JP2004301712A - Radio-controlled timepiece, control method for radio-controlled timepiece, and electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform miniaturization and weight reduction of a radio-controlled timepiece by means of reception electromagnetic conversion coils for carrying out both functions, a reception function for a standard radiowave and an electromagnetic conversion function for power generation, etc. <P>SOLUTION: This radio controlled timepiece is equipped with the reception electromagnetic conversion coils 612 and 622 for performing electromagnetic conversion while receiving the standard radiowave transmitted from the exterior, a received information processing part 51 for processing the standard radiowave received by the coils 612 and 622, a present time counter 531 for clocking present time, a present time correction circuit 532 for correcting the present time on the time counter 531 based on time information on the standard radiowave processed by the processing part 51, and a time display part 2 for displaying the present time clocked by the time counter 531. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a radio-controlled timepiece, a control method of the radio-controlled timepiece, and an electronic device.
[0002]
[Background Art]
2. Description of the Related Art A radio-controlled timepiece is known as a timing device that receives a radio wave including time information and corrects time. The radio-controlled timepiece includes a receiving means for receiving a standard radio wave including time information, a current time counter for counting the current time, and a time for correcting the current time of the current time counter based on the time information received by the receiving means. It is provided with a correction means, a time display unit for displaying the current time measured by the current time counter, and a drive unit for driving the time display unit.
[0003]
The receiving means includes an antenna for receiving the standard radio wave, and a receiving circuit for amplifying and decoding the standard radio wave received by the antenna. In the case where the time display unit includes a dial and a hand that rotates on the dial, the drive unit includes a stepping motor that rotates the hands of the time display unit.
In such a configuration, at a preset reception time, the standard radio wave is received by the antenna. The received standard radio wave is processed by the receiving circuit to decode the time information. The current time of the current time counter is corrected by the time correction means based on the received time information, and the hands of the time display section are driven by the stepping motor of the drive section to display the current time.
[0004]
Meanwhile, there is known a timepiece that receives a rate adjustment reference signal from the outside and adjusts the rate (for example, Patent Document 1). This timepiece includes a receiving means for receiving a rate adjustment reference signal. Patent Document 1 discloses that as a receiving means, a driving coil of a motor is used as an antenna, and a conventionally provided external magnetic field detecting circuit is used as a receiving circuit.
Also, a mobile terminal that performs external data input and the like by wireless communication is known (for example, Patent Document 2). Patent Document 2 discloses that data communication is performed through a coil of an electromagnetic motor for vibration alarm.
[0005]
[Patent Document 1]
JP-A-10-2882270
[Patent Document 2]
JP-A-2002-30073
[0006]
[Problems to be solved by the invention]
However, a radio-controlled timepiece requires an antenna and a receiving circuit for receiving a standard radio wave, in addition to the components that are naturally required to secure the timekeeping function, such as a current time counter, a time display unit, and a drive unit. I do. Then, the antenna needs to have a size corresponding to that in order to secure a sufficient receiving sensitivity. As a result, there has been a problem that the radio-controlled timepiece is larger than a conventional timepiece. Therefore, when the radio-controlled timepiece is a portable type typified by a wristwatch, it is difficult to reduce the size and to improve the design aesthetics.
[0007]
Here, Patent Document 1 discloses an example in which a coil for driving a motor is used as an antenna, and Patent Document 2 discloses an example in which wireless communication is performed using a coil of an electromagnetic motor. However, the reception by the motor drive coil is based on an electromagnetic induction effect (electromagnetic coupling), and the motor drive coil must be brought close to an external signal transmission source to such an extent that the electromagnetic coupling is constituted. There is a problem.
[0008]
Further, in Patent Document 1, although the idea of diverting the motor drive coil to the receiving antenna is disclosed, the rate is merely adjusted by the rate adjustment reference signal, and the time is adjusted by an external operation. In this regard, if a motor drive coil is used for reception, the time display will continue to be stopped.However, a radio-controlled timepiece must correct the time display automatically by receiving standard radio waves containing time information. Must. Therefore, there is a problem that the content of Patent Document 1 cannot be simply applied to a radio-controlled timepiece.
[0009]
Further, Patent Document 2 mentions the case where the portable terminal is a wristwatch, but does not mention how to display the time when the motor drive coil is used for reception or charging. There are difficulties when functioning as a watch. In the above publication, when information (for example, a standard radio wave) is received by a motor drive coil, if another electric signal (for example, a drive pulse) is applied to the motor drive coil, the signal becomes noise and cannot be received. However, no specific configuration for blocking such other signals is disclosed. In this respect, since accurate reception of the standard time signal is required for accurate time correction, there is a problem that the time correction cannot be simply applied to a radio-controlled timepiece.
[0010]
SUMMARY OF THE INVENTION An object of the present invention is to provide a radio-controlled timepiece, an electronic device, and a method of controlling the radio-controlled timepiece that solve the conventional problems and are downsized.
[0011]
[Means for Solving the Problems]
A radio-controlled timepiece according to the present invention includes: a reception electromagnetic conversion coil that performs electromagnetic conversion and receives a standard radio wave transmitted from the outside; a reception information processing unit that processes the standard radio wave received by the reception electromagnetic conversion coil; Current time clock means for measuring the time; time correction means for correcting the current time of the current time clock means based on the time information of the standard time signal processed by the reception information processing unit; and clocking by the current time clock means. And a time display unit for displaying a current time to be displayed.
[0012]
In such a configuration, when a standard radio wave is transmitted from the outside, the standard radio wave is received by the receiving electromagnetic conversion coil. Processing such as amplification and decoding is performed on the standard radio wave received by the reception electromagnetic conversion coil in the reception information processing unit, and time information is obtained. Then, the current time of the current time measuring means is corrected based on the time information acquired by the time correcting means, and the corrected current time is displayed on the time display unit.
On the other hand, the receiving electromagnetic conversion coil performs electromagnetic conversion in addition to receiving the standard radio wave. For example, an induction magnetic field is generated by electromagnetically converting an alternating current like a coil of a motor. The operation of the radio-controlled timepiece, for example, rotation of the hands, is performed by the power generated by the electromagnetic conversion. Alternatively, the receiving electromagnetic conversion coil electromagnetically converts a magnetic field variation like a coil of a generator to generate an induced voltage. Then, energy for operating the radio-controlled timepiece can be obtained using the electric power generated by the electromagnetic conversion.
[0013]
A radio-controlled timepiece needs to have a receiving function of receiving a standard radio wave and an electromagnetic conversion function for generating power and the like.Conventionally, an antenna coil and an electromagnetic conversion coil are separately provided. Was. However, by providing the receiving electromagnetic conversion coil capable of performing both functions, the number of components can be reduced as compared with the case where the antenna coil and the electromagnetic conversion coil are separately provided. The antenna coil and the electromagnetic conversion coil are very large in the timepiece, which was a factor in defining the size of the watch. The size and weight can be dramatically reduced. Therefore, for example, even when the radio-controlled timepiece is made to be a portable type such as a wristwatch, the size of the radio-controlled timepiece can be extremely reduced and aesthetically superior in design can be exhibited, and the weight can be reduced and the wearing feeling can be improved.
Further, by reducing the number of parts and downsizing, material costs, assembly costs, and the like can be significantly reduced, so that lower prices can be realized.
[0014]
In the present invention, when the standard electromagnetic wave is received by the reception electromagnetic conversion coil, the reception electromagnetic conversion coil and the reception information processing unit are electrically connected, and when the standard electromagnetic wave is not received by the reception electromagnetic conversion coil, It is preferable to include a first switch for electrically disconnecting the reception electromagnetic conversion coil from the reception information processing unit.
[0015]
In such a configuration, the first switch unit switches an electrical connection state between the reception electromagnetic conversion coil and the reception information processing unit. The reception electromagnetic conversion coil is connected to the reception information processing unit only when the reception electromagnetic conversion coil receives the standard radio wave. The standard radio wave received in a state where the reception electromagnetic conversion coil and the reception information processing unit are connected by the first switch means is processed by the reception information processing unit to obtain time information.
[0016]
The first switch disconnects the reception electromagnetic conversion coil and the reception information processing unit except when receiving the standard radio wave. Therefore, the electromagnetic conversion can be performed by the reception electromagnetic conversion coil except when the radio wave is received. That is, since the reception information processing unit is disconnected, the electromagnetic conversion is performed by the reception electromagnetic conversion coil. For example, even if the induced electromotive force is generated, the induced electromotive force does not flow into the reception information processing unit. . Therefore, even when the withstand voltage of the reception information processing unit that processes a weak radio wave is small, it is possible to prevent the reception information processing unit from being damaged or the like. In addition, since it is not necessary to forcibly increase the withstand voltage of the reception information processing unit, the sensitivity of the reception information processing unit can be increased. As a result, even if the reception sensitivity of the reception electromagnetic conversion coil is somewhat small, it is sufficient. The time information can be obtained.
[0017]
Alternatively, even when a pulse is applied to the reception electromagnetic conversion coil other than during reception, the pulse is applied only to the reception electromagnetic conversion coil without flowing to the reception information processing unit. The quantity can be controlled precisely. Therefore, for example, even when the hands are moved using the power generated by electromagnetic conversion in the reception electromagnetic conversion coil, accurate time display can be performed by accurately moving the hands.
[0018]
In the present invention, a drive control unit that applies a drive pulse to the reception electromagnetic conversion coil, and a rotor that is rotated by a magnetic field variation caused by electromagnetic conversion by the reception electromagnetic conversion coil, the time display unit, It is preferable to have a pointer that rotates on the dial by rotation of the rotor.
[0019]
In such a configuration, a fluctuating current, for example, a pulse is applied to the receiving electromagnetic conversion coil. Then, an induction magnetic field is generated by the electromagnetic conversion of the reception electromagnetic conversion coil. A rotor magnetized to two or more poles is rotated by the induction magnetic field, and the rotation of the rotor rotates the hands. Then, the time is displayed by the hands. Further, the standard electromagnetic wave is received by the reception electromagnetic conversion coil, and the time is corrected based on the received time information.
[0020]
A pointer-type timepiece that displays the time by rotating the hands requires a power source for rotating the hands, but power can be obtained by electromagnetic conversion using a reception electromagnetic conversion coil. Then, the number of parts can be reduced as compared with the case where the motor coil and the antenna coil are separately provided. As a result, the radio-controlled timepiece can be reduced in size, and the design can be improved when a small portable type such as a wristwatch is used.
Further, since the reception electromagnetic conversion coil is a stator and the rotor is a rotor, the position and the direction of the reception electromagnetic conversion coil can be always fixed. Therefore, even when the reception electromagnetic conversion coil receives the standard radio wave, it can function as an antenna for receiving a radio wave having directivity, and the reception sensitivity can be improved.
[0021]
Here, a stator for transmitting magnetic flux generated in the reception electromagnetic conversion coil and rotatably holding the rotor is provided, and the stator is provided with rotor position fixing means for fixing a stop position of the rotor in a no-load state. Preferably. According to such a configuration, when the receiving electromagnetic conversion coil receives the standard radio wave, the magnetic field does not fluctuate due to the movement of the rotor. Therefore, the standard electromagnetic wave can be accurately received by the receiving electromagnetic conversion coil without being affected by the magnetic field fluctuation from the rotor. As such a rotor position fixing means, a notch or a projection is provided in a part of the stator to generate a cogging torque.
[0022]
In the present invention, the reception electromagnetic conversion coil is electrically disconnected from the drive control unit in a state where the standard electromagnetic wave is received by the reception electromagnetic conversion coil, and the reception is performed in a state where the standard electromagnetic wave is not received by the reception electromagnetic conversion coil. It is preferable to include a second switch for electrically connecting the electromagnetic conversion coil and the drive control unit.
[0023]
According to such a configuration, at the time of receiving the standard radio wave, the drive pulse from the drive control unit to the reception electromagnetic conversion coil is cut off by the second switch means. Therefore, when the reception electromagnetic conversion coil receives the standard radio wave, it is possible to prevent the drive pulse from being superimposed on the standard radio wave. As a result, the standard radio wave can be accurately received.
[0024]
Here, it is preferable that the drive control unit stops the drive pulse in a state where the reception electromagnetic conversion coil receives a standard radio wave. According to such a configuration, it is possible to prevent the drive pulse from being superimposed on the standard radio wave and to accurately receive the standard radio wave. In addition, since driving pulses are not output wastefully, energy consumption can be reduced.
[0025]
In the present invention, there is provided a disconnection time storage unit for storing a disconnection time during which the drive control unit and the reception electromagnetic conversion coil have been electrically disconnected by the second switch unit, When the drive control unit and the reception electromagnetic conversion coil are electrically connected after a predetermined disconnection time by the switch unit, the drive pulse corresponding to the disconnection time stored in the disconnection time storage unit is received by the reception unit. It is preferable to apply the voltage to the electromagnetic conversion coil.
