JP3654056B2 - Electronic timepiece and control method of electronic timepiece - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic timepiece and an electronic timepiece control method, and more particularly to an electronic timepiece and an electronic timepiece control method for displaying a remaining energy level of a power supply means.
[0002]
[Prior art]
In recent years, a wristwatch-type electronic timepiece has built-in power supply means, and this power supply means is roughly constituted by a power generation device having a rotating weight and power storage means (large capacity capacitor) for storing electric energy generated from the power generation device. ing. And this kind of electronic timepiece performs the timepiece operation for a long time without replacing the battery by displaying the time on the time display unit using the electric energy discharged from the capacitor. .
[0003]
[Problems to be solved by the invention]
In this way, the electronic timepiece incorporating the power supply means having the power generation device supplies stable electric energy over a long period of time, so when the power generation device continues in the non-power generation state or the non-portable state for a predetermined time or longer, Or, when the mode is forcibly switched by the user, these states are detected, and the mode of the electronic timepiece is switched from the driving mode (display mode) for displaying time to the power saving mode for not displaying time. It was like that. For example, in an analog timepiece, the driving of the hands is stopped.
[0004]
By the way, although the time is not displayed in this power saving mode, electric energy is supplied to a part of the drive control circuit in order to count the current time. For this reason, electric energy is consumed even in the power saving mode, and the user cannot know the remaining amount of electric energy in the power supply means when in the power saving mode, and knows the period during which the state of the power saving mode can be maintained. There is a problem that you can not.
[0005]
In addition, when the power saving mode is executed for a long time and the electric energy stored in the power storage means of the power supply means has been reduced, the operation mode of the time display unit is changed from the power saving mode to the display mode. In the case of switching, it takes time to store electric energy necessary for driving the time display unit in the power supply means, and the time display unit may not be driven immediately. In such a case, the user may think that the electronic timepiece is out of order.
[0006]
Further, in the conventional electronic timepiece, the user himself / herself cannot arbitrarily confirm the amount of electric energy of the power supply means.
[0007]
The present invention has been made in view of the above-described circumstances, and it is an object of the present invention to provide an electronic timepiece and an electronic timepiece control method capable of displaying the amount of electric energy of power supply means.
[0008]
[Means for Solving the Problems]
In order to solve the above problem, the invention according to claim 1 is a power supply means for supplying electric energy, Said Drive control means which operates by electric energy supplied from the power supply means and outputs a drive signal; Said Driven means driven in response to a drive signal; Said Time display means for displaying time by driving the driven means, and mode switching for switching the operation mode of the driven means between a driving mode for normal driving and a power saving mode based on preset conditions Means, Electric energy amount detecting means for detecting the amount of electric energy supplied from the power supply means; and When shifting the operation mode of the driven means from the drive mode to the power saving mode by the mode switching means, Electric energy amount detected by the electric energy amount detecting means Energy remaining amount display means for displaying The electric energy amount detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means. It is characterized by that.
[0009]
Claim 2 In The described invention includes power supply means for supplying electrical energy; Said Drive control means which operates by electric energy supplied from the power supply means and outputs a drive signal; Said Driven means driven in response to a drive signal; Said Time display means for displaying time by driving the driven means, and mode switching for switching the operation mode of the driven means between a driving mode for normal driving and a power saving mode based on preset conditions Means, Electric energy amount detecting means for detecting the amount of electric energy supplied from the power supply means; and When shifting the operation mode of the driven means from the drive mode to the power saving mode by the mode switching means, Electric energy amount detected by the electric energy amount detecting means Energy remaining amount display means for displaying the time using the time display means. The electric energy amount detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means. It is characterized by that.
[0010]
Claim 3 In The described invention includes power supply means for supplying electrical energy; Said A drive control means that operates by electrical energy supplied from a power supply means and outputs a drive signal; and a driven means that is driven by receiving the drive signal; Said Time display means for displaying time by driving the driven means; Said Date display means that is driven by the driven means and displays the date; and mode switching means that switches the operation mode of the driven means between a drive mode for performing normal driving and a power saving mode based on preset conditions; , Electric energy amount detecting means for detecting the amount of electric energy supplied from the power supply means; and When shifting the operation mode of the driven means from the drive mode to the power saving mode by the mode switching means, Electric energy amount detected by the electric energy amount detecting means Energy remaining amount display means for displaying using the date display means, The electric energy amount detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means. It is characterized by that.
[0011]
The invention according to claim 4 is a power supply means for supplying electric energy, Said Drive control means which operates by electric energy supplied from the power supply means and outputs a drive signal; Said Driven means driven in response to a drive signal; Said The time display means driven by the driven means for displaying the time, the date display means driven by the driven means for displaying the date, and the operation mode of the driven means based on preset conditions. Mode switching means for switching between a driving mode for normal driving and a power saving mode; Electrical energy amount detection means for detecting the amount of electrical energy supplied from the power supply means; The date display means has a display mode different from the date display mode by the date display means when the mode switching means shifts the operation mode of the driven means from the drive mode to the power saving mode. Electric energy amount detected by the electric energy amount detecting means Energy remaining amount display means for displaying The electric energy amount detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means. It is characterized by that.
[0012]
Claim 5 In In the electronic timepiece according to claim 1, 2, 3 or 4, the power source means includes power generation means for converting external energy into electric energy, Said Power storage means for storing electric energy supplied from the power generation means and supplying the electric energy to the drive control circuit, and the power storage means includes a storage capacity detection means for detecting the storage capacity of the power storage means. The remaining energy displayed by the remaining energy display means is the storage capacity detected by the storage capacity detection means.
[0013]
Claim 6 In In the electronic timepiece according to claim 1, 2, 3 or 4, the power source means includes power generation means for converting external energy into electric energy, Said Power storage means for storing electrical energy supplied from the power generation means; Said A step-up / step-down means for stepping up / down the electric energy stored in the power storage means, and the step-up / step-down means is provided with an electric energy amount detecting means for detecting an electric energy amount output from the step-up / step-down means, The remaining amount of energy displayed by the remaining amount display means is the amount of electric energy detected by the electric energy amount detecting means.
[0014]
Claim 7 In In the electronic timepiece according to claim 1, 2, 3 or 4, the power source means includes power generation means for converting external energy into electric energy, Said A power storage unit that stores electrical energy supplied from the power generation unit and supplies the electric energy to the drive control unit, and the power generation unit detects whether or not the power generation unit is in a power generation state. Power generation state detection means is provided, and the condition is whether or not the power generation state detection means detects that the power generation means is in a power generation state.
[0015]
According to an eighth aspect of the present invention, in the electronic timepiece according to the seventh aspect, the power generation state detection means determines whether or not the amount of electrical energy output from the power generation means exceeds a determination energy amount. Means, Said And a power generation time determination means for determining whether or not the duration of the state in which the electric energy amount exceeds the determination energy amount by the energy amount determination means exceeds the determination time value.
[0016]
According to a ninth aspect of the present invention, in the electronic timepiece according to the first, second, third, or fourth aspect, the drive control means is operated by electric energy supplied from the power supply means and outputs a control signal; A drive circuit that operates by electrical energy supplied from the power supply means, receives a control signal output from the control circuit, and outputs a drive signal toward the driven means; In the drive mode, electrical energy is supplied to the control circuit and the drive circuit, and in the power saving mode, electrical energy is supplied only to the control circuit.
[0017]
The invention according to claim 10 is the electronic timepiece according to claim 1, 2, 3 or 4, Said Portable state detecting means for detecting whether or not the electronic timepiece is in a portable state is provided, and the condition is that the portable state detecting means is used when the operation mode of the driven means is switched from the driving mode to the power saving mode. And detecting whether the electronic timepiece is in a non-portable state, whether or not a predetermined time has elapsed for the electronic timepiece being in a non-portable state, and changing the operation mode of the driven means from the power saving mode to the driving mode. When the mode is switched, the electronic timepiece is switched from the non-portable state to the portable state by the portable state detecting means.
[0018]
According to an eleventh aspect of the present invention, in the electronic timepiece according to the first, second, or third aspect, the energy remaining amount display means displays as a predetermined remaining amount display mode.
[0019]
According to a twelfth aspect of the present invention, in the electronic timepiece according to the first, second, third, or fourth aspect, when the drive control means is switched from the power saving mode to the drive mode by the mode switching means, the time display is the current time. It is characterized by comprising a current time return means for performing a return operation for returning.
[0020]
According to a thirteenth aspect of the present invention, in the electronic timepiece according to the fourth aspect, the date display means displays the date when the mode switching means shifts the operation mode of the driven means from the drive mode to the power saving mode. Means use numbers from 1 to 10 Electric energy amount detected by the electric energy amount detecting means Is displayed.
[0021]
According to a fourteenth aspect of the present invention, a power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a drive signal output from the drive control unit A driven unit that is driven by receiving, a time display mechanism that is driven by the driven unit and displays a time, An electric energy detection device for detecting the amount of electric energy supplied from the power supply unit and monitoring the amount of energy; A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition; Said When at least the operation mode of the driven unit is shifted from the drive mode to the power saving mode by the mode switching step, Electrical energy detected and monitored by the electrical energy detector And an energy remaining amount display step for updating the display.
