vss of the power supply means 2 again becomes equal to or lower than the first reference voltage value V1. The normal hand movement operation is resumed. Thereby, even when the time T4 from a to c is short, the modulated hand movement operation can be continuously performed for at least T3 time, and the user can be surely notified of the start of the hand movement.

  The predetermined time T3 may be arbitrarily set according to the type and use of the timepiece, and may be set to T3 = 0 in some cases. In this embodiment, T3 is set to about 4 seconds.

  In the present embodiment, the reference voltage used for determining whether to stop the modulation operation, that is, the second reference voltage value serving as the reference at the start of detection at the predetermined time T3 is set to the same value as the first reference voltage value V2. However, it may be set to any value as required. In order to secure a sufficient modulation driving time, it is preferable to set the voltage value to be not less than the operation start voltage value V1 and not more than the first reference voltage value V2.

Then, since d when the normal hand operation is performed, since the user to begin using wearing the timepiece device to the arm for example, for example, from the time of e, as shown by the solid line curve B _1, starts charging operation again As a result, the power supply voltage value Vss increases.

  In this case, the power supply voltage value Vss again exceeds the first reference voltage value V1 at the time point g, but in this case, the stop storage signal S3 stored in the storage means 10 is reset as described above. Therefore, the modulation signal S5 is not output and the normal hand movement is continued.

Further, since d when the normal hand operation is performed, if not charge the timepiece device, as shown in the dotted curve B _2, the value decreases more power-supply voltage Vss is less than the operation start voltage value V1 At the time of point f, the normal hand movement operation stops. That is, the normal hand movement operation is performed at the time T5 between the point d and the point f, and thereafter, the hand movement operation is stopped.

  The stop of the hand movement is detected by the stop detection means 12 as described above, and the stop storage signal S3 is stored in the storage means 10.

  The timepiece device also includes switch means (not shown) for adjusting time information displayed on the display means 20. This switch means is, for example, a so-called crown device. In this timepiece device, when it is detected that the switch means has been operated, the modulation signal generating means 8 is configured to stop the output of the modulation signal S5, and thereafter the drive timing signal S7 is applied. The synchronized motor drive pulse S10 is output, and the operation is switched to the normal hand movement operation. As a result, when the user sets the time during the modulation hand movement operation of the timepiece device, switching from the modulation hand movement operation to the normal hand movement operation can be performed automatically.

  Next, FIG. 4 shows a flowchart of the operation procedure of the hand movement of the display unit 20 of the timepiece device described above, and the operation of moving the hand when the power unit 2 is charged will be described.

  First, in step S2, the power supply voltage value Vss is detected. Thus, when it is determined that the power supply voltage value Vss is higher than the operation start voltage value V1, the process proceeds to step S4, and the normal hand movement operation is performed using the motor drive pulse S10 synchronized with the drive timing signal S7.

  Next, in step S6, it is determined whether or not the stop detection signal S3 is stored in the storage means 10. If it is determined that it is stored, it is next determined whether or not the power supply voltage value Vss is equal to or higher than the first reference voltage value V2. Accordingly, if it is determined that the power supply voltage value Vss is higher than the first reference voltage value V2, the process proceeds to step S8 and the timer means 6 performs a counting operation. At this time, the timer means 6 performs the counting operation only while the power supply voltage detection signal S4 from the power supply voltage detection means 4 is input.

  Then, after the counting operation is completed, it is determined in step S8 whether or not the counting operation for a predetermined time has been performed. If it is determined by this determination that the counting operation for a predetermined time has not ended, the process returns to step S6 to determine again whether or not the power supply voltage value Vss is equal to or higher than the first reference voltage value V2. It will be.

  On the other hand, if it is determined in step S8 that the counting operation for a predetermined time has been completed, the process proceeds to step S10, and the motor drive pulse S10 synchronized with the modulation signal S5 output from the modulation signal generating means 8 is used. To perform modulation operation.

  Then, it is detected in step S12 that a predetermined time has elapsed from the time point when the power supply voltage value Vss again becomes equal to or lower than the first reference voltage value V1, and the modulation hand movement is terminated, and then the normal hand movement operation is resumed in step S14. .

  By the way, when the normal hand movement is resumed, the time information displayed on the display means 20 differs from the true time information which is the current time due to the influence of the modulation hand movement operation.

  In particular, when the user completes the time adjustment during normal hand movement between the time point p and the time point a shown in FIG. 3, the time adjustment must be performed again after the completion of the modulation hand movement due to the influence of the modulation hand movement. Complexity arises.

Second Embodiment Therefore, an embodiment of a timepiece device that eliminates the complexity described above will be described below.