[0026]
In such a configuration, the disconnection time storage unit stores the time during which the drive control unit and the reception electromagnetic conversion coil were disconnected by the second switch unit when the standard radio wave was received. That is, the cutting time storage unit stores the time during which the reception electromagnetic conversion coil has stopped driving the hands. When the standard electromagnetic wave is received by the reception electromagnetic conversion coil and time information is acquired, the drive control unit and the reception electromagnetic conversion coil are connected again by the second switch. At this time, the drive control unit outputs a drive pulse for fast-forwarding or the like to recover the amount of time when the driving of the hands has been stopped, corresponding to the cutting time stored in the cutting time storage unit. Then, the pointer is fast-forwarded for the stopped time. Then, a drive pulse for further correcting the pointer position is output according to the time information acquired by receiving the standard radio wave.
[0027]
The clock function of the current clock has an accuracy of several seconds per month, and there is usually only an error of a few seconds between the time measured by the internal current time measuring means and the time information of the standard radio wave. In addition, since the driving of the hands is stopped while the standard radio wave is being received, it is certain that the stop must be fast-forwarded. Therefore, if the cutting time stored in the cutting time storage unit is first fast-forwarded at a high speed, and then the deviation in seconds is corrected by the time information of the standard radio wave, the time can be corrected quickly. it can. In addition, since it takes time to process the received standard radio wave and correct the counter value of the current time measuring means, if the pointer is quickly forwarded while processing the standard radio wave, unnecessary waiting time may occur. Time can be corrected quickly without dead time.
[0028]
In the present invention, there is provided a switch control means for controlling an open / close state of the first switch means and the second switch means, wherein the switch control means receives a predetermined unit of the time information and then receives a predetermined unit of the next time information. Before receiving the signal, the reception electromagnetic conversion coil and the reception information processing unit are electrically disconnected by the first switch means, and the drive control unit and the reception electromagnetic conversion coil are connected to the second switch means. It is preferable to conduct electricity electrically at
[0029]
Here, one unit of the time information refers to a set of data constituting each digit such as minute, hour, total day, year, etc. of the time information of the standard time signal, and the predetermined unit of the time information is minute, hour , One or more units obtained in a single receiving operation from data such as total days and years.
According to such a configuration, after the reception electromagnetic conversion coil receives the standard radio wave for a predetermined unit, the reception electromagnetic conversion coil and the reception information processing section are disconnected by the first switch means. At the same time, the drive control unit and the receiving electromagnetic conversion coil are conducted by the second switch means. Then, in this state, a drive pulse is applied from the drive control unit to the reception electromagnetic conversion coil, and the hands are moved by the electromagnetic conversion of the reception electromagnetic conversion coil. The hands indicate the time measured by the current time measuring means. Then, a predetermined unit of the next standard radio wave is received. When the time information of a predetermined number of units is received, the time is adjusted.
[0030]
Each time a predetermined unit is acquired, the drive control unit and the receiving electromagnetic conversion coil are connected, so that the movement of the hands continues even while receiving the standard radio wave. Therefore, an almost accurate current time is displayed on the time display unit. As a result, it is possible to prevent the user from erroneously recognizing the current time, thereby improving the convenience. Further, since the time displayed on the time display section is always substantially the current time, the operation of adjusting the hands to correct the pointer position in accordance with the time information of the standard time signal may be slight. Therefore, the time can be corrected in a short time and simply. As a result, the number of fast-forward pulses or the like for time correction can be reduced, and as a result, energy consumption can be reduced.
[0031]
According to the present invention, a rotor that is rotated by kinetic energy given from the outside to generate a magnetic field fluctuation, and a power storage unit that stores an induced electromotive force generated by electromagnetic conversion of the reception electromagnetic conversion coil from the magnetic field fluctuation due to the rotation of the rotor And it is preferable to have:
[0032]
According to such a configuration, two or more magnetized rotors are rotated by kinetic energy given from the outside, for example, energy input by external operation means such as a winding stem or energy generated by rotation of the rotary weight. . Then, the magnetic field fluctuates due to the rotation of the rotor. The induced electromotive force is generated from the magnetic field fluctuation by the electromagnetic conversion in the reception electromagnetic conversion coil. This induced electromotive force is stored in the power storage means and used for the operation of the radio-controlled timepiece.
Further, the standard electromagnetic wave is received by the receiving electromagnetic conversion coil, and the time is corrected based on the received time information.
[0033]
Since an induced electromotive force can be generated by the reception electromagnetic conversion coil, a radio-controlled timepiece having a built-in power generation mechanism can be provided. Therefore, the convenience can be improved without requiring maintenance such as battery replacement.
By performing electromagnetic conversion and radio wave reception by the reception electromagnetic conversion coil, the number of components can be reduced as compared with a case where a power generation coil and a radio wave reception coil are separately provided. As a result, the radio-controlled timepiece can be reduced in size, and the design can be improved when a small portable type such as a wristwatch is used.
[0034]
In the present invention, the power generation detecting means for detecting an induced electromotive force generated in the reception electromagnetic conversion coil, and the reception electromagnetic conversion coil and the reception information processing unit when the induced electromotive force is detected by the power generation detection means. A third switch for electrically disconnecting and electrically connecting the reception electromagnetic conversion coil and the reception information processing unit when the induced electromotive force is not detected by the power generation detection unit. preferable.
[0035]
According to such a configuration, when power generation is detected by the power generation detection means, the reception electromagnetic conversion coil and the reception information processing unit are disconnected by the third switch means. Therefore, since the power generated by the reception electromagnetic conversion coil does not escape to the reception information processing unit side, all the generated power can be stored in the power storage unit.
Since the reception information processing unit processes weak radio waves, the withstand voltage of the circuit may be small, and if the power generated by the reception electromagnetic conversion coil flows in, the circuit may be damaged. However, the generated power is shut off by the third switch means in front of the reception information processing unit, so that damage to the reception information processing unit can be prevented, and the withstand voltage of the reception information processing unit is forcibly increased. No need.
[0036]
In the present invention, it is preferable that two or more of the reception electromagnetic conversion coils are provided and that the coil axes of at least two or more of the reception electromagnetic conversion coils are arranged in different directions.
[0037]
According to such a configuration, since the coil axis of the receiving electromagnetic conversion coil is oriented in a different direction, it is possible to receive radio waves regardless of the orientation of the timepiece with respect to the radio wave source.
For radio waves with high directivity, the direction of the coil axis greatly affects the receiving sensitivity. However, in a portable watch such as a wristwatch, the direction of the watch at the time of receiving radio waves cannot be fixed. However, by arranging the direction of the coil axis of the receiving electromagnetic conversion coil in several directions, it is possible to receive the standard radio wave regardless of the direction of the watch itself.
[0038]
In the present invention, it is preferable that two or more reception electromagnetic conversion coils are provided, and at least two or more of the reception electromagnetic conversion coils are connected in series.
[0039]
According to such a configuration, the signal intensities received by the respective reception electromagnetic conversion coils are added in series, so that the overall reception sensitivity can be improved. In addition, since the reception strength can be increased by connecting a plurality of reception electromagnetic conversion coils arranged at different positions in series, the reception sensitivity of each reception electromagnetic conversion coil may be somewhat small.
[0040]
In the present invention, preferably, two or more of the reception electromagnetic conversion coils are provided, and at least two or more of the reception electromagnetic conversion coils are connected in parallel.
[0041]
According to such a configuration, since the signals received by the respective reception electromagnetic conversion coils are processed in parallel, the time is corrected using the standard radio wave accurately received by any of the reception electromagnetic conversion coils. be able to. Therefore, the probability that the standard radio wave can be accurately received can be improved.
[0042]
In the aspect of the invention, it is preferable that an outer case and a base frame supporting the reception electromagnetic conversion coil be provided in the outer case, and the base frame be formed of an insulating member.
[0043]
According to such a configuration, since the base frame is an insulating member, radio waves are not shielded by the base frame, and standard radio waves can interlink with the reception electromagnetic conversion coil. Therefore, the receiving sensitivity of the receiving electromagnetic conversion coil can be improved. Here, examples of the base frame include a main plate and a wheel train receiver that constitute a timepiece mechanical body (movement).
[0044]
In the present invention, an outer case and a base frame that supports a reception electromagnetic conversion coil in the outer case are provided, and the reception electromagnetic conversion coil is disposed close to an outer edge of the base frame. preferable.
[0045]
According to such a configuration, the standard radio wave that has entered the interior of the timepiece immediately interlinks with the reception electromagnetic conversion coil at the outer edge of the base frame. Therefore, the receiving sensitivity of the receiving electromagnetic conversion coil can be improved. If the receiving electromagnetic conversion coil is provided in the middle of the base frame, there is a possibility that other parts supported by the base frame, such as a train, shield radio waves and reduce the receiving sensitivity of the receiving electromagnetic conversion coil. is there. However, since the receiving electromagnetic conversion coil is arranged on the outer edge of the base frame, a large amount of interlinkage magnetic flux can be secured and the receiving sensitivity can be improved.
[0046]
In the present invention, it is preferable that a non-conductive member is disposed on an extension of a coil axis of the reception electromagnetic conversion coil.
[0047]
According to such a configuration, the magnetic field of the standard radio wave passes through the non-conductive member without being shielded and is linked to the antenna. Therefore, the flux linkage can be increased, and the receiving sensitivity of the antenna can be improved.
Here, for example, even when components such as a train wheel made of metal constituting a timepiece mechanical body (timepiece movement) are arranged on a plane including the coil axis of the reception electromagnetic conversion coil, these metal components are not used for reception electromagnetic conversion. Do not place on the extension of the coil axis of the coil. Further, when the extension of the coil axis of the reception electromagnetic conversion coil intersects the exterior case, it is preferable that the exterior case is formed of a non-conductive member at least in the extension direction of the coil axis of the reception electromagnetic conversion coil.
[0048]
The radio-controlled timepiece according to the present invention is a control method for a radio-controlled timepiece including a reception electromagnetic conversion coil for performing electromagnetic conversion and receiving a standard radio wave transmitted from the outside, wherein the standard received by the reception electromagnetic conversion coil is provided. The reception information processing step of processing the radio wave, the current time clocking step of clocking the current time, and the current time measured in the current time clocking step based on the time information of the standard radio wave processed in the reception information processing step A time correction step for correcting, a time display step for displaying the current time measured in the current time clocking step, and applying a drive pulse to the reception electromagnetic conversion coil in a state where the reception electromagnetic conversion coil does not receive a standard radio wave. A driving control step; and a cutting time storing step of storing a cutting time during which the driving pulse is not applied to the reception electromagnetic conversion coil, wherein the driving control step includes: When applying a pulse to the reception electromagnetic conversion coil after a predetermined cutting time, applying the drive pulse corresponding to the cutting time stored in the cutting time storage step to the reception electromagnetic conversion coil. .
[0049]
In such a configuration, the drive control step does not apply a drive pulse to the reception electromagnetic conversion coil when the standard electromagnetic wave is received by the reception electromagnetic conversion coil. The time when the drive pulse has not been applied to the electromagnetic conversion coil is stored. The standard radio wave received by the reception electromagnetic conversion coil is processed in a reception information processing step to obtain time information. According to the time information, the current time measured in the current time clocking step is corrected (current time correction step). Then, in the time display step, the current time is displayed. For example, in the case of performing the pointer-type time display, the hands are driven by the power obtained by the electromagnetic conversion by the reception electromagnetic conversion coil, and the time is displayed. Here, in the drive control step, a drive pulse for retrieving the part where the driving of the hands has been stopped is output by fast-forwarding or the like in accordance with the cutting time stored in the cutting time storage step. Then, the pointer is fast-forwarded for the stopped time. Then, a drive pulse for further correcting the pointer position is output according to the time information acquired by receiving the standard radio wave.
The time during which the drive pulse is not applied is counted in the cutting time storage step, and the cutting time stored in the cutting time storage unit is first fast-forwarded at a high speed in the drive control step. Therefore, time correction can be performed promptly. In addition, since the reception information processing step and the time adjustment step require a considerable amount of time, if the pointer is fast forwarded during this time, unnecessary waiting time does not occur, and dead time can be eliminated and time adjustment can be performed quickly. it can.
[0050]
A method for controlling a radio-controlled timepiece according to the present invention is a control method for a radio-controlled timepiece including a reception electromagnetic conversion coil that performs electromagnetic conversion and receives a standard radio wave transmitted from the outside. A reception information processing step of processing the received standard radio wave, a current time clocking step of measuring the current time, and the current time clocking step based on the time information of the standard radio wave processed in the reception information processing step. A time correction step for correcting the current time, a time display step for displaying the current time measured in the current time clocking step, and an electromagnetic conversion of the reception electromagnetic conversion coil generated from a magnetic field variation caused by externally applied kinetic energy. A power storage step of storing the induced electromotive force, and a power generation detection step of detecting an induced electromotive force generated in the reception electromagnetic conversion coil. Process is characterized in that the said induced electromotive force in the power generation detecting step is performed only when undetected.
