JP2010279201A - Battery device and electronic apparatus including the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a battery device that has a simple structure, can be reduced in size, can efficiently generate power for storage, and to provide electronic apparatus including the battery device. <P>SOLUTION: In a power generating section 20 stored inside a battery case 16, a first electrode 32 including a radial section 34 formed radially from a rotation center section and an electret film 35, namely, a charge holding body, are disposed on a rotary plate 24 that opposes a flat battery substrate 23; meanwhile, a second electrode 36 including a radial section 38 so formed on the battery substrate 23 as to oppose the radial section 34 of the first electrode 32 is disposed on the battery substrate 23; and thus the rotary plate 24 is rotated at a fixed interval to the battery substrate 23, and the rotational energy of the rotary plate 24 is efficiently converted to an electrical energy to be stored at a storage section of a battery section 21. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a battery device having a power generation function and an electronic apparatus including the battery device.

  2. Description of the Related Art Conventionally, a power generation device as described in Patent Document 1 is known as a small power generation device using electrostatic induction. In this power generation device, a fixed substrate on which a plurality of electret electrodes, which are charge holding members for holding charges, are arranged, and a movable substrate on which a plurality of movable electrodes are provided are arranged to face each other, and in this state, external vibration is generated. The movable substrate moves in an arbitrary direction in the plane direction, and the electret electrode and the movable electrode move relative to each other to change the induced charge amount between the electret electrode and the movable electrode to generate power. It is configured as follows.

JP 2008-86190 A

  However, since such a conventional power generation device has a structure that converts relative mechanical kinetic energy between the fixed substrate and the movable substrate into electric energy, the movable substrate with respect to the fixed substrate when subjected to external vibration. In order to move the movable substrate in any direction in the plane direction, it is necessary to hold each of the four sides of the movable substrate with a spring member or the like, and in the plane direction with the movable substrate kept at a fixed interval with respect to the fixed substrate. In order to perform the parallel movement, a guide member for guiding the movable substrate is required, which causes a problem that the structure is complicated and the size cannot be reduced.

  The problem to be solved by the present invention is to provide a battery device that can be reduced in size with a simple structure, and that can efficiently generate and store electricity, and an electronic apparatus including the battery device.

In order to solve the above problems, the present invention includes the following components.
The invention according to claim 1 is a battery device in which a power generation unit and a battery unit are housed in a battery case, wherein the power generation unit rotates in a plane facing the flat surface of the substrate. A member, a first electrode provided with a radiating portion formed radially on the rotating member from a rotation center portion of the rotating member, and formed on the flat substrate so as to face the radiating portion of the first electrode A second electrode provided with the radiating portion, and a charge holding body provided on one of the first electrode and the second electrode, and the battery portion includes the first electrode and the second electrode. A battery device comprising a power storage unit that stores electric charges generated by relative rotation with an electrode.

  According to a second aspect of the present invention, the rotating member includes a small-diameter circular portion, and a semicircular arc portion formed in a substantially semicircular arc shape having a larger diameter than the circular portion on the outer peripheral portion of the small-diameter circular portion. The battery device according to claim 1, wherein the battery device is provided.

The invention according to claim 3 is the battery device according to claim 2, wherein the radiation portion of the first electrode is formed in a substantially semicircular arc shape in the semicircular arc portion of the rotating member. It is.

  The invention according to claim 4 is the battery device according to claim 2, wherein the radiating portion of the first electrode is formed in a circular shape in the small-diameter circular portion of the rotating member. is there.

  According to a fifth aspect of the present invention, there is provided an electronic apparatus characterized in that the battery device according to the first aspect is provided in an apparatus case.

  According to the present invention, since the rotating member rotates by facing the flat surface of the flat substrate by external vibration, the rotating member is rotated at a constant interval with respect to the substrate without using the guide member. In addition, the charge holding body provided on one of the first electrode provided on the rotating member and the second electrode provided on the substrate rotates and moves relative to the other electrode. The mechanical rotational kinetic energy of the member can be efficiently converted into electric energy. For this reason, it is possible to reduce the size with a simple structure and to efficiently generate and store electricity.