[0022]
According to a fifteenth aspect of the present invention, a power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a drive signal output from the drive control unit A driven unit that is driven by receiving, a time display mechanism that is driven by the driven unit and displays a time, An electric energy detection device for detecting the amount of electric energy supplied from the power supply unit and monitoring the amount of energy; A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition; Said When at least the operation mode of the driven unit is shifted from the drive mode to the power saving mode by the mode switching step, Electrical energy detected and monitored by the electrical energy detector Is displayed using the time display mechanism. And update its display And a remaining energy display step.
[0023]
According to a sixteenth aspect of the present invention, a power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a drive signal output from the drive control unit Driven by the driven unit, a time display mechanism that is driven by the driven unit and displays the time, and driven by the driven unit and displays the date in addition to the time display by the time display mechanism. A date display mechanism to perform, An electric energy detection device for detecting the amount of electric energy supplied from the power supply unit and monitoring the amount of energy; A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition; Said When at least the operation mode of the driven unit is shifted from the drive mode to the power saving mode by the mode switching step, Electrical energy detected and monitored by the electrical energy detector Is displayed using the date display mechanism. And update its display And a remaining energy display step.
[0024]
According to a seventeenth aspect of the present invention, there is provided a power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a drive signal output from the drive control unit. Driven by the driven unit, a time display mechanism that is driven by the driven unit and displays a time, and a time display that is driven by the driven unit and is displayed by a number in addition to the time display by the time display mechanism. A date display mechanism for displaying, An electric energy detection device for detecting the amount of electric energy supplied from the power supply unit and monitoring the amount of energy; A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition; Said When at least the operation mode of the driven unit is shifted from the drive mode to the power saving mode by the mode switching step, The amount of electrical energy detected and monitored by the electrical energy detection device Display using a number different from the number for date used in the date display function. And update its display And a remaining energy display step.
[0025]
The invention according to claim 18 is the claim of claim 14, 15, 16, or 17 In the electronic timepiece control method described above, the power supply unit includes a power generation device that converts external energy into electrical energy, and a power storage device that stores the electrical energy supplied from the power generation device and supplies the electrical energy. , Said A power storage capacity detection step for detecting a power storage capacity of the power storage device is provided, and the remaining energy displayed in the remaining energy display step is the storage capacity detected in the storage capacity detection step.
[0026]
Claim 19 In The described invention is claimed. 14, 15, 16, or 17 In the electronic timepiece control method described above, the power supply unit includes: a power generation device that converts external energy into electrical energy; a power storage device that stores the electrical energy supplied from the power generation device and supplies the electrical energy; and the power storage A step-up / step-down circuit for stepping up / down electric energy output from the device, Said An electric energy amount detecting step for detecting an electric energy amount output from the step-up / step-down circuit is provided, and the remaining amount of energy displayed by the remaining energy amount displaying step is the amount of electric energy detected in the electric energy amount detecting step. It is characterized by doing.
[0050]
DETAILED DESCRIPTION OF THE INVENTION
Next, preferred embodiments of the present invention will be described with reference to the drawings.
[0051]
[1] First embodiment
First, the first embodiment will be described.
[0052]
[1.1] Outline configuration
FIG. 1 shows a schematic configuration of an electronic timepiece 1 according to an embodiment of the present invention.
The electronic timepiece 1 is a wristwatch, and a user uses a belt connected to the apparatus main body by wrapping it around a wrist.
[0053]
The electronic timepiece 1 according to the present embodiment includes a power generation unit A that generates AC power, and a power source unit that rectifies the AC voltage supplied from the power generation unit A and stores the boosted voltage and supplies electric energy to each component. B, a control circuit 23 that is operated by the electric energy output from the power supply unit B and controls the entire apparatus, a second hand moving mechanism CS that drives the second hand 55 using the stepping motor 10, and a stepping motor for the minute hand and hour hand The second hand driving circuit 30S for driving the second hand moving mechanism CS in response to the control signal output from the control circuit 23, and the control signal output from the control circuit 23. The hour / minute hand driving circuit 30HM for driving the hour / minute hand movement mechanism CHM and the mode of the electronic timepiece 1 are changed from the time display mode to the calendar correction mode, the time correction mode, or forcibly. External input device 100 comprising a crown or button for performing an instruction operation for shifting to the power saving mode to predicates and a (see FIG. 2). In addition, the control circuit 23 includes a power generation state detection unit 91 that detects the power generation state of the power generation unit A, and a voltage detection circuit 92 that detects electrical energy (post-step-up / down voltage VSS) output from the power supply unit B. ing.
[0054]
Here, according to the power generation state of the power generation unit A, the control circuit 23 supplies power to the control circuit 23 and the driving circuits 30S and 30HM (driving circuits) of the fingering mechanisms CS and CHM, thereby displaying the time. (Operation mode) and a function of mode switching means for switching between the second hand moving mechanism CS and the hour / minute hand moving mechanism CHM and switching to the power saving mode in which power is supplied only to the control circuit 23. In the control circuit 23, as will be described later, when the user wraps the electronic timepiece 1 around the wrist and shakes it to generate power, the generated voltage exceeds a predetermined power generation voltage. The mode is switched from the power saving mode to the display mode.
[0055]
[1 ・ 2] Detailed configuration
Hereinafter, each component of the electronic timepiece 1 will be described. The control circuit 23 will be described later using functional blocks.
[0056]
[1 ・ 2 ・ 1] Power generation unit
First, the power generation unit A will be described.
The power generation unit A includes a power generation device 40, a rotary weight 45, and a speed increasing gear 46.
As the power generation device 40, an electromagnetic induction type AC power generation device is used in which the power generation rotor 43 rotates inside the power generation stator 42 and the power induced in the power generation coil 44 connected to the power generation stator 42 can be supplied to the outside. Has been.
The rotary weight 45 functions as a means for transmitting kinetic energy to the power generation rotor 43. The movement of the rotating weight 45 is transmitted to the power generation rotor 43 via the speed increasing gear 46.
In the wristwatch-type electronic timepiece 1, the rotary weight 45 can be turned in the device by capturing the movement of the user's arm, and generates power using external energy related to the user's life. The electronic timepiece 1 is driven using the electric power.
[0057]
[1 ・ 2 ・ 2] Power supply
Next, the power supply unit B will be described.
The power supply unit B includes a limiter circuit LM for preventing an excessive voltage from being applied to a subsequent circuit, a diode 47 that functions as a rectifier circuit, a large-capacitance capacitor 48, and a step-up / down circuit 49. .
Here, the step-up / step-down circuit 49 can perform step-up and step-down in multiple stages using a plurality of capacitors 49a, 49b and an auxiliary capacitor 49c, and a second hand drive circuit according to a control signal φ11 output from the control circuit 23. The voltage supplied to 30S and the hour / minute hand drive circuit 30HM is adjusted.
The power supply unit B takes Vdd (high potential side) as a reference potential (GND) and generates Vss (low potential side) as a power supply voltage (hereinafter referred to as a voltage Vss after step-up / down).
[0058]
[1 ・ 2 ・ 3] Explanation of buck-boost circuit
Here, with reference to FIGS. 3 to 8, the configuration and operation of the step-up / step-down circuit will be described by way of example in the case of boosting.
[0059]
<1 ・ 2 ・ 3 ・ 1> Configuration of buck-boost circuit
As shown in FIG. Large capacitor 48 Switch SW1 with one terminal connected to the high potential side terminal, one terminal connected to the other terminal of switch SW1, and the other terminal Large capacitor 48 Switch SW2 connected to the low potential side terminal, capacitor 49a having one terminal connected to the connection point of switch SW1 and switch SW2, one terminal connected to the other terminal of capacitor 49a, and the other terminal Terminal is Large capacitor 48 A switch SW3 connected to the low potential side terminal, a switch SW4 having one terminal connected to the low potential side terminal of the auxiliary capacitor 49c and the other terminal connected to a connection point between the capacitor 49a and the switch SW3, Large capacitor 48 Switch SW11 having one terminal connected to the connection point between the high potential side terminal of the auxiliary capacitor 49c and the high potential side terminal of the auxiliary capacitor 49c, and one terminal connected to the other terminal of the switch SW11. Large capacitor 48 Switch SW12 connected to the low potential side terminal, capacitor 49b having one terminal connected to the connection point of switch SW11 and switch SW12, one terminal connected to the other terminal of capacitor 49b, and switch SW12. When Large capacitor 48 Switch SW13 having the other terminal connected to the connection point with the low potential side terminal, one terminal connected to the connection point between capacitor 49b and switch SW13, and the other terminal Auxiliary capacitor 49c A switch SW14 connected to the low potential side terminal, a switch SW21 having one terminal connected to the connection point between the switch SW11 and the switch SW12, and the other terminal connected to the connection point between the capacitor 49a and the switch SW3. , And is configured.