[0051]
According to such a configuration, when power generation is detected in the power generation detection step, the reception information processing step is not performed. When power is generated by the reception electromagnetic conversion coil, there is a high risk that the signal is distorted due to the superposition of the magnetic field on the standard radio wave. However, since a power generation detecting step is provided and the standard radio wave is not processed during power generation, erroneous reception due to the effect of power generation can be prevented, and time information can be obtained accurately.
[0052]
The electronic device of the present invention includes a reception electromagnetic conversion coil that performs electromagnetic conversion and receives a radio wave transmitted from the outside, a reception information processing unit that processes a radio wave received by the reception electromagnetic conversion coil, A drive control unit for applying a drive pulse to the electromagnetic conversion coil.
[0053]
According to such a configuration, the wireless information received by the reception electromagnetic conversion coil is processed by the reception information processing unit to acquire the information. An operation can be performed based on the acquired information. Further, it can be operated by the power obtained by electromagnetically converting the drive pulse by the reception electromagnetic conversion coil. As described above, the reception function and the electromagnetic conversion function can be performed by the reception electromagnetic conversion coil. can do.
[0054]
The electronic device of the present invention is a reception electromagnetic conversion coil that performs electromagnetic conversion and receives a radio wave transmitted from the outside, a reception information processing unit that processes a radio wave received by the reception electromagnetic conversion coil, A rotor that is rotated by the applied kinetic energy to generate a magnetic field fluctuation; and a power storage unit that stores an induced electromotive force generated by electromagnetic conversion of the reception electromagnetic conversion coil from the magnetic field fluctuation due to the rotation of the rotor. Features.
[0055]
According to such a configuration, the wireless information received by the reception electromagnetic conversion coil is processed by the reception information processing unit to acquire the information. An operation can be performed based on the acquired information. In addition, it is possible to electromagnetically convert the magnetic field fluctuation caused by the rotation of the rotor with the reception electromagnetic conversion coil to obtain the induced power. Then, energy can be obtained by storing the induced electromotive force. As described above, the reception function and the electromagnetic conversion function can be performed by the reception electromagnetic conversion coil. can do.
[0056]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(1st Embodiment)
FIG. 1 shows a plan view of the first embodiment, and FIG. 2 shows a cross-sectional view taken along line II-II in FIG.
This radio-controlled timepiece 100 is of a wristwatch type, and includes a ring-shaped (short cylindrical shape with both end surfaces opened) outer case 1 as shown in FIGS. The outer case 1 has a cylindrical axial direction L which is the axial direction of the gear driving each hand (for example, the axial direction of the center wheel & pinion 444). ₁ Are ring-shaped with both ends open. The outer case is formed of a non-conductive member, for example, a synthetic resin or the like.
At opposite positions on the outer periphery of the outer case 1, mounting portions 11 and 12 for attaching a wristwatch band are formed. Here, as viewed from the center of the outer case 1, the direction in which one of the mounting portions 11, 12 is provided is a 12:00 direction, and the direction in which the other of the mounting portions 11, 12 is provided is a 6 o'clock direction. In FIG. 1, the upper side (toward the mounting portion 11) is the 12:00 direction, and the lower side (toward the mounting portion 12) is the 6 o'clock direction.
[0057]
A winding stem 131 as the external operating means 13 is provided so as to penetrate the trunk of the outer case 1 from about 4 o'clock. One end of the winding stem 131 is located outside the outer case 1 and a crown 132 is provided at this end. The other end of the winding stem 131 is located inside the outer case 1, and at the other end side, a cannel 133 and a mandarin 134 are provided. The knuckle 133 engages with the pinwheel 135 and pulls out the winding stem 131, whereby the pinwheel 135 moves in the axial direction of the winding stem 131 via the mandarin 134 and the kanuki 133 to correct the needle position, The vehicle 45 can be modified. A switching unit is constituted by the winding stem 131, the kanuki 133, the mandarin 134, the pinwheel 135, and the like.
Further, by the operation of the external operation means 13, a command of a forced reception start for forcibly starting a reception operation of the standard radio wave and a scheduled reception time setting for setting and inputting a scheduled time of the reception operation are performed.
[0058]
As shown in FIG. 2, a time display unit (time display means) 2 is provided on one opening surface side of the outer case 1, and the other opening surface of the outer case 1 has a back as a lid for closing the opening. A lid 3 is provided.
The time display section 2 is in the cylinder axis direction L of the outer case 1. ₁ The dial 21 includes a dial 21 having a time display surface 211 that is substantially perpendicular to the direction perpendicular to the paper surface in FIG. 1, and hands 221 and 222 that rotate on the dial 21.
The dial 21 has a substantially disk shape and has an area that closes the opening surface of the outer case 1. The dial 21 is formed of a non-conductive and non-magnetic member, and is formed of, for example, inorganic glass, plastic, or ceramic. The time display surface 211 is provided outward so as to be visible from the outside, and a number (not shown) representing time is printed in an annular shape near an outer edge on the time display surface 211.
[0059]
The hands are provided with a minute hand 221 indicating the minute and an hour hand 222 indicating the hour. The hands 221 and 222 are both formed of a metal member such as brass, aluminum, and stainless steel. The minute hand 221 and the hour hand 222 are rotated on the time display surface 211 around the substantially center of the dial 21 as a rotation axis, and the time is indicated by pointing to a number on the time display surface 211.
A windshield 23 is provided facing the dial 21 with the hands 221 and 222 therebetween. The draft shield 23 has an area for closing the opening of the outer case 1. The windshield 23 is formed of a non-conductive and non-magnetic light-transmitting member, and is formed of, for example, inorganic glass or organic glass.
[0060]
The back cover 3 is provided to face the dial 21 at a predetermined interval, and has an area for closing the opening of the outer case 1. The back cover 3 is formed of a non-conductive and non-magnetic member, and is formed of, for example, inorganic glass or ceramic.
[0061]
A movement 4 having a timekeeping function, a plastic middle frame 14 for fixing the movement 4 to the outer case 1, and power supply to the movement 4 between the dial 21 and the back cover 3 inside the outer case 1. The battery 49 is provided.
[0062]
The movement 4 includes a crystal unit 41 including a crystal unit 411, a control unit 5 having a control function, a reception drive unit 6 for receiving a standard radio wave and driving a pointer, and a power supply for the reception drive unit 6. 221 and 222, a date wheel (calendar wheel) 45 indicating the date, and the wheel train 44 in the cylinder axis direction L of the outer case 1. ₁ , And a base plate 46 and a train wheel receiver 47 as a base frame to be clamped from above.
[0063]
The crystal unit 41 includes a crystal unit 411 for a reference clock. Further, a quartz oscillator 412 for 60 kHz and a quartz oscillator 413 for 40 kHz are provided as quartz oscillators for generating a tuning signal for tuning to the frequency (60 kHz, 40 kHz) of the standard radio wave. The quartz oscillators 412 and 413 for generating a tuning signal are arranged at approximately 9 o'clock. The crystal unit 41 is disposed at approximately 7 o'clock.
[0064]
As shown in FIG. 3, the control unit 5 includes a reception information processing unit 51 that processes a standard radio wave received by the reception drive unit 6 and a reference signal generation unit that generates a clock pulse based on an oscillation pulse from the crystal unit 411. 52, a central control circuit 53 that counts the current time with a clock pulse and corrects the current time with the received time information, a drive control unit 54 that drives and controls the reception drive unit 6, and a hand position that detects a pointer position. It comprises a detection circuit 55 and a switch section 56 for switching the electrical connection state of the reception information processing section 51 and the drive control section 54 to the reception drive unit 6.
[0065]
The reception information processing unit 51 includes a reception circuit 511 that processes the standard radio wave received by the reception drive unit 6 and outputs the time information, a storage circuit 512 that stores the time information output from the reception circuit 511, and a storage circuit. A comparison circuit 513 for comparing the time information stored in 512 with the hand position detected by the hand position detection circuit 55 is provided.
[0066]
The reception circuit 511 includes an amplification circuit for amplifying the standard radio wave received by the reception drive unit 6, a filter for extracting a desired frequency component, a demodulation circuit for demodulating a signal, a decoding circuit for decoding a signal, and the like. I have. The receiving circuit 511 uses a tuning signal generated based on the oscillations of the tuning quartz oscillators 412 and 413 to tune to the higher reception intensity of the standard radio waves of 60 kHz and 40 kHz to process the signal. .
The storage circuit 512 temporarily stores the time information decoded by the reception circuit 511, and compares the stored plurality of time information to determine the success or failure of the reception. In addition, the storage circuit 512 counts up the stored time information by a clock pulse from the reference signal generation unit 52.
The comparison circuit 513 obtains the display time displayed on the time display unit from the hand position detected by the hand position detection circuit 55. Then, the comparison circuit 513 compares the display time displayed on the time display section with the time information based on the standard radio wave stored in the storage circuit 512, and outputs the comparison result to the central control circuit 53.
[0067]
The reference signal generation unit 52 includes an oscillation circuit 521 that uses a clocking crystal oscillator as a control element, and a frequency division circuit 522 that divides an oscillation pulse from the oscillation circuit 521 to generate a reference clock pulse. ing. The reference clock pulse from the frequency dividing circuit 522 is output to the central control circuit 53.
[0068]
The central control circuit 53 includes a current time counter 531 as current time counting means for counting the current time based on the reference clock pulse, and a time as time correcting means for correcting the count value of the current time counter 531 according to the received time information. A correction circuit 532 and a reception control circuit 533 for storing a reception schedule for receiving the standard radio wave and controlling the reception operation are provided.
As a reception schedule set in the reception control circuit 533, for example, a setting for performing a reception operation from 2:00 am to 2:03 am is performed. Further, forcible reception of the standard radio wave is instructed to the reception control circuit 533 by an input operation by the external operation means 13.
The reception control circuit 533 instructs the reception circuit 511 to start reception when the reception circuit 511 starts the reception processing of the standard radio wave. At the same time, a reception start command is output to the drive control unit and the switch unit 56 at the same time. When terminating the reception processing of the standard radio wave to the reception circuit 511, the reception circuit 511 is instructed to stop the reception, and the drive control unit 54 and the switch unit 56 are also output the reception stop command.
[0069]
The drive control unit 54 includes a driver 541 that applies a drive pulse to the reception drive unit 6 and a driver control unit 542 that controls the operation of the driver 541 according to a command from the reception control circuit 533.
The driver 541 includes a minute hand driver (not shown) that outputs a drive pulse for driving the minute hand, and an hour hand driver (not shown) that outputs a drive pulse for driving the hour hand. The driver 541 applies a drive pulse to the reception drive unit 6 for matching the current time counted by the current time counter 531 with the display time detected by the hand position detection circuit 55.
When receiving a command to start receiving the standard radio wave from the reception control circuit 533, the driver control unit 542 causes the driver 541 to stop outputting the driving pulse. When receiving a command to stop receiving the standard radio wave from the reception control circuit 533, the driver control unit 542 commands the driver 541 to output a driving pulse.
[0070]
The hand position detection circuit 55 detects the hand position of the hands (minute hand 221, hour hand 222) and outputs a detection result to the drive control unit 54 and the reception information processing unit 51.
[0071]
The switch unit 56 includes a first switch unit 561 that switches an electrical connection state between the reception drive unit 6 and the reception information processing unit 51, and a second switch that switches an electrical connection state between the reception drive unit 6 and the drive control unit 54. And a switch control unit 563 as a switch control unit for controlling the opening and closing operations of the first switch unit 561 and the second switch unit 562.
[0072]
The first switch means 561 is provided between the reception drive unit 6 and the reception circuit 511, and switches between an electrically conductive state and an electrically disconnected state of the reception drive unit 6 and the reception circuit 511. Examples of such a switch include a mechanical switch that mechanically performs a switching operation, a non-contact switch using a diode or a transistor, and the like.
The second switch unit 562 is provided between the reception drive unit 6 and the driver 541, and switches between the electrical conduction state and the electrical disconnection state of the reception drive unit 6 and the driver 541.
[0073]
The switch control unit 563 controls opening and closing of the first switch unit 561 and the second switch unit 562 according to a command from the reception control circuit 533. When the reception control circuit 533 instructs the switch control unit 563 to start receiving the standard radio wave, the switch control unit 563 turns on the first switch unit 561 and turns off the second switch unit 562. That is, the reception drive unit 6 and the reception circuit 511 are electrically connected, and the reception drive unit 6 and the driver 541 are electrically disconnected.
When a command to stop the reception processing operation in the reception circuit 511 is issued from the reception control circuit 533 to the switch control unit 563, the switch control unit 563 sets the first switch unit 561 to the OFF state and sets the second switch unit 561 to the OFF state. The means 562 is turned on. That is, the reception drive unit 6 and the reception circuit 511 are electrically disconnected, and the reception drive unit 6 and the driver 541 are electrically connected.
[0074]
The reception drive unit 6 includes a reception minute hand drive unit 61 that receives the standard radio wave and drives the minute hand, and a reception hour hand drive unit 62 that receives the standard radio wave and drives the hour hand.