1 is an enlarged cross-sectional view showing Embodiment 1 of an electronic wristwatch to which the present invention is applied. It is the expanded sectional view which showed the battery apparatus integrated in the electronic wristwatch of FIG. It is the expanded sectional view which showed the principal part in the battery apparatus of FIG. It is the enlarged plan view which looked at the rotating plate in the battery apparatus of FIG. 2 from upper direction. It is the expanded bottom view which looked at the battery board | substrate in the battery apparatus of FIG. 2 from the downward direction. It is the figure which showed the circuit structure of the battery apparatus incorporated in the electronic wristwatch of FIG. 6 is an enlarged bottom view showing a modification of the second electrode provided on the battery substrate in Embodiment 1. FIG. It is the expanded sectional view which showed the principal part of the battery apparatus in Embodiment 2 of the electronic wristwatch to which this invention is applied. FIG. 9 is an enlarged plan view showing a rotating plate in the battery device of FIG. 8. FIG. 9 is an enlarged bottom view showing a battery substrate in the battery device of FIG. 8. It is the expanded sectional view which showed the principal part of the battery apparatus in Embodiment 3 of the electronic wristwatch to which this invention is applied. FIG. 12 is an enlarged plan view showing a rotating plate in the battery device of FIG. 11. FIG. 12 is an enlarged bottom view showing a battery substrate in the battery device of FIG. 11. It is the expanded sectional view which showed the principal part of the battery apparatus in Embodiment 4 of the electronic wristwatch to which this invention is applied. FIG. 15 is an enlarged plan view showing a rotating plate in the battery device of FIG. 14. FIG. 15 is an enlarged bottom view showing a battery substrate in the battery device of FIG. 14. It is the enlarged plan view which showed the modification of the rotating plate in Embodiment 1-4.

(Embodiment 1)
A first embodiment in which the present invention is applied to an electronic wristwatch will be described below with reference to FIGS.
As shown in FIG. 1, the electronic wristwatch includes a wristwatch case 1. The wristwatch case 1 includes a case main body 2 and a ring-shaped bezel 3 provided on the upper outer periphery of the case main body 2.

As shown in FIG. 1, a watch glass 4 is attached to the upper opening of the watch case 1, that is, the upper opening of the bezel 3 via a packing 4 a, and the lower part of the watch case 1, that is, the case body 2. A back cover 5 is attached to the lower part via a waterproof ring 5a. A watch module 6 is provided in the watch case 1. The timepiece module 6 includes an upper housing 7 and a lower housing 8, and a circuit board 9 is provided between them.

In this case, a dial plate 10 is provided on the upper surface of the upper housing 7 as shown in FIG. A clock movement (not shown) is provided in the upper housing 7. In this timepiece movement, the pointer shaft 11 a protrudes above the dial plate 10, and hands 11 b such as a second hand, a minute hand, and an hour hand are attached to the protruding upper end portion, and the pointer 11 b moves the dial 10 above the dial plate 10. Thus, the time is indicated.

Further, as shown in FIG. 1, the lower housing 8 is provided with a battery housing portion 13 for housing the battery device 12 and an antenna 14. On the lower surface of the lower housing 8, a metal base plate 15 is provided except for portions corresponding to the battery housing portion 13 and the antenna 14. The base plate 15 is provided with a plurality of hook portions 15 a at the peripheral edge thereof, and the plurality of hook portions 15 a are locked to the side surface of the upper housing 7, thereby fixing the upper housing 7 to the lower housing 8. It is configured as follows.

Incidentally, the battery device 12 includes a button-type battery case 16 as shown in FIG. The battery case 16 has a configuration in which a circular opening 17a is provided at the top of a button-shaped case body 17, and an electrode plate 18 is provided in the opening 17a via an insulating member 19. The case body 17 is made of a conductive metal plate and is formed on the positive electrode (+) of the entire battery device 12. The electrode plate 18 is made of a conductive metal plate, and is formed on the negative electrode (−) of the entire battery device 12.

In this case, as shown in FIG. 2, the electrode plate 18 is inserted into the opening 17 a of the case body 17 and exposed to the outside, and the case body 17 at the edge of the opening 17 a of the case body 17. And an attachment flange 18b that is fixed to the inner surface of the first through the insulating member 19. Thereby, the electrode plate 18 is fixed to the main body case 17 without contacting the case main body 17 and conducting.