[0060]
<1, 2, 3, 2> Operation of buck-boost circuit
The operation of the step-up / step-down circuit 49 will be described with reference to FIGS. 4 to 8 at the time of 3 × boosting, 2 × boosting, 1.5 × boosting, 1 × boosting (short mode), and 1 × boosting (charge) Transfer mode) will be described as an example.
[0061]
<1 ・ 2 ・ 3 ・ 2 ・ 1> During triple boosting
The step-up / step-down circuit 49 operates based on a boost clock CKUD input from the outside. At the time of triple boosting, as shown in FIG. 4, at the first boost clock timing (parallel connection timing), the switch SW1. ON, switch SW2 OFF, switch SW3 ON, switch SW4 OFF, switch SW11 ON, switch SW12 OFF, switch SW13 ON, switch SW14 OFF, switch SW21 OFF.
The equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 5A. Power is supplied to the capacitors 49a and 49b from the large-capacitance capacitor 48, and the voltages of the capacitors 49a and 49b are large. Charging is performed until the voltage of the capacitor 48 becomes substantially equal.
[0062]
Next, at the second boost clock timing (serial connection timing), the switch SW1 is turned off, the switch SW2 is turned on, the switch SW3 is turned off, the switch SW4 is turned off, the switch SW11 is turned off, the switch SW12 is turned off, and the switch SW13 is turned on. The switch SW14 is turned on and the switch SW21 is turned on. The equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 5B. The large-capacitance capacitor 48, the capacitor 49a, and the capacitor 49b are connected in series, and are three times the voltage of the large-capacitance capacitor 48. The auxiliary capacitor 49c is charged at a voltage of 3 to achieve a triple boost.
[0063]
<1, 2, 3, 2, 2> During double boosting
The step-up / step-down circuit 49 operates based on the boost clock CKUD input from the outside, and at the time of double boost, as shown in FIG. 4, at the first boost clock timing (parallel connection timing), the switch SW1. ON, switch SW2 OFF, switch SW3 ON, switch SW4 OFF, switch SW11 ON, switch SW12 OFF, switch SW13 ON, switch SW14 OFF, switch SW21 OFF.
The equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 6A. Power is supplied from the large-capacitance capacitor 48 to the capacitors 49a and 49b, and the voltages of the capacitors 49a and 49b are large. Charging is performed until the voltage of the capacitor 48 becomes substantially equal.
[0064]
Next, in the second boost clock timing (serial connection timing), the switch SW1 is turned off, the switch SW2 is turned on, the switch SW3 is turned off, the switch SW4 is turned on, the switch SW11 is turned off, the switch SW12 is turned on, and the switch SW13 is turned on. The switch SW14 is turned off and the switch SW21 is turned off. An equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 6B. A large-capacitance capacitor 48 is connected in series to the capacitors 49a and 49b connected in parallel, and the large-capacity The auxiliary capacitor 49c is charged with a voltage twice the voltage of the capacitor 48, and double boosting is realized.
[0065]
<1, 2, 3, 2, 3> 1.5 times boost
The step-up / step-down circuit 49 operates based on the boost clock CKUD input from the outside. At the time of 1.5-fold boost, as shown in FIG. 4, at the first boost clock timing (parallel connection timing), The switch SW1 is turned on, the switch SW2 is turned off, the switch SW3 is turned off, the switch SW4 is turned off, the switch SW11 is turned off, the switch SW12 is turned off, the switch SW13 is turned on, the switch SW14 is turned off, and the switch SW21 is turned on.
The equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 7A. Power is supplied to the capacitors 49a and 49b from the large-capacitance capacitor 48, and the voltages of the capacitors 49a and 49b are large. Charging is performed until the voltage is approximately equal to ½ of the voltage of the capacitor 48.
[0066]
Next, in the second boost clock timing (serial connection timing), the switch SW1 is turned off, the switch SW2 is turned on, the switch SW3 is turned off, the switch SW4 is turned on, the switch SW11 is turned off, the switch SW12 is turned on, and the switch SW13 is turned on. The switch SW14 is turned off and the switch SW21 is turned off. The equivalent circuit of the step-up / step-down circuit 49 in this case is as shown in FIG. 7B. A large-capacitance capacitor 48 is connected in series to the capacitors 49a and 49b connected in parallel, and the large-capacity The auxiliary capacitor 49c is charged with a voltage 1.5 times the voltage of the capacitor 48, and a 1.5-fold boost is realized.
[0067]
<1, 2, 3, 2, 4> When boosted 1 time (when not boosted; short mode)
As shown in FIG. 4, the step-up / down circuit 49 always turns off the switch SW1, turns on the switch SW2, turns on the switch SW3, turns on the switch SW4, turns off the switch SW11, turns on the switch SW12, as shown in FIG. The switch SW13 is turned on, the switch SW14 is turned on, and the switch SW21 is turned off.
The connection state of the step-up / step-down circuit 49 in this case is as shown in FIG. 8A, and its equivalent circuit is as shown in FIG. 8B, and the large-capacitance capacitor 48 is replaced by the auxiliary capacitor 49c. It becomes a state directly connected to.
In this way, the step-up / step-down circuit 49 outputs the post-step-up / down voltage VSS by stepping up / down the charging voltage Vc of the large-capacitance capacitor 48 at a predetermined magnification.
[0068]
[1, 2, 4] Hand movement mechanism
Next, the hand movement mechanisms CS and CHM will be described.
<1, 2, 4.1> Second hand movement mechanism
First, the second hand movement mechanism CS will be described.
Here, the stepping motor 10 used in the second hand moving mechanism CS is also called a pulse motor, a stepping motor or a digital motor, and is often used as an actuator of a digital control device. The stepping motor 10 is driven by a pulse signal. It is what is done. In recent years, this type of stepping motor, which has been reduced in size and weight, has been widely used as a compact electronic timepiece suitable for carrying or an actuator for information equipment. Examples of such electronic timepieces include time switches and chronographs.
[0069]
The stepping motor 10 of this embodiment includes a drive coil 11 that generates a magnetic force by a drive pulse supplied from the second hand drive circuit 30S, a stator 12 that is excited by the drive coil 11, and a magnetic field that is excited inside the stator 12. And a rotor 13 that rotates.
The rotor 13 is a PM type (permanent magnet rotating type) having a disk-shaped two-pole permanent magnet, and different magnetic poles due to the magnetic force generated by the drive coil 11 are provided on the stator 12 around the rotor 13. A magnetic saturation portion 17 generated in each phase (pole) 15 and 16 is provided.
Further, in order to define the rotation direction of the rotor 13, an inner notch 18 is provided at an appropriate position on the inner periphery of the stator 12, and a cogging torque is generated to stop the rotor 13 at an appropriate position. Yes.
[0070]
The rotation of the rotor 13 by the stepping motor 10 is transmitted to the second hand 53 by a wheel train 50 including a second intermediate wheel 51 and a second wheel (second indicating wheel) 52 meshed with the rotor 13, and the second hand 53 displays a second display. Has been made.
[0071]
<1, 2, 4, 2> Hour and minute hand movement mechanism
Next, the hour / minute hand movement mechanism CHM will be described. The stepping motor 60 used in the hour / minute hand movement mechanism CHM has substantially the same configuration as the stepping motor 10.
[0072]
The stepping motor 60 of this embodiment is excited in a drive coil 61 that generates a magnetic force by a drive pulse supplied from the hour / minute drive circuit 30HM, a stator 62 excited by the drive coil 61, and further inside the stator 62. And a rotor 63 rotated by a magnetic field.
Further, the rotor 63 is configured as a PM type (permanent magnet rotation type) having a disk-shaped two-pole permanent magnet. Further, the stator 62 is provided with a magnetic saturation portion 67 in which different magnetic poles due to the magnetic force generated in the drive coil 61 are generated in the respective phases (poles) 65 and 66 around the rotor 63.
Further, in order to define the rotation direction of the rotor 63, an inner notch 68 is provided at an appropriate position on the inner periphery of the stator 62 so that cogging torque is generated to stop the rotor 63 at an appropriate position. Yes.
[0073]
Then, the rotation of the rotor 63 of the stepping motor 60 causes the fourth wheel 71, third wheel 72, second wheel (minute indicator wheel) 73, minute wheel 74 and hour wheel (hour indicator wheel) meshed with the rotor 63. ) Is transmitted to each needle by a train wheel 70 consisting of 75. A minute hand 76 is connected to the second wheel & pinion 73, and an hour hand 77 is connected to the hour wheel 75. The hour and minute are displayed by these hands in conjunction with the rotation of the rotor 63.
The train wheel 70 has a transmission system for displaying a date and time (calendar) (not shown) (for example, when displaying a date, a cylinder intermediate wheel, a date turning intermediate wheel, a date turning wheel, a date) It is of course possible to connect a car or the like. In this case, a calendar correction system wheel train (for example, a first calendar correction transmission wheel, a second calendar correction transmission wheel, a calendar correction wheel, a date wheel, etc.) may be additionally provided.
[0074]
[1 ・ 2 ・ 5] Second hand drive circuit and hour / minute hand drive circuit
Next, the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM will be described. Here, since the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM have the same configuration, only the second hand drive circuit 30S will be described with reference to FIG.