The reception minute hand driving unit 61 includes a coil core 611 formed of ferrite, a first reception electromagnetic conversion coil 612 wound around the coil core 611, and a minute hand stator 613 excited by an induction magnetic field generated in the reception electromagnetic conversion coil. And a minute hand rotor 614 that is rotated by a magnetic field variation excited in the minute hand stator 613.
[0075]
The first reception electromagnetic conversion coil 612 is connected to the reception circuit 511 with the first switch 561 interposed therebetween, and connected to the driver 541 with the second switch 562 interposed.
When the first switch means 561 is in the ON state and the second switch means 562 is in the OFF state, the first reception electromagnetic conversion coil 612 receives a standard radio wave. That is, the signal of the standard radio wave is received in response to the magnetic field component of the standard radio wave linked to the first reception electromagnetic conversion coil 612, and the received signal is sent to the receiving circuit 511 via the first switch unit 561.
When the first switch 561 is in the OFF state and the second switch 562 is in the ON state, the first reception electromagnetic conversion coil 612 drives the minute hand 221. That is, the driving pulse from the driver 541 applied to the first receiving electromagnetic conversion coil 612 is electromagnetically converted to generate an induced magnetic field. This induction magnetic field is transmitted by the minute hand stator 613, and the minute hand rotor 614 is rotated. The rotation of the rotor is transmitted by the wheel train, and the minute hand is rotationally driven.
[0076]
The minute hand stator 613 has a flat plate shape made of a high magnetic permeability material and has a shape sandwiching both ends of the first reception electromagnetic conversion coil 612. Both ends of the coil core 611 are screwed to the minute hand stator 613. The minute hand stator 613 is provided with a concave portion for rotatably holding the minute hand rotor 614, and a notch 613A formed with a notch is provided on the inner periphery of the concave portion. The notch may be cut out from the outer periphery of the minute hand stator 613 toward the recess.
The minute hand rotor 614 is a two-pole magnetized circular permanent magnet, and the pinion of the minute hand rotor 614 is meshed with the train wheel 44.
[0077]
Like the reception minute hand driving unit 61, the reception hour hand driving unit 62 includes a coil core 621, a second reception electromagnetic conversion coil 622, an hour hand stator 623, and an hour hand rotor 624. The second reception electromagnetic conversion coil 622 is connected to the reception circuit 511 with the first switch 561 interposed therebetween, and connected to the driver 541 with the second switch 562 interposed therebetween.
[0078]
The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are connected in parallel via a switch (not shown). When a standard radio wave is received, this switch is turned on and connected in parallel. You. Then, the standard radio waves received by the first and second reception electromagnetic conversion coils 622 are added in parallel and sent to the reception circuit 511. When the drive pulse is applied from the drive control unit 54, the switch is turned off, and the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are driven independently.
[0079]
In the planar arrangement, as shown in FIG. 1, the first receiving electromagnetic conversion coil 612 and the second receiving electromagnetic conversion coil 622 have their axial directions different from each other, and the extensions of the central axes thereof are substantially orthogonal to each other. They are arranged in a positional relationship (the angle α at which the respective central axes intersect is approximately 90 degrees). The angle α may be in a range from 45 degrees to 135 degrees.
[0080]
The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are both disposed between the train wheel receiver 47 and the middle frame 14 as shown in FIG. Reference numeral 612 is arranged on the outer periphery of the movement 4 at about 11:00, and the second reception electromagnetic conversion coil 622 is arranged on the outer periphery of the movement 4 at about 8:00. The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are arranged such that both ends of the axis face the outside of the movement 4, that is, on the extension of the axis, the outer case 1 and the inner case are disposed. Only the frame 14 is located, and no metal parts in the movement 4 such as the train wheel 44 are located.
In the cross-sectional arrangement shown in FIG. 2, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are arranged in the movement 4 close to the back cover 3.
[0081]
The position of the notch 613A in the minute hand stator 613 and the position of the notch 623A in the hour hand stator 623 are the same as each other, and are substantially parallel to the axis of the receiving electromagnetic conversion coils 613, 623 in the forward direction of the hands 221, 222. It is formed by cutting. Due to the cogging torque generated by the notches 613A and 623A, the rotors 614 and 624 stop in a no-load state (non-excitation state) with the line connecting the N pole and the S pole substantially parallel to the axis of the reception electromagnetic conversion coils 612 and 622. I do.
[0082]
The train wheel 44 transmits the rotation of the rotors 614 and 624 toward the hands 221 and 222, and is connected to the second wheel & pinion 444 that rotates integrally with the minute hand shaft 442 to which the minute hand 221 is connected from the minute hand rotor 614. 44A and an hour hand wheel train 44B connected from the hour hand rotor 624 to the hour wheel 441 to which the hour hand 222 is connected.
[0083]
The date wheel 45 is a gear held inside the outer case 1 by the main plate 46, the wheel train holder 47 and the date wheel holder 451, and having a central opening. The date indicator 45 is formed of a non-conductive and non-magnetic member, and is formed of, for example, plastic, inorganic glass, paper, or the like. The date wheel 45 is meshed with a wheel train (not shown) connected to the hour wheel 441, and is rotated at a predetermined speed by the rotation of the hour wheel 441. On the date indicator 45, characters representing the day are written facing the dial 21 (not shown). A date window 212 is formed in the dial 21 so that the character of the date wheel 45 can be visually recognized from outside.
[0084]
The base plate 46 supports the train wheel 44 on the dial 21 side, and the train wheel receiver 47 supports the train wheel 44 on the back cover 3 side. The base plate 46 and the train wheel receiver 47 are formed of non-conductive and non-magnetic members, for example, plastic or ceramic.
[0085]
The middle frame 14 is a ring-shaped member along the inner periphery of the outer case 1 and surrounds the peripheral end surface of the movement 4. The movement 4 is fixed in the outer case 1 by the middle frame 14. The middle frame 14 is formed of a non-conductive and non-magnetic member, and is formed of, for example, plastic or ceramic.
[0086]
The battery 49 is a primary battery or a secondary battery, and its outer can case is formed of metal. The battery 49 is disposed substantially in the direction of 2 o'clock, and occupies a place from approximately 1 o'clock to approximately 3 o'clock.
[0087]
The operation of the first embodiment having such a configuration will be described.
The current time of the current time counter 531 is updated by the reference clock generated by dividing the oscillation of the crystal oscillator 411 (current time counting step). The position of the hands (minute hand 221 and hour hand 222) is detected by the hand position detection circuit 55, and the detection result is output to the drive control unit 54. The pointer position is compared with the counter value of the current time counter 531, and a driving pulse is applied from the driver 541 to the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 based on the comparison result (drive control step). ). When a driving pulse is applied to the first reception electromagnetic conversion coil 612, the first reception electromagnetic conversion coil 612 performs electromagnetic conversion to generate an induced magnetic field. The induced magnetic field propagates through the minute hand stator 613 to rotate the minute hand rotor 614. The rotation of the minute hand rotor 614 is transmitted to the minute hand 221 by the minute hand train wheel 44A, and the minute hand 221 indicates a number on the time display surface 211, so that the minute time is displayed (time display step).
[0088]
Similarly, when a drive pulse is applied from the driver 541 to the second reception electromagnetic conversion coil 622, an induction magnetic field is generated in the second reception electromagnetic conversion coil 622, and the hour hand rotor 624 is rotated via the hour hand stator 623. . The rotation of the hour hand rotor 624 is transmitted to the hour hand 222 via the hour hand wheel train 44B, and the hour hand 222 indicates a number on the time display surface 211 to display the hour and time.
[0089]
Next, the operation of receiving the standard time signal and the time adjusting operation based on the time information of the standard time signal will be described with reference to the flowchart of FIG.
When the reception time of the standard radio wave set in the reception control circuit 533 is, for example, 2:00 am (ST100), or the forced reception operation is performed by the external operation means 13 (ST101), the reception operation and the time of the standard radio wave Correction is started.
[0090]
When the reception of the standard radio wave is started, a reception start command is output from the reception control circuit 533 to the driver control unit 542, the switch control unit 563, and the reception circuit 511. When driver control section 542 receives a signal from reception control circuit 533, driver control section 542 stops the operation of driver 541, and the driving pulse from driver 541 is stopped (ST102). At this time, the rotors 614 and 624 stop at a predetermined stop position due to the action of the cogging torque.
When the switch control unit 563 receives the instruction to start reception, the first switch unit 561 is turned on and the second switch unit 562 is turned off (ST103). Further, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are connected in parallel.
[0091]
In this state, the standard radio wave interlinks the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622. Then, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 receive the standard radio wave in response to the magnetic field fluctuation of the standard radio wave (ST104). The signal of the standard radio wave received by the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 is sent to the reception circuit 511 via the first switch means 561, and the reception processing operation is executed (reception information processing). Process).
The receiving circuit 511 performs processing such as amplification, extraction, and decoding on the signal of the standard radio wave to obtain time information. The standard radio wave transmits time information (time code) of a second in a one-minute cycle, and the receiving circuit 511 receives time information set in advance in the reception control circuit 533, for example, three consecutive time information. To perform reception processing.
The time information processed by the reception circuit 511 is stored in the storage circuit 512.
[0092]
When the predetermined number of reception operations are completed (ST105), the time information stored in storage circuit 512 is output to comparison circuit 513. The comparison circuit 513 compares the time information stored in the storage circuit 512 with the display time based on the pointer position detected by the hand position detection circuit 55. The comparison result is output to the time adjustment circuit 532, and the time adjustment circuit 532 adjusts the count value of the current time counter 531 based on the comparison result (time adjustment step, ST106).
[0093]
When the reception operation is completed, a reception completion command is output from the reception control circuit 533 to the driver control unit 542, the switch control unit 563, and the reception circuit 511.
Receiving circuit 511, upon receiving the instruction to complete the reception, ends the reception processing operation.
Upon receiving the reception completion command, switch control section 563 turns off first switch means 561 and turns on second switch means 562 (ST107). In addition, the connection between the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 is disconnected, and the first and second reception electromagnetic conversion coils are driven independently.
[0094]
When the driver control unit 542 receives the instruction of completion of reception, the driver 541 is restarted (ST108). The driver 541 applies a drive pulse to the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 until the position of the hands detected by the hand position detection circuit 55 matches the corrected counter value of the current time counter 531. Then, the pointers 221 and 222 are fast-forwarded (ST109). When the pointer position matches the counter value of the current time counter 531, the correction of the pointer position ends, and the time correction is completed.
[0095]
According to the first embodiment having such a configuration, the following effects can be obtained.
(1) The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 can fulfill both functions of a standard radio wave reception function and a pointer driving function. Therefore, compared with the case where the antenna coil and the electromagnetic conversion coil are separately provided, the number of components can be reduced and the radio-controlled timepiece 100 can be downsized.
[0096]
(2) When receiving the standard radio wave, the first switch 561 is turned on and the second switch 562 is turned off. Therefore, the driver 541 does not affect the signal of the standard radio wave linked to the first and second reception electromagnetic conversion coils 622. As a result, the signal of the standard radio wave received by the reception electromagnetic conversion coil is accurately transmitted to the receiving circuit 511, and accurate time correction can be performed based on the accurate time information of the standard radio wave.
[0097]
(3) The first switch 561 is turned off and the second switch 562 is turned on except when the standard radio wave is received. Then, the drive pulse does not flow to the reception circuit 511, but is applied only to the first and second reception electromagnetic conversion coils 612 and 622. Therefore, since the amount of electromagnetic conversion in the first and second receiving electromagnetic conversion coils 612 and 622 can be accurately controlled, the rotation speed and the rotation period of the rotors 614 and 624 can be accurately controlled. As a result, the movement of the hands of the hands 221 and 222 can be accurately controlled.
[0098]
(4) When receiving the standard radio wave, the driver control unit 542 stops driving the driver 541, and the driver 541 stops outputting the driving pulse. Therefore, it is possible to reliably prevent the drive pulse from being superimposed on the standard radio wave interlinked with the first and second reception electromagnetic conversion coils 612 and 622. As a result, the time information of the standard radio wave can be received accurately. Further, since unnecessary drive pulses are not output, energy consumption can be reduced. As a result, in addition to reducing the frequency of replacement of the battery 49, the radio-controlled timepiece 100 can be downsized by reducing the size of the battery 49.
[0099]
(5) The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are disposed on the outer periphery of the movement 4 and both ends of the reception electromagnetic conversion coils 612 and 622 face outward of the movement 4. ing. Therefore, the standard radio wave that enters the inside of the outer case 1 is immediately linked to the first and second reception electromagnetic conversion coils 612 and 622. In other words, since the standard radio wave is not shielded by the metal parts of the movement 4, it is possible to increase the interlinkage magnetic flux interlinking the first and second reception electromagnetic conversion coils 622. As a result, the reception sensitivity of the first and second reception electromagnetic conversion coils 612 and 622 can be improved.