  FIG. 5 shows a schematic block diagram of a second embodiment of the timepiece device.

  In FIG. 5, the operation of each block indicated by the same reference numeral as that shown in FIG. 1 is the same as the operation described in FIG. 1, and thus detailed description thereof will be omitted.

  This timepiece device is configured such that the user sets the time at the true time using time adjustment means such as a crown device (not shown) during normal hand movement between the time points p and a shown in FIG. Then, after the modulation hand movement operation is finished, the time information displayed on the display means is automatically adjusted to display the true time information.

  Therefore, the timepiece device shown in FIG. 5A is configured by adding a reverse rotation control means 22 which is an embodiment of the display control means to the structure of the timepiece device shown in FIG.

  The reverse drive means 22 calculates a time difference between the time information displayed on the display means and the true time information based on the time setting while the modulation signal generating means 8 outputs the modulation signal S5, After the hand movement is completed, the time difference is corrected and the reverse drive signal S6 is output to the display drive means 16 so that the time information displayed on the display means is displayed retroactively to the true time.

  By this reverse drive signal S6, the display drive means 16 outputs a motor drive pulse S10 so as to drive the motor 18 in reverse, and the display means 20 moves the hour hand and the minute hand in the reverse direction.

  FIG. 5B shows a functional block diagram of the reverse rotation control means 22, and FIG. 6 shows a timing chart thereof.

  The reverse rotation driving means 22 of the present embodiment up-counts the pulse of the modulation signal S5 and down-counts the pulse input from the OR gate 180, and count outputs R1, R2, A detection unit 102 that detects whether or not all of R3 are 0 and outputs an H level signal S30 only when all are detected as 0, and a gate 104 that outputs a signal S32 obtained by inverting the signal S30 And an AND gate 106 for inputting the drive timing signal S7 to the OR gate 108 on condition that the gate signal S32 is at the H level.

  With the above configuration, the up / down counter 100 up-counts the pulse of the modulation signal S5 output from the modulation signal generating means 8, and simply calculates the time advanced by the modulation operation.

  As described above, when the up / down counter 100 starts the count operation, the outputs R1R2... Of the up / down counter 100 take values other than 0 as shown in FIG. When the output R1R2... Takes a value other than 0, the 0 detection unit 102 detects this and outputs an L level signal S30, and the gate 104 inverts this to generate an H level signal S32 and the AND gate 110 and AND. Output to the gate 106.

  The AND gate 106 inputs the drive timing signal S7 output from the reference signal generating means 14 to the downcount terminal of the up / down counter 100 through the OR gate 108 during the period when the H level signal S32 is input. As a result, the up / down counter 100 counts down the drive timing signal S7 input from the start of the modulation operation.

  As a result, the up / down counter 100 calculates the time difference between the current time and the true time based on the time advanced by the modulation operation obtained by up-counting and the elapsed time obtained by down-counting. Then, the count output corresponding to the time difference is output from R1, R2, and R3. Therefore, the 0 detection unit 102 outputs the H level signal S32 to the AND gates 110 and 106 through the gate 104 until the count output of the up / down counter 100 becomes 0.

  Further, as shown in FIG. 6, the modulation signal generating means 8 of the present embodiment outputs an H level signal S20 during the modulation driving period for outputting the modulation signal S5, and the reverse rotation driving means 22 outputs the H level. The signal S20 is input to the AND gate 110.

  Further, the reverse rotation driving means 22 includes a frequency dividing circuit 114 that divides the output pulse S1 output from the reference signal generation means 14 and generates a timing signal for reverse rotation driving of a predetermined period. It is configured to input to 110.

  As a result, an H level signal S20 indicating that the modulation driving period is in progress and an H level signal S32 indicating that the count output of the up / down counter 100 is a value other than 0 are input to the AND gate 110. During this period, the timing signal output from the frequency dividing circuit 114 is output to the display driving means 16 as it is as the pulse signal of the reverse drive signal S6.

  Furthermore, the pulse of the reverse drive signal S6 output from the AND gate 110 at this time is fed back to the down count terminal of the up / down counter 100 via the OR gate 108.

  With the above-described configuration, the reverse rotation driving means 22 of the present embodiment is configured so that the current display time and the true time are based on the time advanced by the modulation operation obtained by up-counting and the elapsed time obtained by down-counting. Thus, the reverse drive signal S6 is output to the display drive means so that the time difference from the time becomes zero.

  Although the time elapses even during the output period of the reverse drive signal S6, the drive timing signal S7 is input to the down count terminal of the up / down counter 100 in the up / down counter 100 even during this period. Therefore, the reverse drive signal S6 is output in consideration of the passage of time during the reverse drive period.