[0075]
Here, the second hand drive circuit 30S supplies various drive pulses to the stepping motor 10 under the control of the control circuit 23.
The second hand drive circuit 30S includes a bridge circuit constituted by a P-channel transistor 33a and an N-channel transistor 32a connected in series, and a P-channel transistor 33b and an N-channel transistor 32b. The second hand drive circuit 30S includes rotation detection resistors 35a and 35b connected in parallel to the transistors 33a and 33b, respectively, and a sampling P-channel transistor for supplying a chopper pulse to the resistors 35a and 35b. 34a, 34b.
[0076]
As a result, the second hand drive circuit 30S applies control pulses having different polarities and pulse widths from the control circuit 23 to the gate electrodes of these transistors 32a, 32b, 33a, 33b, 34a and 34b at the respective timings. A drive pulse having a different polarity is supplied to the drive coil 11, or a detection pulse for exciting an induced voltage for detecting the rotation of the rotor 13 and detecting the magnetic field is supplied.
[0077]
[1 ・ 2 ・ 6] Control circuit
Next, the configuration of the control circuit 23 will be described with reference to FIG. 2. The functional block diagram of FIG. 2 shows the control circuit 23 and its peripheral configuration.
[0078]
Here, the control circuit 23 includes a pulse synthesis circuit 22, a mode setting unit 90, a drive control circuit 24, and the like.
First, the pulse synthesizing circuit 22 generates an oscillation circuit that oscillates a reference pulse having a stable frequency using a reference oscillation source 21 such as a crystal resonator, and a divided pulse and a reference pulse obtained by dividing the reference pulse. And a synthesizing circuit that generates pulse signals having different pulse widths and timings.
[0079]
Next, the mode setting unit 90 includes a power generation state detection unit 91, a setting value switching unit 95 that switches a setting value used for detection of the power generation state, and a charging voltage Vc (from the step-up / down circuit 49) of the large-capacitance capacitor 48. A voltage detection circuit 92 for detecting the voltage VSS after the step-up / step-down, a central control circuit 93 for controlling the time display mode according to the power generation state and controlling the boosting magnification based on the charging voltage, and a mode memory for storing the mode. Part 94.
[0080]
The power generation state detection unit 91 compares the electromotive voltage Vgen of the power generation device 40 with the set voltage value V0 to determine whether or not the power generation state is present, and the first detection circuit 97 The circuit 97 includes a second detection circuit 98 that determines a stable power generation state by comparing the time Tgen with a set time value T0, with the time during which the power generation device 40 is in a power generation state by the circuit 97 as a power generation duration time Tgen. ing.
[0081]
The power generation state detection unit 91 determines that the power generation unit A is in the power generation state when both conditions of the first detection circuit 97 and the second detection circuit 98 are satisfied. Here, the set voltage value V0 is a negative voltage with Vdd (= GND) as a reference, and indicates a potential difference from Vdd.
[0082]
Here, the set voltage value V0 used in the first detection circuit 97 is controlled by the set value switching unit 95. When the set value switching unit 95 is switched from the display mode to the power saving mode, the first voltage value V0 is changed. The set voltage value V0 used for the first detection circuit 97 is changed. That is, in this example, the set voltage value Va is set in the display mode, and the set voltage value Vb is set in the power saving mode, and this relationship is set to Va <Vb. Therefore, large power generation is required to switch from the power saving mode to the display mode. Note that the set time value T0 used in the second detection circuit 98 may be switched by the set value switching unit 95.
[0083]
The central control circuit 93 includes a non-power generation time measuring circuit 99 that measures a non-power generation time Tn in which power generation is not detected by the detection circuits 97 and 98.
[0084]
On the other hand, in the return from the power saving mode to the display mode, the power generation state detection unit 91 detects that the power generation unit A is in the power generation state, and the charging voltage Vc of the large capacity capacitor 48 returns from the power saving mode to the display mode. It is executed when the condition that there is enough electric energy necessary to do is satisfied.
[0085]
In this case, when the limiter circuit LM operates in the power saving mode and is in the on (closed) state, the power generation unit A is short-circuited, and the power generation state detection unit 91 is in a state where the power generation unit A is in the power generation state. However, it becomes impossible to detect it, and it becomes impossible to shift from the power saving mode to the display mode.
Therefore, in the present embodiment, when in the power saving mode, regardless of the power generation state of the power generation unit A, the limiter circuit LM is turned off (opened), and the power generation state detection unit 91 Can be reliably detected.
[0086]
In addition, since the power supply unit B of this embodiment includes the step-up / down circuit 49, as described above, the step-up / down voltage Vss obtained by boosting the charge voltage Vc by the step-up / down circuit 49, even when the charge voltage Vc is low to some extent. As a result, the hand movement mechanisms CS and CHM can be driven.
On the other hand, even if the charging voltage Vc is somewhat high and higher than the driving voltage of the hand movement mechanism CS, CHM, the hand movement mechanism CS, CHM is driven by the step-up / down voltage Vss obtained by stepping down the charging voltage Vc by the step-up / down circuit 49. Is possible.
The central control circuit 93 determines the step-up / step-down magnification based on the charging voltage Vc detected by the voltage detection circuit 92 and controls the step-up / down circuit 49.
[0087]
However, if the charging voltage Vc is too low, a voltage that can operate the hand movement mechanisms CS and CHM cannot be obtained even if the charging voltage is increased. In such a case, when the mode is shifted from the power saving mode to the display mode, accurate time display cannot be performed and wasteful power is consumed.
Therefore, by comparing the charging voltage Vc with a predetermined set voltage value Vb, it is determined whether or not the charging voltage Vc is sufficiently charged, and this is used as a condition for shifting from the power saving mode to the display mode. Good.
[0088]
The operation mode set in this way is stored in the mode storage unit 94, and the information is supplied to the drive control circuit 24, the time information storage unit 96, and the set value switching unit 95.
[0089]
Here, in the drive control circuit 24, for example, when the operation mode of the electronic timepiece 1 is switched from the display mode to the power saving mode by operating the external input device 100, the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM are operated. The supply of the control signal is stopped, and the operations of the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM are stopped. Thereby, the motors 10 and 60 do not rotate, and the time display is stopped.
[0090]
Next, the drive control circuit 24 generates a drive pulse corresponding to the mode based on the various pulses output from the pulse synthesis circuit 22. First, in the power saving mode, the supply of drive pulses is stopped. Further, the drive control circuit 24 has a current time return function for returning the redisplayed time display to the current time immediately after switching from the means power saving mode to the display mode. That is, by supplying a fast feed pulse with a short pulse interval as a drive pulse to the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM, the hand movement is advanced and the current time is quickly returned.
[0091]
Next, after the supply of the fast-forward pulse is completed, a drive pulse with a normal pulse interval is supplied to the second hand drive circuit 30S and the hour / minute hand drive circuit 30HM.
[0092]
On the other hand, 101 is a second counter circuit, and the second counter circuit 101 is configured as a 60 second counter by a second position counter 102, a time counter 103, and a coincidence detection circuit 104 connected to the output side of the counters 102 and 103. Has been.
[0093]
Here, a pulse signal linked to the second hand drive signal is input to the second position counter 102, and when the display control mode is forcibly shifted from the display mode to the power saving mode by, for example, an operation of the external operation device 100, the drive control circuit 24 greatly increases. A fast-forward pulse corresponding to the charging voltage Vc of the capacitor 48 is output, the second hand 55 is rotated via the second motor 10, and the remaining energy is displayed by the second hand 55. Then, when the output of the drive signal is stopped, the second hand is stopped and the power saving mode is entered. In addition, since the second hand drive signal is not input during the power saving mode, the second position counter 102 is not counted up, and only the time counter 103 is counted up. (Faster than 1 Hz) is input, and the second position counter 102 is counted up to the same value as the value of the time counter 103. In the coincidence detection circuit 104, when the value of the second position counter 102 and the value of the time counter 103 become the same value, fast-forwarding is stopped and the normal display mode is entered.
[0094]
Reference numeral 111 denotes an hour / minute counter circuit, and the hour / minute counter circuit 111 is connected to the output side of the hour / minute position counter 112, the time counter 113, and the counters 112 and 113 in substantially the same manner as the second counter circuit 101. When the minute hand 76 is operated for one minute by the detection circuit 114, it is configured as a 1440 (24 × 60) counter. When the minute hand 76 is operated for 20 seconds, it counts 3 times per minute, so 4320 (24 × 60 × 3) is counted.
[0095]
[1 ・ 2 ・ 7] Voltage detection circuit
Next, the configuration and operation of the voltage detection circuit 92 will be described with reference to FIGS.
[0096]
<1, 2, 7, 1> Configuration of voltage detection circuit
First, the configuration of the voltage detection circuit 92 will be described with reference to FIG.