[0100]
(6) The outer case 1 and the middle frame 14 are located on the extension of the axis of the first and second reception electromagnetic conversion coils 612 and 622, but both the outer case 1 and the middle frame 14 are non-conductive members. Therefore, the standard radio wave is linked to the first and second reception electromagnetic conversion coils 612 and 622 without being shielded by the outer case 1 and the middle frame 14. Furthermore, in addition to the base plate 46 and the train wheel receiver 47 as the base frame, the dial 21 and the back cover 3 are also non-conductive members, so that the standard radio wave is not shielded by the base frame, the dial 21 and the like. The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are linked. Therefore, it is possible to sufficiently secure the linkage magnetic flux to the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622, and to improve the reception sensitivity.
[0101]
(7) The first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are arranged at an angle of 90 degrees with each other. Therefore, the magnetic fluxes do not easily interfere with each other, and do not interfere with the rotation control of the rotors 614 and 624. As a result, the hands 221 and 222 are accurately moved. Further, since the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 have their axes oriented in directions different from each other, regardless of the traveling direction of the standard radio wave or the direction of the timepiece 100, either of the reception electromagnetic conversion coils 612 and 622 has the same axis. The standard coils can always be received by the conversion coils 612 and 622. Therefore, even when the direction is not fixed, such as a wristwatch, the time can be adjusted by reliably receiving the standard radio wave.
[0102]
(8) A reception minute hand drive section 61 for driving the minute hand 221 and a reception hour hand drive section 62 for driving the hour hand 222 are provided. Therefore, the minute hand 221 and the hour hand 222 are independently rotated by mutually independent driving forces. Therefore, even when the time is adjusted based on the received time information, the minute hand 221 and the hour hand 222 can be independently rotated, and the hand position can be instantaneously corrected. For example, since the hour hand 222 is directly rotated, as compared with a configuration in which the hour hand 222 advances by one graduation in conjunction with one rotation of the minute hand 221, time correction is faster and power consumption can be reduced accordingly.
[0103]
(9) Notches 613A and 623A for fixing the rotor position in a no-load state are provided on the minute hand stator 613 and the hour hand stator 623. Therefore, when the standard radio wave is received by the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622, noise of magnetic field fluctuation due to rotation of the rotors 614 and 624 does not occur, and the standard radio wave is accurately received. Can be.
[0104]
(10) Since the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are connected in parallel when receiving the standard radio wave, at least one of the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 is used. The time can be corrected based on the time information of the standard radio wave received on either side. Therefore, the probability of successful reception can be improved.
[0105]
(2nd Embodiment)
Next, a second embodiment of the radio-controlled timepiece according to the present invention will be described.
The basic configuration of the second embodiment is the same as that of the first embodiment, but the feature of the second embodiment is that a stop time storage unit (disconnection time storage unit) 57 is provided.
[0106]
FIG. 5 shows the configuration of the control unit according to the second embodiment. In FIG. 5, the control unit 5 includes a switch control unit 563, a stop time storage unit 57 that counts the OFF state time of the second switch unit 562, and a driver control unit 542.
The basic operation of the switch control unit 563 is the same as that of the first embodiment, but the switch control unit 563 outputs information on the open / close operation of the second switch unit 562 to the stop time storage unit 57.
[0107]
The stop time storage unit 57 includes a counter that counts time. The stop time storage unit 57 receives a reference clock from the reference signal generation unit 52 via the central control circuit 53, and Information about the switch operation of the second switch unit 562 is input from the switch control unit 563.
When receiving the information on the operation of turning off the second switch means 562 from the switch control unit 563, the stop time storage unit 57 starts counting time with a counter (disconnection time storage step). That is, when the second switch means 562 is turned off and the driving pulse from the driver 541 to the reception electromagnetic conversion coil is stopped, the counting of the time (stop time) is started. When receiving information on the operation of turning on the second switch means 562 from the switch control unit 563, the counting of the time by the counter is terminated, and the counted stop time (cutting time) is transmitted to the driver control unit 542. Output.
[0108]
When the driver control unit 542 receives the information about the stop time from the stop time storage unit 57, the driver control unit 542 causes the driver 541 to output a drive pulse for fast-forwarding the hands by the stop time.
[0109]
With reference to the flowchart of FIG. 6, a description will be given of a standard radio wave reception operation and a time correction operation based on standard radio wave time information in the second embodiment.
The basic operation is the same as that of the first embodiment, but when the switch control unit 563 receives a command to start the reception of the standard radio wave, the first switch unit 561 is turned on and the second switch unit 561 is turned on. The switch unit 562 is turned off (ST203). At this time, the switch control unit 563 outputs to the stop time storage unit 57 the information that the second switch unit 562 is turned off. Then, the stop time storage unit 57 starts counting the stop time (ST204).
[0110]
When the receiving operation is completed a predetermined number of times and the receiving operation is completed (ST206), the count value of current time counter 531 is corrected according to the time information acquired by receiving circuit 511 (ST207). Further, the switch control unit 563 switches the second switch unit 562 to the ON state and switches the first switch unit 561 to the OFF state (ST208), and outputs this information to the stop time storage unit 57. Then, the stop time storage unit 57 ends counting of the stop time (ST209), and outputs the counted stop time to the driver control unit 542.
[0111]
Driver control unit 542 receives the command of the completion of reception from reception control circuit 533, and further receives the input of the stop time from stop time storage unit 57, and restarts driver 541 (ST201). At this time, first, the driver control unit 542 causes the driver 541 to output a drive pulse for fast-forwarding the hands 221 and 222 for the stop time. Then, the hands 221 and 222 are fast-forwarded by the time during which they stopped (ST211). Subsequently, the driver control unit 542 causes the driver 541 to output a drive pulse that causes the corrected counter value of the current time counter 531 to match the detection result of the hand position detection circuit 55. Then, the pointer position is corrected (ST212), and the time correction is completed.
The fast-forwarding of the hands based on the stop time (ST211) is performed simultaneously and in parallel with the correction of the count value of the current time counter 531 by the reception information processing unit 51 and the time correction circuit 532 (ST207).
[0112]
According to the second embodiment having such a configuration, the following effects can be obtained in addition to the effects (1) to (10) of the first embodiment.
(11) The hands 221 and 222 are quickly forwarded by the stop time stored in the stop time storage unit 57 immediately before the reception of the standard time signal is completed and the time is adjusted. Therefore, the time required for time correction can be reduced. In addition, the hands 221 and 222 are fast-forwarded in parallel with the processing of the received standard time signal and the correction of the counter value of the current time counter 531, so that unnecessary waiting time does not occur and dead time is eliminated. Time can be adjusted quickly.
[0113]
(Third embodiment)
Next, a third embodiment of the radio-controlled timepiece according to the present invention will be described.
The basic configuration of the third embodiment is the same as that of the first embodiment, but the feature of the third embodiment is that output from the reception control circuit 533 to the reception circuit 511, the drive control unit 54, and the switch unit 56 is performed. At the output timing of the command. That is, in the first embodiment, the movement of the hands 221 and 222 is stopped for a certain time during which the standard radio wave is received. However, in the third embodiment, the movement of the hands 221 and 222 is continued while the standard radio wave is received. The feature is that it does.
[0114]
The reception control circuit 533 instructs the reception circuit 511, the drive control unit 54, and the switch unit 56 to start reception when the reception circuit 511 starts the reception processing of the standard radio wave. The reception control circuit 533 causes the reception circuit 511 to perform a reception operation for less than one minute, for example, 55 seconds, and then outputs a command to temporarily stop reception to the reception circuit 511, the drive control unit 54, and the switch unit 56. Then, upon receiving the instruction to temporarily stop reception, the switching operation of the switch unit 56 and the movement of the hands of the hands 221 and 222 by the driving pulse from the driver 541 are performed before reaching the next second. Further, the reception control circuit 533 outputs a reception operation start command to the reception circuit 511, the switch unit 56, and the drive control unit 54 at least until the next second arrives.
When a predetermined number of reception operations are completed, the reception control circuit 533 outputs a reception stop command to the reception circuit 511, the switch unit 56, and the drive control unit 54.
[0115]
With reference to the flowchart of FIG. 7, a description will be given of a standard radio wave reception operation and a time correction operation based on standard radio wave time information in the third embodiment.
If the standard radio wave reception time set in the reception control circuit 533 has come (for example, 2:00 am) (ST300), or if a forced reception operation is performed by the external operation means 13 (ST301), the standard radio wave reception operation is performed. Then, time adjustment is started, and a reception start command is output from the reception control circuit 533 to the driver control unit 542, the switch control unit 563, and the reception circuit 511.
[0116]
When driver control section 542 receives the reception start signal, driver control section 542 stops the operation of driver 541 (ST302). Then, the driving pulse from the driver 541 is stopped.
When the switch control unit 563 receives a command to start reception, the switch control unit 563 outputs a switch switching command to the first switch unit 561 and the second switch unit 562. Then, switch switching is performed in which the first switch means 561 is turned on and the second switch means 562 is turned off (ST303).
[0117]
In this state, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 receive required digit data of time information for one frame (predetermined unit) in less than 60 seconds (ST304).
[0118]
Here, in the time code format of the standard radio wave, one signal is transmitted every one second, and one frame is formed in 60 seconds. The time code format includes the minute data of the current time, the hour, the total date from January 1 of the current year, the year (last two digits of the year), the day of the week, and the leap second digit data in order from the second. Is represented by a combination of numerical values (bit data) assigned every second. In addition, although 60 seconds are allocated to one frame, generally, data is not allocated to all of the 60 seconds. is there. Also, since the bit signal sent at 59 seconds is a parity bit, at least the last second is not a signal constituting digit data.
Therefore, for example, a receiving operation is performed for 55 seconds to receive necessary data for one frame.
[0119]
The signal of the standard radio wave for one frame received by the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 is sent to the reception circuit 511 via the first switch means 561, subjected to reception processing, and processed by the storage circuit 512. It is memorized.
[0120]
When the reception operation of one frame is performed for 55 seconds, the reception control circuit 533 outputs a command to temporarily stop reception to the driver control unit 542, the switch control unit 563, and the reception circuit 511. Receiving circuit 511, upon receiving the command to temporarily suspend reception, suspends the reception processing operation.
When receiving the command to temporarily stop reception, switch control section 563 performs switch switching to turn first switch 561 off and second switch 562 to on (ST305).
[0121]
When driver control unit 542 receives a command to temporarily stop reception, it restarts driver 541 (ST306). The driver 541 outputs a drive pulse that causes the positions of the hands 221 and 222 detected by the hand position detection circuit 55 to match the count value counted by the current time counter 531. When the drive pulse is applied to first reception electromagnetic conversion coil 612 and second reception electromagnetic conversion coil 622, hands 221 and 222 are moved, and the count value of current time counter 531 is displayed on the time display section (ST307). .
If the reception has not been completed the predetermined number of times (ST308), the reception operation is started again by a command from the reception control circuit 533.
[0122]
For example, when 2:00:00 am, which is the set reception time, it is necessary to move the time display unit by one minute from 1:59 to 2:00 in the case of normal hand movement. Since the driver 541 is stopped to perform the operation, the time display remains at 1:59 without performing the hand movement. When the switch is switched to start the reception operation at 2:00:00, that is, when the first switch means 561 is turned on and the second switch means 562 is turned off, the reception of the standard radio wave is correct. Since the time is from the second, the time information starts from 2:01:00. That is, if the time information of one frame is received in less than 60 seconds (55 seconds), the time is 2:01:55.
[0123]
In this state, the driver 541 is restarted together with the switch switching, and the pointer position is adjusted to the current time counter 531. In other words, a driving pulse for moving the hand by one step (from 1 o'clock to 2 o'clock) is applied to the first reception electromagnetic conversion coil 612 for two steps (from 59 minutes to 01 minutes) and to the second reception electromagnetic conversion coil 622, and the hands 221, The hand movement of 222 is performed. Then, when the hands of the hands 221 and 222 are finished, the receiving operation is started again, and the first and second reception electromagnetic conversion coils 612 and 622 receive time information from 2:02:00 am.
[0124]
ST302 to ST307 are repeated until a predetermined number of times of time information (frames) are obtained, for example, three times.
When the reception operation of the predetermined number of times is completed (ST308: YES), the time correction circuit 532 is obtained from the comparison result between the time information stored in the storage circuit 512 and the display time based on the pointer position detected by the hand position detection circuit 55. , The count value of the current time counter 531 is corrected (ST309).
[0125]
The driver 541 applies the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 until the positions of the hands 221 and 222 detected by the hand position detection circuit 55 match the corrected counter value of the current time counter 531. A driving pulse is output, and the hands 221 and 222 are fast-forwarded. When the pointer position matches the counter value of the current time counter 531, the correction of the pointer position ends (ST 310), and the time correction is completed.
[0126]
According to the third embodiment, the following effects can be obtained in addition to the effects (1) to (10) of the above-described embodiment.