  Thus, the reverse drive signal S6 is output from the reverse drive means 22 so as to display the true time that the display means 20 would have displayed if there was no modulation hand movement.

  FIG. 7 shows an operation flowchart of the present embodiment. The operations in steps S22 to S28, S30, and S34 are the same as the operations in steps S2 to S8, S10, S12, and S14 in FIG.

  In the present embodiment, when the modulation hand movement operation of step S28 is started, at the same time, in step S29, the reverse drive means 22 calculates the time difference between the current display time and the true time.

  Then, after the completion of the modulation operation in step S30, in step S32, the display means 20 is driven in reverse based on the time difference calculated in step S29 to perform an accurate time display operation.

  Thereafter, the normal hand movement operation is resumed in step S34.

Third Embodiment FIG. 8 shows a schematic block diagram of a third embodiment of the timepiece device.

  The timepiece device of the third embodiment shown in FIG. 8 (A) is provided with a display control means 24 instead of the reverse rotation control means 22 of the timepiece device of the second embodiment shown in FIG. 5 (A). It is characterized by that.

  FIG. 8B shows a functional block diagram of the display control means 24, and FIG. 9 shows a timing chart thereof.

  The configuration of the up / down counter 100, the 0 detection unit 102, the gate 104, and the AND gate 106 constituting the display control means 24 is the same as that of the reverse rotation control means 22 shown in FIG. Then, the explanation is omitted.

  FIG. 10 shows an operation flowchart of the timepiece device according to the present embodiment. Here, steps S42 to S50 and S54 correspond to steps S22 to S30 and S34 in the operation flowchart shown in FIG.

  In the timepiece device of the present embodiment, when the modulation hand movement operation in step S48 is started, the display control means 24 calculates the time difference between the true time and the time advanced by the modulation hand movement as shown in step S49. Since the configuration for calculating the time difference is the same as the configuration of the reverse rotation driving means 22 shown in FIG. 5, the description thereof is omitted here.

  When the modulation hand movement ends in step S50, the display control means 24 outputs a display control signal S9 for stopping the hand movement to the display drive means 16 in step S52.

  The display driving unit 16 is configured to stop the output of the motor driving pulse S10 without receiving the driving timing signal S7 output from the reference signal generating unit 14 during the output period of the display driving signal S9.

  Here, the display control means 24 is based on the drive timing signal S7 output from the reference signal generating means 14, and the amount of deviation between the time currently displayed on the display means 22 in the state where the hand movement is stopped and the true time. Is calculated using the up / down counter 100, and the display control signal S9 is outputted to the display driving means 16 until the amount of deviation becomes zero, and when the time difference becomes zero, the signal output is stopped.

  The display drive means 16 starts outputting the motor drive pulse S10 based on the drive timing signal S7 from the time when the display control signal S9 is not input. As a result, the normal hand movement operation in step S54 is started, and the time display by the normal hand movement is resumed on the display means 26.

Other Embodiments The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the gist of the present invention.

  For example, in each of the above embodiments, the power supply voltage value Vss is compared with the reference voltage V2, and the modulation operation is stopped. However, the present invention is not limited to this, and the modulation operation is performed based on other conditions. You may comprise so that it may stop. For example, timer means for counting the elapsed time from the start time of the modulation hand movement may be provided, and the output of the modulation signal S5 may be stopped when the timer means detects the elapse of a predetermined time.

  Here, the timer means may be formed integrally with the modulation signal generating means, or may be formed separately.

  In addition, the timepiece device of the present invention starts moving hands to control the display driving means to the normal hand movement prohibition state until the end of the modulation driving when the stop storage signal is stored in the storage means as necessary. You may comprise so that a control means may be included.

  That is, when the hand movement start control means is not provided, normal hand movement is started immediately when the power supply voltage value exceeds the operation start voltage due to the start of the charging operation of the power supply means, and the operation may become unstable due to the power consumption by this. There is. On the other hand, by providing the hand movement start control means, it is possible to inhibit normal hand movement and suppress power consumption until the charging of the power supply means reaches a sufficient stage, that is, until the modulation hand movement is completed. Thus, charging at the start of the charging operation can be performed effectively, and the timepiece device can be promptly brought into a stable hand movement state after the start of charging.

  In particular, since the normal driving is started for the first time when the modulation driving is completed, the occurrence of a situation where the modulation driving is suddenly performed immediately after the start of the normal driving is prevented, and a timepiece device that is more suitable for the user's sense is provided. Can be obtained.

  Here, the movement start control means may be formed integrally with the modulation movement generation means, or may be formed as a separate body, if necessary.