The voltage detection circuit 92 divides the charging voltage Vc of the large-capacitance capacitor 48 to generate a detection voltage Vc ′ that is proportional to the charging voltage Vc, a reference power supply 92B that generates the reference voltage Vref, and a detection voltage A comparator 92C that compares Vc 'with the reference voltage Vref and outputs the original limiter signal SLIM0, and a latch circuit 92D that latches and holds the original limiter signal SLIM0 at a timing corresponding to the sampling signal SS3 and outputs it as a limiter signal SLIM1. A switch SW1 for supplying power to the reference power supply 92B based on the sampling signal SS1, a switch SW2 for supplying power to the comparator 92C based on the sampling signal SS2, and a large capacity voltage dividing circuit 92A based on the sampling signal SS3. And a switch SW3 connected to the capacitor 48.
[0097]
In this case, the sampling signal SS1, the sampling signal SS2, and the sampling signal SS3 are changed from the "H" level to the "L" level, that is, when the switch SW1, the switch SW2, and the switch SW3 are turned on. → Sampling signal SS3.
[0098]
Accordingly, power is supplied to the reference power supply 92B that takes the most time to become stable, then power is supplied to the comparator 92C, and after the operations of the reference voltage Vref and the comparator 92C are stabilized, the voltage dividing circuit 92A is connected. The original limiter signal SLIM0 is taken in by the latch circuit 92D.
[0099]
On the other hand, the voltage dividing circuit 92A is connected to resistors 92A1, 92A2, 92A3, and 92A4 having a resistance value R connected in series, an N-channel transistor 92A5 connected to both ends of the resistor 92A3, and both ends of the resistor 92A4. N-channel transistor 92A6.
[0100]
In this voltage dividing circuit 92A, since the resistors 92A1 to 92A4 are voltage dividing resistors, the detection voltage Vc 'with the charging voltage Vc being 1/4 is taken out by the resistor 92A1. When the charging amount of the charging voltage Vc becomes low, the detection voltage Vc ′ taken out by the resistor 92A1 is set to 1/3, 1/1 / of the charging voltage Vc by appropriately closing the transistors 92A5 and 92A6. 2. Thereby, the state of charge of the large-capacity capacitor 48 is displayed as full charge, 3/4 charge, and 1/2 charge. Signals for various remaining amount display modes are obtained by appropriately selecting the number of voltage dividing resistors and the resistance value.
[0101]
<1, 2, 7, 2> Operation of voltage detection circuit
Next, the operation will be described with reference to the process flowchart of FIG. 10 and the timing chart of FIG. Actually, the transition timing is shifted in the order of sampling signal SS1 → sampling signal SS2 → sampling signal SS3, but in FIG. 11, the transition timings of sampling signals SS1, SS2, and SS3 are shown for the sake of simplicity of explanation. Are almost the same timing.
[0102]
First, it is determined whether or not the elapsed time T from the previous sampling timing is equal to or longer than the sampling period Tsp (step S1).
[0103]
If it is determined in step S1 that the elapsed time T from the previous sampling timing is less than the sampling period Tsp (step S1; No), a standby state is entered, and the processing in step S1 is repeated.
[0104]
If the elapsed time T from the previous sampling timing is equal to or longer than the sampling period Tsp (step S1; Yes) in step S1, the sampling signal SS1, sampling is performed as shown at times t1, t3, and t4 in FIG. The signal SS2 and the sampling signal SS3 are sequentially shifted from the "H" level to the "L" level, that is, the switch SW1, the switch SW2, and the switch SW3 are sequentially turned on to supply power to the reference power supply 92B, and then to the comparator 92C. After power is supplied and the operation of the reference voltage Vref and the comparator 92C is stabilized, the voltage dividing circuit 92A is connected, and the comparator 92C determines whether or not the detected voltage Vc ′ exceeds the reference voltage Vref (step) S2).
[0105]
When the detection voltage Vc ′ exceeds the reference voltage Vref and the original limiter signal SLIM0 has transitioned to the “H” level as shown in time t2 to time t5 in FIG. S2; Yes) As shown at times t3 and t4 in FIG. 11, the "H" level original limiter signal SLIM0 is taken into the latch circuit 92D, and the limiter signal SLIM1 = "H" level is set (step S3).
[0106]
On the other hand, in the determination in step S2, as shown at time t1 to time t2 or time t5 in FIG. 11, the detection voltage Vc 'becomes less than the reference voltage Vref, and the original limiter signal SLIM0 is changed to the "L" level. In this case (step S2; No), as shown at times t1 and t6 in FIG. 11, the "L" level original limiter signal SLIM0 is taken into the latch circuit 92D, and the limiter signal SLIM1 = "L" level (step S1). S4), the process again proceeds to step S1, and thereafter the same process is repeated.
[0107]
As described above, by intermittently performing the operation of the voltage detection circuit 92 based on the sampling signal, it is possible to further reduce power consumption accompanying detection.
[0108]
[1, 2, 8] Magnification setting operation by central control circuit
<1, 2, 8, 1> Relationship between charging voltage and buck-boost circuit magnification
First, the relationship between the charging voltage Vc of the large-capacitance capacitor 48 and the magnification of the step-up / down circuit 49 will be described with reference to FIG.
For convenience of explanation, in the initial state, it is assumed that the power generation state detection circuit 91 is in the operating state, the limiter circuit LM is in the non-operating state, and the step-up / down circuit 49 is in the non-operating state. In this initial state, the charging voltage Vc of the large-capacity capacitor 48 is, for example, less than 0.45 [V], and the minimum voltage for driving the hand movement mechanisms CS and CHM is set to less than 1.2 [V]. Has been.
[0109]
(1) When the charging voltage Vc is in the range of 0.0 to 0.62 [V] (x3 range)
When the charging voltage Vc of the large-capacitance capacitor 48 is less than 0.45 [V], the step-up / step-down circuit 49 is inactive and the charging voltage Vc detected by the voltage detection circuit 92 is also 0.45 [V]. Therefore, the hand movement mechanisms CS and CHM remain in the non-driven state.
When the charging voltage Vc of the large-capacitance capacitor 48 exceeds 0.45 [V], the central control circuit 93 outputs a command signal for causing the step-up / step-down circuit 49 to perform triple boosting. As a result, the step-up / step-down circuit 49 performs a triple boosting operation, and this triple boosting is continued until the charging voltage Vc reaches 0.62 [V].
As a result, the voltage Vss after step-up / step-down becomes 1.35 [V] or more, and the hand movement mechanisms Cs and CHM are in a driving state.
[0110]
In this case, depending on the power generation state, for example, when the electronic timepiece 1 is swung suddenly, the voltage may suddenly rise and exceed the rated voltage, so that the operation is shifted to the triple boosting operation. If the step-up / step-down magnification is controlled according to the power generation state, such as double or 1.5 times boosting, more stable operating voltage can be supplied. The same applies to the following cases.
[0111]
(2) When the charging voltage Vc is in the range of 0.62 [V] to 0.83 [V] (x2 range)
When the charging voltage Vc of the large-capacitance capacitor 48 exceeds 0.62 [V], the central control circuit 93 outputs a command signal for causing the step-up / step-down circuit 49 to perform double boosting. As a result, the step-up / step-down circuit 49 performs a double boosting operation, and this double boosting is continued until the charging voltage Vc reaches 0.83 [V].
As a result, the voltage Vss after the step-up / step-down becomes 1.24 [V] or higher, and the hand movement mechanisms CS and CHM are maintained in the driving state as usual.
[0112]
(3) When in the range of 0.83 [V] to 1.23 [V] (x1.5 range)
When the charging voltage Vc of the large-capacitance capacitor 48 exceeds 0.83 [V], the central control circuit 93 outputs a command signal for causing the step-up / step-down circuit 49 to boost the voltage 1.5 times. As a result, the step-up / step-down circuit 49 performs a 1.5-fold voltage boosting operation, and this 1.5-fold voltage boosting operation is continued until the charging voltage Vc reaches 1.23 [V].
As a result, the voltage Vss after the step-up / step-down becomes 1.24 [V] or higher, and the hand movement mechanisms CS and CHM are maintained in the driving state as usual.
[0113]
(4) When it is 1.23 [V] or more (x1 range)
When the charging voltage Vc of the large-capacitance capacitor 48 exceeds 1.23 [V], the central control circuit 93 outputs a command signal for causing the step-up / step-down circuit 49 to perform a single boosting (short mode), that is, non-boosting operation. Is done. As a result, the step-up / step-down circuit 49 performs a one-time voltage boosting operation, and this one-time voltage boosting operation is continued until the charging voltage Vc becomes less than 1.23 [V].
As a result, the voltage Vss after the step-up / step-down becomes 1.24 [V] or higher, and the hand movement mechanisms CS and CHM are maintained as usual.
Furthermore, when the charging voltage Vc of the large-capacitance capacitor 48 exceeds 2.5 [V], the limiter circuit LM is turned on.
[0114]
In the characteristic diagram of FIG. 12, the magnification ranges x3, x2, x1.5, and x1 are different when the charging voltage Vc rises and falls.
Thus, in this embodiment, since the magnification of the step-up / step-down circuit 49 is set in the central control circuit 93 based on the charging voltage Vc detected by the voltage detection circuit 92, the voltage detection circuit 92 can also be used. The configuration can be simplified.