(12) Since the hands of the hands 221 and 222 continue to operate while the standard radio wave is received, almost accurate current time can be displayed on the time display unit 2. If the reception of the standard radio wave is not successful, the reception operation may be continued for several minutes. However, no matter how long the reception operation is continued, the time display unit 2 displays a substantially accurate current time. Inconvenience of erroneously recognizing the current time can be prevented, and convenience can be improved.
[0127]
(13) By moving the hands 221 and 222 even during reception of the standard radio wave, the time displayed on the time display unit 2 can always be substantially the current time. Then, the operation of time correction for correcting the position of the hands according to the time information of the standard time signal may be slight. Therefore, time correction is performed in a short time and simply, and the number of fast-forward pulses for time correction is reduced, so that energy consumption can be reduced as a result.
[0128]
During the reception of the standard radio wave, the hands of the hands 221 and 222 are not moved at the moment of the second, but after the standard radio wave for one frame is received. As a result, the display of the time display unit 2 is delayed by a maximum of 1 minute and 55 seconds from the count value of the current time counter 531. However, considering that the count value itself of the current time counter 531 is shifted from the accurate current time by several tens of seconds before and after, such a time display deviation is not recognized as a major problem. Displaying approximately the current time has an effect of greatly improving the convenience of the user as compared with the case where the hands of the hands 221 and 222 are completely stopped during reception of the standard radio wave.
[0129]
In addition, the switching operation of the first and second switch means 561 and 562 is repeatedly performed during the reception of the standard radio wave. For example, the first and second switch means 561 and 562 are switched to a non-contact switch (for example, a thyristor or the like). In this case, since the power required for switch switching is extremely small, there is almost no increase in energy consumption. Rather, the energy consumption can be reduced as a whole by reducing the number of fast-forward pulses in time correction.
[0130]
(Fourth embodiment)
Next, a fourth embodiment of the radio-controlled timepiece according to the present invention will be described.
The feature of the fourth embodiment is that it has a power generation function as well as a standard radio wave reception function.
This radio-controlled timepiece is the same as the first embodiment in that it includes an exterior case 1 (not shown), a time display unit, and a movement 4.
[0131]
FIG. 8 shows a plan view of the movement of the fourth embodiment. In FIG. 8, a movement 4 includes a crystal unit 41 including a crystal unit 411, a control unit 5 having a control function, a stepping motor 48 as a driving unit for driving the hands, and a power of the stepping motor 48. (Not shown), a power generation unit 7 that receives standard radio waves and generates power, an external energy input unit 13 that inputs external energy to the power generation unit 7, and a power generation by the power generation unit 7. And a secondary battery 491 as a power storage means for storing the generated power.
[0132]
FIG. 9 shows a configuration of the control unit 5. The control unit 5 includes a reception information processing unit 51 that processes the standard radio wave received by the reception power generation unit 7, a reference signal generation unit 52 that generates a clock pulse using an oscillation pulse from the crystal unit 411, and a A central control circuit 53 that counts the time and corrects the current time based on the received time information; a drive control unit 54 that drives and controls the stepping motor 48; a hand position detection circuit 55 that detects a pointer position; A rectifying unit 58 for rectifying the current generated by the power generation unit 7, a switch unit 56 for switching the electrical connection between the reception information processing unit 51 and the secondary battery 491 for the reception power generation unit 7, and a power generation state in the reception power generation unit 7. And a power generation detection unit (power generation detection means) 59 for detecting the
[0133]
The central control circuit 53 includes a current time counter 531, a time adjustment circuit 532, and a reception control circuit 533.
The reception control circuit 533 instructs the reception information processing unit 51 to start reception when the reception circuit 511 starts the reception processing of the standard radio wave. At the same time, a reception start command is output to the switch unit 56. When terminating the reception processing of the standard radio wave to the reception information processing section 51, the reception information processing section 51 is instructed to stop reception, and the switch section 56 is also output a reception stop instruction.
When the power generation detection unit 59 detects power generation in the reception power generation unit 7, the reception control circuit 533 instructs the switch unit 56 and the reception information processing unit 51 to stop reception.
[0134]
The switch unit 56 includes a third switch unit (first switch unit) 564 that switches an electrical connection state between the reception power generation unit 7 and the reception information processing unit 51, and an electrical connection state between the reception power generation unit 7 and the rectification unit 58. And a switch control section 563 for controlling the opening and closing operations of the third switch means and the fourth switch means.
[0135]
The third switch unit 564 is provided between the reception power generation unit 7 and the reception information processing unit 51, and switches between the electric conduction state and the electric disconnection state of the reception power generation unit 7 and the reception information processing unit 51.
The fourth switch means 565 is provided between the reception power generation unit 7 and the rectification unit 58, and switches between the electrical conduction state and the electric disconnection state of the reception power generation unit 7 and the rectification unit 58.
[0136]
The switch control unit 563 controls opening and closing of the third switch unit 564 and the fourth switch unit 565 according to a command from the reception control circuit 533. When the reception control circuit 533 instructs the switch control unit 563 to start receiving the standard radio wave, the switch control unit 563 turns on the third switch unit 564 and turns off the fourth switch unit 565. That is, the reception power generation unit 7 and the reception information processing unit 51 are electrically connected, and the reception power generation unit 7 and the rectification unit 58 are electrically disconnected.
[0137]
In addition, when a command to stop the reception processing operation in the reception information processing unit 51 is issued from the reception control circuit 533 to the switch control unit 563, the switch control unit 563 sets the third switch unit 564 to the OFF state and sets the third switch unit 564 to the OFF state. Four-switch means 565 is turned on. That is, the reception power generation unit 7 and the reception information processing unit 51 are electrically disconnected, and the reception power generation unit 7 and the rectification unit 58 are electrically connected.
[0138]
The stepping motor 48 includes a motor coil core 481, a motor coil 482 wound around the motor coil core 481, a motor stator 483 for transmitting a magnetic field variation generated in the motor coil 482, and a magnetic field transmitted by the motor stator 483. And a motor rotor 484 rotated by the fluctuation. The rotation of the motor rotor 484 is transmitted by the wheel train 44 toward hands (not shown).
[0139]
The reception power generation unit 7 includes a coil core 71 formed of ferrite, a third reception electromagnetic conversion coil 72 wound around the coil core, a power generation rotor 73 rotated by energy input by the external energy input unit 13, A power generating stator 74 for transmitting the magnetic field of the power generating rotor 73 to the third receiving electromagnetic conversion coil 72.
[0140]
The third reception electromagnetic conversion coil 72 is arranged on the outer periphery of the movement 4. The stator 74 for power generation has basically the same configuration as the stator 613 for the minute hand and the stator 623 for the hour hand, and includes a concave portion for rotatably holding the rotor 73.
[0141]
The third reception electromagnetic conversion coil 72 is connected to the reception information processing unit 51 with the third switch means 564 interposed, and the power generation detection unit 59 is connected to the third reception electromagnetic conversion coil 72.
When the third switch 564 is ON and the fourth switch 565 is OFF, the third receiving electromagnetic conversion coil 72 receives a standard radio wave. That is, the signal of the standard radio wave is received in response to the magnetic field component of the standard radio wave linked to the third reception electromagnetic conversion coil 72, and the received signal is sent to the reception information processing unit 51 via the third switch unit 564. .
[0142]
When the third switch 564 is in the OFF state and the fourth switch 565 is in the OFF state, the third receiving electromagnetic conversion coil 72 performs power generation. That is, the rotor 73 is rotated by the external energy input by the external energy input unit 13. Magnetic field fluctuations caused by the rotation of the rotor 73 are transmitted by the power generation stator 74. The magnetic field fluctuation transmitted by the power generation stator 74 is electromagnetically converted by the third reception electromagnetic conversion coil 72 to generate an induced electromotive force in the third reception electromagnetic conversion coil 72.
[0143]
The external energy input means 13 includes a winding stem 131 provided so as to penetrate the trunk of the outer case 1 from approximately 3 o'clock, and a wheel train 49 that transmits the rotation of the winding stem 131 to the receiving power generation unit 7. It is provided with. One end of the winding stem 131 is located outside the outer case 1 and a crown 132 is provided at this end. The other end of the winding stem 131 is located inside the outer case 1, and a pinion wheel 135 is provided on the other end side. Is transmitted to the power generation rotor 73.
The external energy input means 13 also functions as the external operation means 13 for performing an input operation for forcibly starting the receiving operation.
[0144]
The operation of the fourth embodiment having such a configuration will be described.
A case where the hand movement of the pointer by the stepping motor 48 and the power generation by the reception power generation unit 7 are performed when the third switch means 564 is in the OFF state and the fourth switch means 565 is in the ON state will be described.
When the time is displayed by the movement of the hands by the stepping motor 48, the position of the hands detected by the hand position detecting circuit 55 is compared with the counter value of the current time counter 531. Based on the comparison result, the driver 541 sends the time to the stepping motor 48. A drive pulse is applied. When a drive pulse is applied to the stepping motor 48, the motor rotor 484 is rotated. The rotation of the motor rotor 484 is transmitted to the hands by the train wheel 44, and the current time is displayed on the time display unit.
[0145]
Next, when power is generated in the receiving power generation unit 7, when the winding stem 131 is rotated to input external energy, the rotation of the winding stem 131 is rotated through the pinion wheel 135, the crown gear 492, and the intermediate gear 493, and the power generation rotor 73 is rotated. And the power generation rotor 73 is rotated. Magnetic field fluctuations caused by rotation of the power generation rotor 73 are transmitted by the power generation stator 74 and electromagnetically converted by the third reception electromagnetic conversion coil 72. Then, an induced electromotive force is generated in the third receiving electromagnetic conversion coil 72, and the induced power is transmitted to the rectifier 58 via the fourth switch means 565 and rectified. The rectified power is stored in the secondary battery 491 (power storage step).
[0146]
Next, the reception operation of the standard radio wave and the time correction operation based on the time information of the standard radio wave will be described with reference to the flowchart of FIG.
When the reception time (for example, 2:00 am) of the standard radio wave set in the reception control circuit 533 is reached (ST400) or when the forced reception operation is performed by the external operation means 13 (ST401), the reception operation of the standard radio wave is performed. Time adjustment is started.
[0147]
When starting reception of the standard radio wave, first, the reception control circuit 533 reads out the state of power generation detection (power generation detection step) in the power generation detection unit 59. When the power generation is not performed in the reception power generation unit 7 (ST402: NO), the reception control circuit 533 outputs a reception start command to the switch control unit 563 and the reception circuit 511.
When switch control section 563 receives the command to start reception, it turns on third switch means 564 and turns off fourth switch means 565 (ST403).
[0148]
In this state, the standard radio wave interlinks with the third reception electromagnetic conversion coil 72. Then, the third reception electromagnetic conversion coil 72 receives the standard radio wave in response to the magnetic field fluctuation of the standard radio wave. The signal of the standard radio wave received by third reception electromagnetic conversion coil 72 is sent to reception circuit 511 via third switch means 564, and the reception processing operation is executed (ST404).
[0149]
The reception control circuit 533 periodically reads the detection state of the power generation detection unit 59 even during the reception operation (ST405), and continues the reception operation to the reception circuit 511 on the condition that the power generation detection unit 59 has not detected power generation. Let it.
[0150]
When the reception operation of the predetermined number of times is completed (ST406), the received time information is compared with the display time based on the pointer position detected by the hand position detection circuit 55, and the current time counter 531 is checked based on the comparison result. The count value is corrected by the time correction circuit 532 (ST407).
[0151]
When the reception operation is completed, a reception completion command is output from the reception control circuit 533 to the switch control unit 563 and the reception circuit 511.
Receiving circuit 511, upon receiving the instruction to complete the reception, ends the reception processing operation.
Upon receiving the reception completion command, switch control section 563 turns off third switch means 564 and turns on fourth switch means 565 (ST408).
[0152]
The driver 541 outputs a drive pulse to the stepping motor 48 until the position of the hands detected by the hand position detection circuit 55 matches the corrected counter value of the current time counter 531 and fast-forwards the hands. When the pointer position matches the counter value of the current time counter 531, the correction of the pointer position ends, and the time correction is completed (ST 409).
[0153]
In ST402, when power generation is detected by power generation detection section 59 (ST402: YES), reception control circuit 533 does not output a command to start reception and waits until power generation detection section 59 no longer detects power generation. Maintain state.
In ST405, when power generation is detected by power generation detection section 59 during the reception operation (ST405: YES), reception control circuit 533 outputs a command to stop the reception operation to switch control section 563 and reception circuit 511. When receiving the command to stop the receiving operation, the switch control section 563 turns off the third switch means 564 and turns on the fourth switch means 565. Then, the standby state is maintained until the power generation is not detected by the power generation detection unit 59.
[0154]
According to the fourth embodiment, the following effect can be obtained in addition to the effects (5) and (6) of the above-described embodiment.
(14) The power energy can be obtained by using the power generated by the electromagnetic conversion in the third receiving electromagnetic conversion coil 72. Therefore, the convenience can be improved without requiring maintenance such as battery replacement. In addition, since the third reception electromagnetic conversion coil 72 can perform electromagnetic conversion and reception of the standard radio wave, the number of components can be reduced as compared with the case where the power generation coil and the radio wave reception coil are separately provided. be able to. As a result, the radio-controlled timepiece 100 can be reduced in size.