  Further, in each of the embodiments described above, the case where the modulation driving is performed by the modulation operation of the analog display hand has been described as an example, but the present invention is not limited to this, and for other digital display type watches, You may comprise so that the same modulation drive may be performed. In this case, the modulation drive may be formed visually and audibly as necessary.

1 is a schematic block diagram of an embodiment of a timepiece device according to the present invention. 2 is a timing chart of each signal in the timepiece device of FIG. 1. It is a figure for demonstrating an example of charge operation and discharge operation of a timepiece device. It is a flowchart explaining the hand movement operation | movement procedure of the timepiece apparatus of FIG. FIG. 5 is a schematic block diagram of a second embodiment of the timepiece device, in which FIG. (A) is an overall view and FIG. (B) is a block diagram of reverse rotation control means. 6 is a timing chart of each signal in the timepiece device of FIG. 5. It is a flowchart explaining the hand movement operation | movement procedure of the timepiece apparatus of FIG. It is a schematic block diagram of 3rd Embodiment of a timepiece apparatus, The figure (A) is the whole figure, The figure (B) is a block diagram of a display control means. It is a timing chart of each signal in the timepiece device of FIG. It is a flowchart explaining the hand movement operation | movement procedure of the timepiece apparatus of FIG.

Explanation of symbols

  2 power supply means, 4 power supply voltage detection means, 6 timer means, 8 modulation signal detection means, 10 storage means, 12 stop detection means, 14 reference signal detection means, 16 display drive means, 18 motor, 20 display means, 22 reverse drive Means, 24 display control means

Claims (14)

Display means for displaying time information;
Display driving means for driving the display means;
When detecting the stop state of the display means, stop detection means for outputting a stop detection signal;
Storage means for storing and outputting a stop storage signal based on the stop detection signal from the stop detection means;
Power supply voltage detection means for outputting a power supply voltage detection signal when the power supply voltage value of the power supply means is equal to or higher than a first reference voltage value set higher than the operation start voltage value;
When the power supply voltage detection signal is input from the power supply voltage detection means while the stop storage signal is input from the storage means, a modulation signal that generates a modulation signal for notifying the start of driving operation of the display means Generating means;
Have
The timepiece device, wherein the display driving means modulates and drives the display means based on the modulation signal. In claim 1,
A reference signal generating means for generating a reference signal when a voltage capable of driving the display driving means is stored in the power supply means;
The timepiece detecting device outputs the stop detection signal when the reference signal is not output from the reference signal generating unit. In any one of Claims 1, 2.
The timepiece storage device in which the state of the stop storage signal is reset according to a predetermined condition after the input of the power supply voltage detection signal from the power supply voltage detection means. In any one of Claims 1-3,
The timepiece device, wherein the power supply means includes a power generation means and a power storage means, and the power storage means charges the power storage means. In any one of Claims 1-4,
The display means includes at least two hands of a minute hand and an hour hand,
A timepiece device in which at least one of the two hands is driven to be modulated. In any one of Claims 1-5,
The timepiece device, wherein the modulation signal generation means outputs the modulation signal after the power supply voltage detection signal from the power supply voltage detection means is continuously input for a predetermined time. In any one of Claims 1-6,
The modulation signal generating means stops the output of the modulation signal after a predetermined time has elapsed when the power supply voltage detection means detects a power supply voltage value equal to or lower than a second reference voltage value. apparatus. In any one of Claims 1-7,
A timepiece apparatus comprising: display control means for outputting a display control signal for adjusting time information displayed on the display means for time adjustment to the display driving means. In claim 8,
The display control means reversely displays the time information displayed on the display means retroactively until the time advanced by the modulation drive after the output of the modulation signal stops coincides with the time displayed by the normal drive. A timepiece device that outputs a driving signal to the display driving means. In claim 8,
The display control means outputs a display control signal for stopping the drive of the display means to the display drive means until the time advanced by the modulation drive coincides with the time displayed by the normal drive. Watch device. In any one of Claims 1-10,
Including switch means for outputting a switch signal;
The timepiece apparatus according to claim 1, wherein the modulation signal generating means stops outputting the modulation signal when a switch signal is input from the switch means. In any one of Claims 1-11,
Timer means for measuring an elapsed time of the modulation drive,
The timepiece apparatus according to claim 1, wherein the modulation signal generating means stops the output of the modulation signal when the modulation drive has passed for a given time. In any one of Claims 1-12,
A timepiece apparatus comprising drive start control means for controlling the display drive means to a normal drive prohibited state until the end of the modulation drive when the stop storage signal is stored in the storage means. In any one of Claims 1-13,
The timepiece device is characterized in that the display means electronically displays the time.

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