[0115]
In addition, a remaining amount display mode to be described later can also be set by a command signal for controlling the step-up / down circuit 49. For example, when the limiter circuit LM is activated, the full charge state is 1/3, and the voltage is 2/3. If the charging state is 1.5 times boosted, it can be set to 1/2 state.
[0116]
[1, 2, 9] Specific example of remaining amount display
FIG. 13 illustrates how the remaining amount of the charging voltage Vc of the large-capacitance capacitor 48 is displayed. In the present embodiment, the dial 80 and the second hand that is rotatably arranged on the dial 80 using the stepping motor 10 are used. 55 (the minute hand 76 and the hour hand 77 are not shown).
[0117]
In this example, when the charging voltage Vc of the large-capacitance capacitor 48 is in the full state, the remaining amount display mode is rotated by 30 seconds with respect to the current time position (for example, 0 second position) of the second hand 55 ( 13 (a)), when the charging voltage Vc is 2/3 of the full charge, the second hand 55 is rotated for 20 seconds with reference to the current time position (FIG. 13 (b)). The amount of energy is displayed.
[0118]
[1-3] Operation of the first embodiment
Based on FIG. 14, an operation process of the electronic timepiece 1 according to the present embodiment will be described.
[0119]
First, the control circuit 23 determines whether or not it is in the power saving mode (step S11). If it is determined in step S11 that the electronic timepiece 1 is in the power saving operation mode (step S11; YES), the process proceeds to step S16 described later.
[0120]
On the other hand, if it is not in the power saving mode in the determination of step S11, that is, in the display mode (step S11; NO), the user is forced to shift from the display mode to the power saving mode. It is determined whether or not the crown or button has been operated (step S12).
If it is determined in step S12 that the user does not operate the external input device 100 (step S12; NO), the process proceeds to step S22 to display the time.
[0121]
On the other hand, in the determination of step S12, when an operation by the user is performed (step S12; YES), the charging voltage Vc is detected from the voltage detection circuit 92 in step S13, and the second hand 55 is set in step S14 as described above. A display corresponding to the charging voltage Vc (for example, (a) in FIG. 13) is fast-forwarded by a predetermined amount from the current position, and the position of the second hand 55 is counted up by the second position counter 102 (step S15). Then, the mode is switched to the power saving mode (step S16).
[0122]
Further, in step S17, time information corresponding to the elapsed time of the power saving mode is counted up by the time counters 103 and 113 in order to perform time return processing (steps S19 to S21) described later, and the power generation state detection unit 91 It is determined whether or not the power generation device 40 has started power generation (step S18).
If it is determined in step S18 that there is no power generation (step S18; NO), the process in step S17 is repeated.
[0123]
If it is determined in step S18 that power generation has been started (step S18; YES), the display returns from the power saving mode to the display mode. In this case, first, the hour hand 77, the minute hand 76, and the second hand 55 are fast-forwarded (step S18), the position of the second hand 55 is counted up by the second position counter 102 (step S19), and the counter of the second position counter 102 is further counted at step S21. The process of step S20 is repeated until the value matches the value of the time counter 103. Thereby, the second hand 55 is returned to the current time by fast-forwarding. The hands 55, 76 and 77 are also driven as usual to display the time (step S22).
In this process, only the second hand 55 has been described, but the same applies to the hour hand 77 and the minute hand 76.
[0124]
[1/4] Effects of the first embodiment
As described above, in the electronic timepiece 1 according to the present embodiment, when the user forcibly switches the operation mode of the electronic timepiece 1 from the display mode to the power saving mode, the large-capacitance capacitor 48 when the user switches to the power saving mode. Since the charging voltage Vc is displayed by the movement of the second hand 55, the user can know the remaining energy of the large-capacitance capacitor 48 by the rotation angle of the second hand 55, and how much the electronic timepiece 1 is. It is possible to grasp whether the power saving mode can be maintained during the period. As a result, the user can eliminate the anxiety that the electronic timepiece 1 cannot be restarted immediately when the operation mode of the electronic timepiece 1 is switched from the power saving mode to the display mode due to the lack of the charging voltage Vc.
[0125]
Accordingly, by grasping the amount of the charging voltage Vc stored in the large-capacitance capacitor 48, the user can charge before the charging voltage Vc of the large-capacity capacitor 48 becomes low, and display from the power saving mode. Even when the mode is switched to the mode, the electronic timepiece 1 can be restarted quickly, and if the electronic timepiece 1 is out of order, it is possible to prevent an early match point.
[0126]
[2] Second embodiment
The present embodiment will be described with reference to FIGS. 15 and 16. The feature of the present embodiment is that the second hand is fixed at a position corresponding to the charging voltage Vc during the power saving mode, and the remaining energy is displayed. The charging voltage Vc is always monitored and displayed. In the present embodiment, the same components as those in the first embodiment described above are denoted by the same reference numerals, and the description thereof is omitted.
[0127]
[2.1] Specific example of remaining amount display
FIG. 15 illustrates how the remaining amount of the charging voltage Vc of the large-capacitance capacitor 48 is displayed. In this embodiment, the dial 80 and the second hand that is rotatably arranged on the dial 80 using the stepping motor 10 are used. 55 (the minute hand 76 and the hour hand 77 are not shown).
[0128]
In this embodiment, when the charge voltage Vc of the large-capacitance capacitor 48 is full, the second hand 55 is fixed at the 30-second position (FIG. 15A), and the charge voltage Vc is full. When the charging time is 2/3, the second hand 55 is fixed at the 20-second position (FIG. 15B), and the energy amount of the large-capacitance capacitor 48 is displayed.
[0129]
[2.2] Operation of the second embodiment
Based on FIG. 16, an operation process of the electronic timepiece 1 according to the present embodiment is shown.
[0130]
First, the control circuit 23 determines whether or not it is in the power saving mode (step S11). If it is determined in step S31 that the electronic timepiece 1 is in the power saving operation mode (step S31; YES), the process proceeds to step S36 described later.
[0131]
On the other hand, if it is not in the power saving mode in the determination in step S31, that is, if it is in the display mode (step S31; NO), the user is forced to shift the external input device 100 from the display mode to the power saving mode. It is determined whether or not an operation has been performed (step S32).
If it is determined in step S32 that the user does not operate the external input device 100 (step S32; NO), the process proceeds to step S43 to display the time.
[0132]
On the other hand, in the determination of step S32, when an operation by the user is performed (step S32; YES), the charging voltage Vc is detected from the voltage detection circuit 92 in step S33, and the second hand 55 is set in step S34 as described above. The display is rotated to a position corresponding to the charging voltage Vc (for example, (a) in FIG. 15), and the position of the second hand 55 is counted up by the second position counter 102 (step S35). Then, the mode is switched to the power saving mode (step S36).
[0133]
In step S37, time information corresponding to the elapsed time in the power saving mode is counted up by the time counters 103 and 113 in order to perform time recovery processing (steps S40 to S43) described later. Further, in step S38, the charging voltage Vc is detected again to determine whether or not the charging voltage Vc has changed. If not (step S38; NO), the process proceeds to step S39, where the power generation state detection unit It is determined by 91 whether or not the power generation device 40 has started power generation.
If it is determined in step S39 that there is no power generation (step S39; NO), the processes in steps S37 and S38 are repeated.
[0134]
If it is determined in step S39 that power generation has started (step S39; YES), the display returns from the power saving mode to the display mode. In this case, first, the hour hand 77, the minute hand 76, and the second hand 55 are fast-forwarded (step S40), the position of the second hand 55 is counted up by the second position counter 102 (step S41), and the counter of the second position counter 102 is further counted in step S42. The processing in step S41 is repeated until the value and the value of the time counter 103 are located. Thereby, the second hand 55 is returned to the current time by fast-forwarding. The hands 55, 76 and 77 are also driven as usual to display the time (step S43).
In this process, only the second hand 55 has been described, but the same applies to the hour hand 77 and the minute hand 76.
[0135]
On the other hand, if the charging voltage Vc of the large-capacitance capacitor 48 has changed in the determination in step S38 (step S38; YES), the second hand 55 is rotated to display an indication corresponding to the charging voltage Vc (for example, the charging voltage Vc is If 2/3 of the full charge is reached, (b) of FIG. 15 is performed (step S44). Further, the second position counter 102 is counted down by the counter corresponding to the position of the second hand 55 at this time. In step S37, the process is returned.
[0136]
As described above, in the present embodiment, when the user forcibly switches the operation mode from the display mode to the power saving mode, and when the charging voltage Vc changes during the power saving mode, the position of the large capacity capacitor 48 depends on the position of the second hand 55. The charging voltage Vc can be displayed.
[0137]
[2.3] Effects of the second embodiment
As described above, in the electronic timepiece 1 according to the present embodiment, when the user forcibly switches the operation mode of the electronic timepiece 1 from the display mode to the power saving mode, the large-capacitance capacitor 48 when the user switches to the power saving mode. Since the charging voltage Vc is displayed by the position of the second hand 55, the user can know the remaining energy of the large-capacitance capacitor 48 by the position of the second hand 55, and how long the electronic timepiece 1 is. It is possible to grasp whether the power saving mode can be maintained. As a result, the user can eliminate the anxiety that the electronic timepiece 1 cannot be restarted immediately when the operation mode of the electronic timepiece 1 is switched from the power saving mode to the display mode due to the lack of the charging voltage Vc.