[0155]
(15) The third reception electromagnetic conversion coil 72 is disposed on the outer periphery of the movement 4 and both ends of the reception electromagnetic conversion coil 72 are disposed facing the outside of the movement 4. Therefore, the standard radio wave that enters the inside of the outer case 1 is immediately linked to the third receiving electromagnetic conversion coil 72. That is, since the standard radio wave is not shielded by the metal parts of the movement 4, it is possible to increase the interlinkage magnetic flux interlinking the third reception electromagnetic conversion coil 72. As a result, the receiving sensitivity of the third receiving electromagnetic conversion coil 72 can be improved.
[0156]
(16) When the power generation detection unit 59 is provided and the power generation in the reception power generation unit 7 is detected, the third reception electromagnetic conversion coil 72 and the reception information processing unit 51 are disconnected by the third switch unit 564. Therefore, the generated power is shut off by the third switch unit 564 before the reception information processing unit 51, so that even if the withstand voltage of the reception circuit 511 is small, damage can be prevented.
[0157]
(17) The fourth switch means 565 is provided, and the third reception electromagnetic conversion coil 72 is disconnected from the reception information processing unit 51 by the fourth switch means 565 at least during power generation. The generated power does not escape to the reception information processing unit 51, and all of the generated power can be stored in the secondary battery 491.
[0158]
The power generating stator 74 does not particularly have a notch or the like for fixing the rotor position, but the rotor 73 is fixed in position by meshing with the wheel train 49 (intermediate gear 493) unless the winding stem 131 is rotated by an external force. You. Therefore, the fluctuation of the magnetic field due to the rotation of the rotor 73 does not overlap the standard radio wave during the reception of the standard radio wave.
[0159]
(Modification)
FIG. 11 shows an example of the reception electromagnetic conversion coil. In the above embodiment, the reception electromagnetic conversion coils (the first to third reception electromagnetic conversion coils 612, 622, and 72) have been described as being wound around the coil cores 611, 621, and 71.
Here, for example, as shown in FIG. 11A, the receiving electromagnetic conversion coil 8 may be wound around the coil core 83 only once. And, T which is both ends of the reception electromagnetic conversion coil 8 ₁ And T ₂ May be connected to the receiving circuit 511, the driver 541, or the rectifier 58. That is, when the reception electromagnetic conversion coil 8 receives the standard radio wave, the induced voltage generated by the linkage magnetic flux is represented by T ₁ And T ₂ Receive with the voltage difference between. When the pointer is driven by the electromagnetic conversion of the reception electromagnetic conversion coil 8, T ₁ And T ₂ And a driving pulse is applied. When power is generated by the electromagnetic conversion of the receiving electromagnetic conversion coil 8, T ₁ And T ₂ And the induced electric power generated between them is stored.
According to such a configuration, the configuration is the simplest and the manufacturing cost can be reduced by using a coil that has been widely used in the past.
[0160]
Alternatively, as shown in FIG. 11B, the reception electromagnetic conversion coil 8 is configured by a winding 81 wound once around a coil core 83 and a lead wire 82 connected in the middle of the winding 81. It may be. In FIG. 11B, both ends of the winding 81 are T ₁ , T ₂ And the end of the lead wire 82 is T ₃ And Then, for example, T ₁ And T ₂ Is connected to the receiving circuit 511 and the rectifying unit 58, while T ₁ And the end T of the lead wire ₃ May be connected to the driver 541. According to such a configuration, for the reception and generation of the standard radio wave, while the induced voltage (power) due to the linkage magnetic flux is increased by using the entire length of the coil core 83, the region to which the drive pulse is applied is narrowed. , The ampere-turn can be reduced and the driving force for the pointer can be adjusted.
[0161]
Alternatively, as shown in FIG. 11C, the receiving electromagnetic conversion coil 8 has a portion wound once to the middle of the coil core 83 and a portion wound once or more around the remaining portion of the coil core 83. A winding 81 and a lead 82 connected in the middle of the winding 81 may be provided. In FIG. 11C, the winding 81 is wound once from one end of the coil core 83 to the other end, and then is turned back and further wound halfway through the coil core 83. The lead wire 82 is connected to the winding 81 at the other end of the coil core 83. Note that, in FIG. ₁ , T ₂ And the end of the lead wire 82 is T ₃ And
Then, for example, both ends T of the winding 81 ₁ And T ₂ Is connected to the receiving circuit 511 or the rectifying unit 58, and T ₂ And T which is the end of the lead wire ₃ May be connected to the driver 541.
According to such a configuration, the number of windings can be increased by folding back the windings 81. Therefore, for reception and power generation of the standard radio wave, the induced voltage (power) due to the interlinkage magnetic flux can be further increased, and the driving force for the pointer can be adjusted by changing the number of turns in the region where the driving pulse is applied. .
[0162]
In the above, the end T of the winding 81 ₁ , T ₂ And the end T of the lead wire ₃ Is connected to the receiving circuit 511, the driver 541, and the rectifying unit 58 depending on the case, and is not limited to the above example.
[0163]
The radio-controlled timepiece of the present invention is not limited to the above-described embodiment, but may, of course, be modified in various ways without departing from the scope of the present invention.
[0164]
In the above embodiment, the case where the reception electromagnetic conversion coil operates as the reception antenna and the motor coil and the case where the reception electromagnetic conversion coil operates as the reception antenna and the power generation coil have been described. May also be used. Alternatively, in the fourth embodiment, the case where the reception electromagnetic conversion coil 72 is shared as the reception antenna and the power generation coil has been described. However, the motor coil 482 of the fourth embodiment also serves as the reception electromagnetic conversion coil for the motor. It may be shared as a coil and a receiving antenna. When a standard radio wave is received, the power generation coil and the motor coil may be connected in series, or the power generation coil and the motor coil may be connected in parallel.
[0165]
Further, a dedicated antenna coil for receiving the standard radio wave may be provided. When receiving the standard radio wave, the reception electromagnetic conversion coil may be connected in parallel or in series with the dedicated antenna coil.
[0166]
In the first embodiment, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are described as being connected in parallel at the time of receiving the standard radio wave. However, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are connected in parallel. The reception electromagnetic conversion coil 622 may be connected in series at the time of receiving the standard radio wave.
[0167]
In the above embodiment, the control unit 5 is not limited to the one configured by hardware such as the central control circuit 53, the reception information processing unit 51, and the switch unit 56, but also includes a CPU (central processing unit) and a memory (storage device). A computer equipped with a computer and the like is installed, and a predetermined program is installed in the computer to realize the functions of the central control circuit 53, the reception information processing unit 51, the switch unit 56, the stop time storage unit 57, the power generation detection unit 59, and the like. It may be. According to such a configuration, it is easy to change the setting of various parameters. For example, the scheduled reception time in the reception control circuit 533 and the switch switching timing in the switch control unit 563 can be appropriately changed. The predetermined program may be installed by directly pointing a memory card, a CD-ROM, or the like into the radio-controlled timepiece 100, or by attaching an external device for reading these recording media to the radio-controlled timepiece 100. You may connect. Further, a LAN cable, a telephone line or the like may be connected to the radio-controlled timepiece 100 to supply and install the program by communication, or the program may be supplied and installed wirelessly. When the program is supplied wirelessly, there is an advantage that the program can be received by the reception electromagnetic conversion coil.
[0168]
In the first embodiment, the case 1 is described as being formed of a non-conductive member. However, the case 1 may be formed of a metal member such as brass, stainless steel, and a titanium alloy. As described above, even if the outer case 1 is made of metal, the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 are arranged close to the back cover 3 or the dial 21 which is a non-conductive member. Then, the standard radio wave entering from the back cover 3 side or the dial 21 side interlinks the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622, so that the standard radio wave can be received. It is.
[0169]
In the first embodiment, the reception electromagnetic conversion coils 612 and 622 are shared as a reception antenna and a motor coil. However, the antenna is required to be sensitive to external radio waves, whereas the motor coil is not. Is required to have magnetic resistance to radio waves from Therefore, by making the number of windings of the reception electromagnetic conversion coils 612 and 622 extremely large, a coil having high sensitivity to radio waves and high magnetic resistance can be obtained. By increasing the number of windings, the overall size can be reduced as compared to the case where the motor coil and the receiving coil are separately provided, even if the coil is slightly thickened.
[0170]
In the above-described embodiment, the base frame may be a member on which the reception drive unit 6 or the reception power generation unit 7 is mounted, and usually includes a main plate 46 and a train wheel receiver 47. Further, as the base frame, a case in which the outer case 1 and the back cover 3 are integrated (one-piece type), a case in which the back cover 3 and the band for arm attachment are integrated, the case 1 and the back cover 3 and the band May be integrated.
[0171]
In the first embodiment, the motor configuration in which the reception electromagnetic conversion coils 612 and 622 are the stator and the rotor is the rotor has been described as an example, but the motor configuration in which the reception electromagnetic conversion coils 612 and 622 are the rotor is described. There may be.
[0172]
In the first embodiment, when the standard radio wave is received, both the first reception electromagnetic conversion coil 612 and the second reception electromagnetic conversion coil 622 stop the motor drive and receive the standard radio wave. One of them may receive the radio wave while the other is driven by the motor. For example, the second reception electromagnetic conversion coil 622 that drives the hour hand 222 may receive standard radio waves, and the first reception electromagnetic conversion coil 612 may continue driving the minute hand 221.
[0173]
In the third embodiment, if the scheduled time is not set to the exact second such as 2:00:00 am, but is shifted from the exact second, such as 2:00:30 am, The hand movement step can be performed in units of one minute. Even when the scheduled reception time is set to a second such as 2:00:00 am, the hands of the hands 221 and 222 are first moved before reaching the scheduled reception time and starting the receiving operation. If the receiving operation is started from, the hand movement step can be performed in units of one minute.
Also, it has been described that one frame is received for only 55 seconds, but the time for receiving one frame is not particularly limited, and may be, for example, 20 seconds or 30 seconds. Even when all the time information of one frame cannot be obtained by one receiving operation, the time information that could not be obtained last time may be complemented by the next receiving operation.
[0174]
In the fourth embodiment, the third reception electromagnetic conversion coil 72 and the rectifier 58 may be always connected without the fourth switch means 565. This is because an electric signal is hardly emitted from the rectification unit 58 and the secondary battery 491, and noise from the rectification unit 58 is not added to the standard radio wave received by the third reception electromagnetic conversion coil 72.
[0175]
In the fourth embodiment, the description has been given assuming that the external energy is input by the rotation of the winding stem 131. However, the external energy is provided by a rotating weight that rotates by a motion given from the outside or a swinging weight that swings by a movement from the outside. The rotor may be rotated with rotational energy obtained by the movement of the weight or the swing weight.
Alternatively, an induction power may be generated in a reception electromagnetic conversion coil by an electromagnetic induction action from an external commercial power supply, and the induction electromotive force may be stored.
[0176]
In the above embodiment, the time display unit displays the time with the minute hand and the hour hand. However, it goes without saying that the second hand may be provided in addition to the minute hand and the hour hand. Further, the display is not limited to the pointer type, but may be digitally displayed on a liquid crystal or the like.
[0177]
In the above embodiment, the radio-controlled timepiece has been described. However, the present invention is not limited to the radio-controlled timepiece, but can be applied to any electronic device that receives wireless information and performs electromagnetic conversion. Examples of such electronic devices include various electronic devices such as a portable radio, a music box, and a mobile phone. For example, a measurement result of physical characteristics such as atmospheric pressure, gas concentration, voltage, and current may be transmitted as wireless information, and an electronic device that receives the wireless information may drive a pointer with a stepping motor and display the measured value in analog. .
Further, the wireless information is not limited to the time information based on the long-wave standard radio wave. For example, wireless information using FM, GPS, Bluetooth, or a non-contact IC card may be used, and the content of external wireless information such as news and weather forecast is not limited.
[0178]
In the first, second, and third embodiments, an external magnetic field may be detected, and the operation of receiving the standard radio wave and the operation of moving the hands of the hands may be controlled based on the result of the detection of the external magnetic field.
That is, in FIG. 12, the central control circuit 53 includes a magnetic field determination unit 534 that determines the presence of an external magnetic field. The magnetic field determination unit 534 is configured by an induced voltage detection unit in which a threshold for determining a predetermined voltage value is set. The magnetic field determination unit 534, the reception electromagnetic conversion coil 612, and the stator 613 constitute an external magnetic field detection unit that detects an external magnetic field. Alternatively, an external magnetic field detecting unit configured to detect an external magnetic field is configured by the magnetic field determination unit 534, the reception electromagnetic conversion coil 623, and the stator 623.