[0138]
Further, in the electronic timepiece 1 according to the present embodiment, even in the power saving mode, the voltage detection circuit 92 appropriately monitors the charging voltage Vc of the large-capacitance capacitor 48, and when the charging voltage Vc is reduced to a preset ratio. The second hand 55 is rotated to a preset position to display the charging state of the charging voltage Vc. As a result, the user can grasp how long the electronic timepiece 1 can be left.
[0139]
Accordingly, by grasping the amount of the charging voltage Vc stored in the large-capacitance capacitor 48, the user can charge before the charging voltage Vc of the large-capacity capacitor 48 becomes low, and display from the power saving mode. Even when the mode is switched to the mode, the electronic timepiece 1 can be restarted quickly, and if the electronic timepiece 1 is out of order, it is possible to prevent an early match point.
[0140]
[3] Modification of embodiment
[3.1] First modification
In each of the embodiments, the charging voltage Vc of the large-capacitance capacitor 48 is displayed using the second hand 55. However, the present invention is not limited to this, and as shown in FIG. The date may be displayed using the date display function 110 using the plate 111. For example, the date is “10” when the large-capacitance capacitor 48 is in a fully charged state, and “5” when the large capacity capacitor 48 is in a 1/2 charged state. And so on. Thereby, the user can recognize that it is a power saving mode with the state in which the hands 55, 76, and 77 are stopped, and can grasp the state of charge by the number of the date.
In addition, when the number plate 111 using a color / font different from the date number is prepared and the charging voltage Vc is displayed, it is possible to display the date voltage by using this number.
[0141]
[3.2] Second modification
In the embodiment, the case where the user forcibly switches the operation mode of the electronic timepiece 1 from the display mode to the power saving mode by operating the external input device 100 has been described, but the present invention is not limited to this, and the power generation state detection unit 91 and the non-power generation state measurement circuit 99 may measure the time during which power generation is stopped, and when this time exceeds a predetermined time, the display mode may be automatically switched to the power saving mode. In addition, the user can check the charging voltage Vc regardless of the operation mode of the electronic timepiece 1.
[0142]
[3.3] Third modification
Further, the electronic timepiece 1 is provided with a portable state detection circuit constituted by an acceleration sensor, a heat detection sensor, etc., and the portable state detection circuit detects that it is in a non-portable state and measures the non-portable time at this time. Then, the non-power generation state may be monitored indirectly. Even in this case, the operation mode of the electronic timepiece 1 may be switched from the display mode to the power saving mode at this time when the time for maintaining the non-portable state has elapsed for a predetermined time. . On the other hand, when switching from the power saving mode to the display mode, it may be performed when the electronic timepiece 1 is switched from the non-portable state to the portable state by the portable state detection circuit.
[0143]
[3.4] Fourth modification
In the above embodiment, the electronic timepiece 1 that displays the hour, minute, and second with two motors is described as an example, but three or more motors (second hand, minute hand, hour hand, calendar, chronograph, etc. are individually controlled) The present invention can also be applied to an electronic timepiece having a motor.
[0144]
[3.5] Fifth modification
In the above embodiment, the charging voltage Vc of the large-capacity capacitor 48 in the power saving mode is displayed by the second hand 55, but the present invention is not limited to this, and the relative position between the second hand 55 and the minute hand 76, the second hand 55 and the hour hand. The charging voltage Vc may be displayed by a relative position with respect to 77 or a relative position between the minute hand 76 and the hour hand 77.
Further, dedicated display means may be provided separately from the hands 55, 76, 77 for displaying the clock.
[0145]
[3.6] Sixth modification
In the above embodiment, an electromagnetic power generation device that transmits the rotational motion of the rotary weight 45 to the rotor 43 and generates the electromotive force Vgen in the output coil 44 by the rotation of the rotor 43 is adopted as the power generation device 40. The present invention is not limited to this. For example, a power generation device that generates a rotational motion by the restoring force of the mainspring (corresponding to external energy) and generates an electromotive force by the rotational motion, or vibration generated externally or by self-excitation. Alternatively, a power generation device that generates electric power by a piezoelectric effect by applying displacement (corresponding to external energy) to the piezoelectric body may be used.
[0146]
Further, the power generation device may generate electric power by photoelectric conversion using light energy such as sunlight (corresponding to external energy).
[0147]
Furthermore, it may be a power generation device that generates electric power by thermoelectric power generation by a temperature difference (thermal energy; corresponding to external energy) between a certain part and another part.
[0148]
It is also possible to use an electromagnetic induction power generation apparatus that receives floating electromagnetic waves such as broadcasting and communication radio waves and uses the energy (corresponding to external energy).
[0149]
[3.7] Seventh modification
In the above-described embodiment, the reference potential (GND) is set to Vdd (high potential side), but it is needless to say that the reference potential (GND) may be set to Vss (low potential side).
[0150]
[3.8] Eighth Modification
In the above embodiment, a secondary battery that stores the power generated by the power generator, or a rechargeable power storage device such as a capacitor is used as the power source. However, a primary battery may be used, and a rechargeable power storage. An apparatus and a primary battery may be used in combination, or a power generation apparatus and a primary battery may be used in combination.
[0151]
【The invention's effect】
According to the present invention, when the operation mode of the driven means is automatically switched from the driving mode to the power saving mode by the external input means, the remaining energy level of the power source means is displayed by the remaining energy level display means. Therefore, the user can grasp the remaining energy level. For example, when in the power saving mode, it is possible to know how long the power saving mode state can be maintained, and to eliminate the anxiety when leaving the electronic timepiece. Then, the user can quickly restart the electronic timepiece by switching the electronic timepiece from the power saving mode to the drive mode while the remaining energy is sufficient.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an electronic timepiece according to a first embodiment of the invention.
FIG. 2 is a functional block diagram showing a control circuit and its peripheral configuration according to the embodiment.
FIG. 3 is a circuit configuration diagram showing a step-up / down circuit.
FIG. 4 is an operation explanatory diagram of a step-up / down circuit.
FIG. 5 is an equivalent circuit diagram of a buck-boost circuit at the time of triple boosting.
FIG. 6 is an equivalent circuit diagram of a step-up / step-down circuit at the time of double boosting.
FIG. 7 is an equivalent circuit diagram of the step-up / step-down circuit at the time of 1.5 times boosting.
FIG. 8 is an equivalent circuit diagram of a step-up / step-down circuit in direct connection (during 1-time boosting).
FIG. 9 is a schematic configuration diagram of a voltage detection circuit.
FIG. 10 is a flowchart showing processing of a voltage detection circuit.
FIG. 11 is a timing chart showing the operation of the voltage detection circuit.
FIG. 12 is a characteristic diagram showing the relationship between the charging voltage of the buck-boost circuit and the buck-boost voltage.
FIG. 13 is a specific example showing a remaining amount display mode in which a second hand is rotated to display a charging voltage Vc of a large-capacity capacitor.
FIG. 14 is a flowchart showing the operation of the first embodiment.
FIG. 15 is a specific example showing a remaining amount display mobile that displays a charging voltage Vc of a large-capacitance capacitor according to the second hand position according to the second embodiment.
FIG. 16 is a flowchart showing the operation of the second embodiment.
FIG. 17 is a specific example showing a remaining amount display mobile that displays a charging voltage Vc of a large-capacitance capacitor by a date display function according to a first modification.
[Explanation of symbols]
1 ... Electronic clock
23 ... Control circuit
24. Drive control circuit
30S ... Second hand drive circuit
30HM… Hour / minute hand drive circuit
40 ... Power generation device
45 ... Rotating weight
48 ... High-capacity secondary power supply (large-capacity capacitor)
55 ... second hand
76 ... minute hand
77 ... hour hand
90 ... Mode setting section
91 ... Power generation state detection unit
92 ... Voltage detection circuit
93 ... Central control circuit
94. Mode storage unit
100: External input device
A ... Power generation section
B ... Power supply

Claims (19)

Power supply means for supplying electrical energy;
And drive control means for operating by electrical energy supplied from said power supply means, for outputting a drive signal,
A driven means driven by receiving the drive signal,
By driving the driven means, and time display means for displaying time,
Mode switching means for switching the operation mode of the driven means between a driving mode for performing normal driving and a power saving mode based on a preset condition;
Electrical energy amount detection means for detecting the amount of electrical energy supplied from the power supply means;
When the mode switching means shifts the operation mode of the driven means from the driving mode to the power saving mode, the remaining energy display means for displaying the electric energy amount detected by the electric energy amount detecting means;
The electronic timepiece is characterized in that the electric energy detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means . Power supply means for supplying electrical energy;
And drive control means for operating by electrical energy supplied from said power supply means, for outputting a drive signal,
A driven means driven by receiving the drive signal,
By driving the driven means, and time display means for displaying time,
Mode switching means for switching the operation mode of the driven means between a driving mode for performing normal driving and a power saving mode based on a preset condition;
Electrical energy amount detection means for detecting the amount of electrical energy supplied from the power supply means;
When the mode switching means shifts the operation mode of the driven means from the driving mode to the power saving mode, the remaining energy display means for displaying the electric energy amount detected by the electric energy amount detecting means using the time display means. When,
The electronic timepiece is characterized in that the electric energy detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means . Power supply means for supplying electrical energy;
Operated by electrical energy supplied from said power supply means, and a drive control means for outputting a drive signal, and a driven means driven by receiving the drive signal,
By driving the driven means, and time display means for displaying time,
It said driven by the driven means, and a date display means for performing a date display,
Mode switching means for switching the operation mode of the driven means between a driving mode for performing normal driving and a power saving mode based on a preset condition;
Electrical energy amount detection means for detecting the amount of electrical energy supplied from the power supply means;
When the operation mode of the driven means is shifted from the driving mode to the power saving mode by the mode switching means, the remaining energy display means for displaying the electric energy amount detected by the electric energy amount detecting means using the date display means. When,
The electronic timepiece is characterized in that the electric energy detection means monitors the energy amount of the power supply means and updates the display on the remaining energy display means . Power supply means for supplying electrical energy;
And drive control means for operating by electrical energy supplied from said power supply means, for outputting a drive signal,
A driven means driven by receiving the drive signal,
It said driven by the driving means, a time display means for displaying the time,
Date display means that is driven by the driven means and displays a date;
Mode switching means for switching the operation mode of the driven means between a driving mode for performing normal driving and a power saving mode based on a preset condition;
Electrical energy amount detection means for detecting the amount of electrical energy supplied from the power supply means;
With
In the date display means, when the mode switching means shifts the operation mode of the driven means from the drive mode to the power saving mode, the electric energy amount detection means has a display mode different from the date display mode by the date display means. It has energy remaining amount display means for displaying the detected electric energy amount, and the electric energy amount detection means monitors the energy amount of the power supply means and updates the display on the energy remaining amount display means. Electronic watch. The electronic timepiece according to claim 1, 2, 3, or 4,
The power supply means includes power generation means for converting external energy into electrical energy;
Storing the electrical energy supplied from the power generation means, and comprising power storage means for supplying the electric energy toward the drive control means ,
The storage means is provided with storage capacity detection means for detecting the storage capacity of the storage means, and the remaining energy displayed by the remaining energy display means is the storage capacity detected by the storage capacity detection means. An electronic timepiece characterized by that. The electronic timepiece according to claim 1, 2, 3, or 4,
The power supply means includes power generation means for converting external energy into electrical energy;
A storage means for storing electrical energy supplied from said power generating means,
A step-up / step-down means for stepping up / down the electric energy stored in the power storage means,
The step-up / step-down means is provided with electric energy amount detection means for detecting the amount of electric energy output from the step-up / step-down means,
An electronic timepiece characterized in that the remaining energy displayed by the remaining energy display means is the amount of electrical energy detected by the electrical energy detection means. The electronic timepiece according to claim 1, 2, 3, or 4,
The power supply means includes power generation means for converting external energy into electrical energy;
Storing the electrical energy supplied from the power generation means, and comprising a power storage means for supplying the electric energy toward the drive control means,
The power generation means is provided with power generation state detection means for detecting whether or not the power generation means is in a power generation state,
The electronic timepiece is characterized in that the condition is whether or not the power generation state detection unit detects that the power generation unit is in a power generation state. The electronic timepiece according to claim 7,
The power generation state detection means includes an energy amount determination means for determining whether or not the amount of electrical energy output from the power generation means exceeds a determination energy amount,
And a power generation time determining means for determining whether or not the duration of the state in which the electric energy amount exceeds the determined energy amount by the energy amount determining means exceeds the determination time value. Electronic clock. The electronic timepiece according to claim 1, 2, 3, or 4,
The drive control means is operated by electric energy supplied from the power supply means and outputs a control signal; and
A drive circuit that operates by electrical energy supplied from the power supply means, receives a control signal output from the control circuit, and outputs a drive signal toward the driven means;
The electronic timepiece characterized in that the mode switching means supplies electric energy to the control circuit and the driving circuit in the driving mode and supplies electric energy only to the control circuit in the power saving mode. The electronic timepiece according to claim 1, 2, 3, or 4,
The carried state detecting means for detecting whether the electronic timepiece is in the carried state is provided,
The condition is that when the operating mode of the driven means is switched from the driving mode to the power saving mode, the portable state detecting means detects that the electronic timepiece is in a non-portable state, and the electronic timepiece is not portable. Whether or not the predetermined time has elapsed, and when the operating mode of the driven means is switched from the power saving mode to the driving mode, the portable time detecting means causes the electronic timepiece to An electronic timepiece characterized by whether or not it is switched to a portable state. The electronic timepiece according to claim 1, 2 or 3,
The electronic remaining time display means displays as a predetermined remaining amount display mode. The electronic timepiece according to claim 1, 2, 3, or 4,
An electronic timepiece characterized in that the drive control means includes a current time return means for performing a return operation for returning the time display to the current time when the mode switching means switches from the power saving mode to the drive mode. The electronic timepiece according to claim 4,
In the date display means, when the operation mode of the driven means is shifted from the driving mode to the power saving mode by the mode switching means,
The date display means displays the electric energy amount detected by the electric energy amount detection means using a number from 1 to 10 . A power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a driven that is driven in response to the drive signal output from the drive control unit A unit, a time display mechanism that is driven by the driven unit and displays the time, and an electric energy amount detection device that detects the amount of electric energy supplied from the power supply unit and monitors the amount of energy. An electronic timepiece control method,
A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition;
When at least the operation mode of the driven unit shifts from the driving mode to the power saving mode by the mode switching step, the electric energy amount detected and monitored by the electric energy amount detecting device is displayed and the display is updated. An energy remaining amount display step,
An electronic timepiece control method comprising: A power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a driven that is driven in response to the drive signal output from the drive control unit A unit, a time display mechanism that is driven by the driven unit and displays the time, and an electric energy amount detection device that detects the amount of electric energy supplied from the power supply unit and monitors the amount of energy. An electronic timepiece control method,
A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition;
When the operation mode of at least the driven unit shifts from the driving mode to the power saving mode by the mode switching step, the electric energy amount detected and monitored by the electric energy amount detecting device is displayed using the time display mechanism. And an energy remaining amount display step for updating the display;
An electronic timepiece control method comprising: A power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a driven that is driven in response to the drive signal output from the drive control unit A unit, a time display mechanism that is driven by the driven unit and displays a time, a date display mechanism that is driven by the driven unit and displays a date in addition to the time display by the time display mechanism, and the power source An electronic timepiece control method comprising: an electric energy amount detection device that detects an amount of electric energy supplied from a unit and monitors the amount of energy ;
A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition;
When at least the operation mode of the driven unit shifts from the drive mode to the power saving mode by the mode switching step, the electric energy amount detected and monitored by the electric energy amount detection device is displayed using the date display mechanism. And an energy remaining amount display step for updating the display;
An electronic timepiece control method comprising: A power supply unit that supplies electric energy, a drive control unit that is operated by the electric energy supplied from the power supply unit and outputs a drive signal, and a driven that is driven in response to the drive signal output from the drive control unit A unit, a time display mechanism that is driven by the driven unit and displays a time, a date display mechanism that is driven by the driven unit and displays a date by a number in addition to the time display by the time display mechanism; An electronic timepiece control method comprising: an electric energy amount detection device that detects an amount of electric energy supplied from the power supply unit and monitors the amount of energy ;
A mode switching step of switching a mode of the driven unit between a driving mode for performing normal driving and a power saving mode based on a preset condition;
When at least the operation mode of the driven unit shifts from the driving mode to the power saving mode by the mode switching step, the electric energy amount detected and monitored by the electric energy amount detecting device is used in the date display function. A display that uses a number different from the number for the date, and a process for displaying the remaining amount of energy for updating the display,
An electronic timepiece control method comprising: In the control method of the electronic timepiece according to claim 14, 15, 16, or 17 ,
The power supply unit includes a power generation device that converts external energy into electrical energy, and a power storage device that stores the electrical energy supplied from the power generation device and supplies the electrical energy.
Provided storage capacity detection step for detecting the storage capacity of the electric storage device,
The method of controlling an electronic timepiece according to claim 1, wherein the remaining amount of energy displayed in the remaining energy display step is the storage capacity detected in the storage capacity detection step. In the control method of the electronic timepiece according to claim 14, 15, 16, or 17 ,
The power supply unit includes a power generation device that converts external energy into electrical energy, a power storage device that stores the electrical energy supplied from the power generation device and supplies the electrical energy, and raises and lowers the electrical energy output from the power storage device. A step-up / step-down circuit for pressing,
The electrical energy amount detecting step of detecting an electrical energy amount output from the buck-boost circuit is provided, the energy remaining amount displayed by said energy level display process, electrical energy amount detected in the electrical energy amount detecting step A method for controlling an electronic timepiece, characterized by comprising:

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