[0179]
When an external magnetic field is detected in such a configuration, a control signal for causing the driver 541 to output a magnetic field detection pulse is output from the driver control unit 542. Then, the driver 541 turns ON only one pole of each of the reception electromagnetic conversion coils 612 and 622. In this state, when an external magnetic field acts on the reception electromagnetic conversion coils 612 and 622 to induce an induced voltage due to the external magnetic field on the reception electromagnetic conversion coils 612 and 622, the induced voltage is determined by the magnetic field determination unit 534 via the driver 541. Sampled. The magnetic field determination unit 534 detects the presence of an external magnetic field by comparing the value of the induced voltage with a predetermined threshold value.
[0180]
Examples of the external magnetic field include those generated from a source of a high-frequency magnetic field (50 Hz to 60 Hz) such as an electric blanket and an electric kotatsu, and those generated from a source of an AC magnetic field (motor noise) such as an electric shaver and a dryer. Can be considered. The pulse width and period of the magnetic field detection pulse are made to correspond to the external magnetic field to be detected. For example, a continuous control pulse of about 20 ms is applied to a high-frequency magnetic field, and an intermittent chopper pulse is applied to an AC magnetic field. Is exemplified.
[0181]
In the above configuration, the movement of the hands of the hands 221 and 222 may be controlled according to the result of the external magnetic field detection. That is, the external magnetic field is detected before the drive pulse for moving the hands 221 and 222 is applied to the reception electromagnetic conversion coils 612 and 622. At this time, when no external magnetic field is detected, a normal drive pulse is applied to the reception electromagnetic conversion coils 612 and 622 to move the hands 221 and 222. On the other hand, when an external magnetic field is detected, a special drive pulse having a larger effective value than a normal drive pulse is applied to the reception electromagnetic conversion coils 612 and 622 to move the hands 221 and 222. Note that it is desirable to provide rotation detection means for detecting the rotation of the rotors 614, 624, and to detect the rotation of the rotors 614, 624.
[0182]
Further, the receiving operation of the standard radio wave or the processing operation of the received time information may be controlled according to the result of the external magnetic field detection.
That is, the reception control circuit 533 sends an external magnetic field detection command to the driver control unit 542 before starting reception of the standard radio wave. Then, the driver control unit 542 sends a control signal for outputting a magnetic field detection pulse to the driver 541. When the external magnetic field is detected by the magnetic field determination unit 534, the reception control circuit 533 inhibits the reception operation (reception operation is prohibited). In this case, the reception control circuit 533 includes the reception circuit 511, the switch control unit 563, and the driver control. Unit 542 is not instructed to start the receiving operation. When the external magnetic field is no longer detected, the reception control circuit 533 instructs the reception circuit 511, the switch control unit 563, and the driver control unit 563 to start the reception operation (reception operation restart).
[0183]
Alternatively, even when an external magnetic field is detected, the reception operation of the standard radio wave may be performed, and the time information of the standard radio wave received in a state where the external magnetic field is detected may be invalidated (reception information invalidation). That is, the time information received in a state where the external magnetic field is detected is not used for time correction. On the other hand, the time information of the standard radio wave received in a state where the external magnetic field is not detected is validated (reception information validation), and the time is corrected based on the time information.
It is preferable that the resumption of the reception operation and the validation of the reception information be performed after a predetermined time has elapsed since the detection of the external magnetic field is stopped.
[0184]
Alternatively, in a state where the external magnetic field is detected, the preset number of receptions may be invalidated, and the time information frame may be received more than the set number of receptions. Further, a flag is attached to the time information of the standard radio wave received in a state where the external magnetic field is detected, and the time information with the flag is received more than a predetermined number of times, and the success of the reception is more than usual. May also be determined strictly.
[0185]
When performing the operation of receiving the standard radio wave, one of the reception electromagnetic conversion coils 612 and 622 receives the standard radio wave, and the other detects the external magnetic field in addition to the movement of the hands 221 and 222. May be performed.
[0186]
【The invention's effect】
As described above, according to the present invention, an excellent effect of being able to provide a radio-controlled timepiece, an electronic device, and a control method of the radio-controlled timepiece that can be downsized can be provided.
[Brief description of the drawings]
FIG. 1 is a plan view of a first embodiment of a radio-controlled timepiece according to the present invention.
FIG. 2 is a cross-sectional view taken along line II-II in FIG. 1 in the first embodiment.
FIG. 3 is a diagram showing a configuration of a control unit in the first embodiment.
FIG. 4 is a flowchart showing a standard radio wave reception operation and a time correction operation in the first embodiment.
FIG. 5 is a diagram showing a configuration of a control unit in a second embodiment of the radio-controlled timepiece according to the present invention.
FIG. 6 is a flowchart showing a standard radio wave reception operation and a time correction operation in the second embodiment.
FIG. 7 is a flowchart showing a standard radio wave reception operation and a time adjustment operation in the third embodiment of the radio-controlled timepiece of the present invention.
FIG. 8 is a plan view of a radio-controlled timepiece according to a fourth embodiment of the present invention.
FIG. 9 is a diagram showing a configuration of a control unit in the fourth embodiment.
FIG. 10 is a flowchart showing a standard radio wave reception operation and a time correction operation in the fourth embodiment.
FIG. 11 is a diagram showing a modification of the reception electromagnetic conversion coil.
FIG. 12 is a diagram showing a control unit in a configuration having an external magnetic field detection function as a modification of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Exterior case, 2 ... Time display part, 4 ... Movement, 5 ... Control part, 6 ... Reception drive unit, 7 ... Reception power generation unit, 8 ... Reception electromagnetic conversion coil, 13 ... External operation means (external energy input means) 46: Base plate (base frame), 48: Stepping motor, 51: Reception information processing unit, 52: Reference signal generation unit, 53: Central control circuit, 54: Drive control unit, 55: Needle position detection circuit, 56: Switch unit 57, a stop time storage unit (cutting time storage unit), 58, a rectification unit, 59, a power generation detection unit, 72, a reception electromagnetic conversion coil, 73, a power generation rotor, 74, a power generation stator, 100, a radio wave correction clock, 221: minute hand, 222: hour hand, 491: secondary battery (power storage means) 531: current time counter (current time clock means), 532 ... time correction circuit (time correction means), 533 ... reception control circuit, 54 .., Driver 542, driver control section, 561 first switch means, 562 second switch means, 563 switch control section, 564 third switch means, 565 fourth switch means, 612 reception electromagnetic conversion coil 613: reception electromagnetic conversion coil, 614: rotor for minute hand, 622: reception electromagnetic conversion coil, 623: stator for hour hand, 624: rotor for hour hand.

Claims (15)

A receiving electromagnetic conversion coil for performing electromagnetic conversion and receiving a standard radio wave transmitted from the outside,
A reception information processing unit that processes a standard radio wave received by the reception electromagnetic conversion coil,
A current time measuring means for measuring the current time;
Time correction means for correcting the current time of the current time clock means based on the time information of the standard time signal processed by the reception information processing unit,
A time display unit for displaying a current time measured by the current time clock means. The radio-controlled timepiece according to claim 1,
In a state where the standard electromagnetic wave is received by the reception electromagnetic conversion coil, the reception electromagnetic conversion coil and the reception information processing unit are electrically connected, and in a state where the standard electromagnetic wave is not received by the reception electromagnetic conversion coil, the reception electromagnetic conversion coil is used. A radio-controlled timepiece comprising: a first switch for electrically disconnecting the reception information processing unit from the timepiece. The radio-controlled timepiece according to claim 1 or 2,
A drive control unit that applies a drive pulse to the reception electromagnetic conversion coil,
A rotor that is rotated by a magnetic field variation generated by electromagnetic conversion by the reception electromagnetic conversion coil,
The radio-controlled timepiece according to claim 1, wherein the time display unit has a hand that rotates on a dial by rotation of the rotor. The radio-controlled timepiece according to claim 3,
In a state where the reception electromagnetic conversion coil receives the standard radio wave, the reception electromagnetic conversion coil and the drive control unit are electrically disconnected, and in a state where the reception electromagnetic conversion coil does not receive the standard radio wave, the reception electromagnetic conversion coil and A radio-controlled timepiece comprising a second switch for electrically connecting the drive control unit. The radio-controlled timepiece according to claim 4,
A disconnection time storage unit that stores a disconnection time during which the drive control unit and the reception electromagnetic conversion coil are electrically disconnected by the second switch unit;
The drive control unit is configured to control the disconnection time stored in the disconnection time storage unit when the drive control unit and the reception electromagnetic conversion coil are electrically connected after a predetermined disconnection time by the second switch unit. A radio-controlled timepiece characterized in that the drive pulse according to (1) is applied to the reception electromagnetic conversion coil. The radio-controlled timepiece according to claim 4,
Switch control means for controlling the open / close state of the first switch means and the second switch means,
The switch control means, after receiving a predetermined unit of the time information, before receiving a predetermined unit of the next time information, electrically connects the reception electromagnetic conversion coil and the reception information processing unit with the first switch means. Wherein the second switch means electrically connects the drive control section and the reception electromagnetic conversion coil with each other. The radio-controlled timepiece according to any one of claims 1 to 6,
A rotor that is rotated by kinetic energy given from the outside to generate a magnetic field fluctuation,
A radio-controlled timepiece comprising: a power storage unit that stores induced electromotive force generated by electromagnetic conversion of the reception electromagnetic conversion coil from magnetic field fluctuation due to rotation of the rotor. The radio-controlled timepiece according to claim 7,
Power generation detection means for detecting an induced electromotive force generated in the reception electromagnetic conversion coil,
In a state in which the induced electromotive force is detected by the power generation detecting means, the reception electromagnetic conversion coil and the reception information processing section are electrically disconnected, and in a state in which the induced electromotive force is not detected by the power generation detecting means, the reception is performed. A radio-controlled timepiece comprising: a third switch for electrically connecting an electromagnetic conversion coil to the reception information processing unit. The radio-controlled timepiece according to any one of claims 1 to 8,
A radio-controlled timepiece, wherein two or more reception electromagnetic conversion coils are provided, and the coil axes of at least two or more reception electromagnetic conversion coils are arranged in different directions. The radio-controlled timepiece according to any one of claims 1 to 9,
A radio-controlled timepiece wherein two or more reception electromagnetic conversion coils are provided, and at least two or more of the reception electromagnetic conversion coils are connected in series. The radio-controlled timepiece according to any one of claims 1 to 10,
A radio-controlled timepiece, wherein two or more reception electromagnetic conversion coils are provided, and at least two or more of the reception electromagnetic conversion coils are connected in parallel. A method for controlling a radio-controlled timepiece having a reception electromagnetic conversion coil for performing electromagnetic conversion and receiving a standard radio wave transmitted from the outside,
A reception information processing step of processing a standard radio wave received by the reception electromagnetic conversion coil,
A current time clocking process for measuring the current time;
A time correction step of correcting the current time measured in the current time measurement step based on the time information of the standard time signal processed in the reception information processing step,
A time display step of displaying the current time measured in the current time clocking step,
A drive control step of applying a drive pulse to the reception electromagnetic conversion coil in a state where the reception electromagnetic conversion coil does not receive a standard radio wave,
A cutting time storing step of storing a cutting time during which the drive pulse is not applied to the reception electromagnetic conversion coil,
The drive control step includes, when applying the drive pulse to the reception electromagnetic conversion coil after a predetermined disconnection time, the drive pulse corresponding to the disconnection time stored in the disconnection time storage step and the reception electromagnetic conversion coil. A method for controlling a radio-controlled timepiece, characterized in that the clock is applied to a clock. A method for controlling a radio-controlled timepiece having a reception electromagnetic conversion coil for performing electromagnetic conversion and receiving a standard radio wave transmitted from the outside,
A reception information processing step of processing a standard radio wave received by the reception electromagnetic conversion coil,
A current time clocking process for measuring the current time;
A time correction step of correcting the current time measured in the current time measurement step based on the time information of the standard time signal processed in the reception information processing step,
A time display step of displaying the current time measured in the current time clocking step,
A power storage step of storing an induced electromotive force generated by electromagnetic conversion of the reception electromagnetic conversion coil from a magnetic field variation caused by externally applied kinetic energy,
Power generation detection step of detecting an induced electromotive force generated in the reception electromagnetic conversion coil,
The method of controlling a radio-controlled timepiece, wherein the reception information processing step is performed only in a state where the induced electromotive force is not detected in the power generation detection step. A receiving electromagnetic conversion coil for performing electromagnetic conversion and receiving a radio wave transmitted from the outside,
An electronic device comprising: a reception information processing unit that processes a radio wave received by the reception electromagnetic conversion coil; and a drive control unit that applies a drive pulse to the reception electromagnetic conversion coil. A receiving electromagnetic conversion coil for performing electromagnetic conversion and receiving a radio wave transmitted from the outside,
A reception information processing unit that processes a radio wave received by the reception electromagnetic conversion coil, a rotor that is rotated by kinetic energy given from the outside and generates a magnetic field variation,
An electronic device comprising: a power storage unit configured to store an induced electromotive force generated by electromagnetic conversion of the reception electromagnetic conversion coil from a magnetic field variation due to rotation of the rotor.

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