As shown in FIG. 2, a power generation unit 20 and a battery unit 21 are housed inside the battery case 16. The battery unit 21 is a rechargeable battery or a capacitor having a power storage unit 22 (see FIG. 6) to be described later, the lower outer peripheral surface is formed as a positive electrode (+), and the upper surface is a negative electrode (−). Is formed. As shown in FIG. 2, the battery unit 21 is disposed at the bottom of the battery case 16, and the upper outer periphery is pressed by a protrusion 17 b provided on the case body 17. In this state, the lower outer peripheral surface is The case body 17 is configured to contact and conduct.

On the other hand, as shown in FIG. 2, the power generation unit 20 includes a flat battery substrate 23 provided on the lower surface of the electrode plate 18, and a rotating plate 24 that rotates to face the plane of the battery substrate 23. Yes. In this case, the battery substrate 23 is electrically connected to the case main body 17 by the connecting member 25. Thereby, the battery substrate 23 and the positive electrode (+) of the battery unit 21 are electrically connected to the case body 17 which is the positive electrode (+) of the battery case 16.

The rotating plate 24 is made of a conductive metal, and is positioned below the battery substrate 23 as shown in FIG. It is attached rotatably by. That is, as shown in FIG. 2, the rotating shaft 26 is rotatably attached to a bearing 27 embedded in the electrode plate 18 through a shaft hole 24a provided in the center of the rotating plate 24. A nut 18 a is attached to a portion protruding above 27, so that it is rotatably attached to the electrode plate 18.

As a result, the rotary plate 24 is fastened by the nut 18a being screwed into the rotary shaft 26 inserted into the shaft hole 24a at the center thereof, and tightened by the head 26a of the rotary shaft 26 and the nut 18a. The edge portion of the shaft hole 24 a is pressed against the inner ring portion of the bearing 27, so that the shaft hole 24 a rotates with the rotating shaft 26 at a constant distance from the lower surface of the battery substrate 23. In this case, the rotating plate 24 is the negative electrode (−) of the battery case 16 through the rotating shaft 26 and the bearing 27 because the rotating shaft 26 and the bearing 27 are formed of a conductive metal. It is electrically connected to the electrode plate 18.

Further, the rotating shaft 26 is provided with a leaf spring-like connecting member 28 between the head portion 26 a and the negative electrode (−) on the upper surface of the battery unit 21, and the leaf spring-like connecting member 28 causes the rotating shaft 26 to rotate. It is electrically connected to the negative electrode (−) of the battery unit 21 while being pushed up elastically. As a result, both the rotating plate 24 and the negative electrode (−) of the battery unit 21 are connected to the electrode plate 18 that is the negative electrode (−) of the battery case 16 via the connecting member 28, the rotating shaft 26, and the bearing 27. Electrically connected.

As shown in FIG. 4, the rotating plate 24 includes a small-diameter circular portion 30 and a semicircular arc portion 31 that is larger in diameter than the small-diameter circular portion 30 and is formed in a substantially semicircular arc shape. . The small-diameter circular portion 30 is provided with a shaft hole 24a into which the rotary shaft 26 is inserted at the center thereof. The semicircular arc portion 31 is integrally formed on the outer peripheral portion of the small-diameter circular portion 30 with the weight portion 31a provided on the outer peripheral portion thereof. Thus, the rotating plate 24 is configured to rotate around the rotating shaft 26 by the inertia of the weight portion 31a of the semicircular arc portion 31 when receiving external vibration.

Further, as shown in FIGS. 2 to 4, the first electrode 32 is provided on the upper surface of the rotating plate 24 via an insulating film 33. In this case, as shown in FIGS. 3 and 4, the insulating film 33 is provided over almost the entire upper surface of the semicircular arc portion 31 of the rotating plate 24. The first electrode 32 provided on the insulating film 33 includes radial portions 34 that are formed radially from the shaft hole 24 a that is the rotation center portion of the rotating plate 24.

As shown in FIGS. 3 and 4, the radial portion 34 has a configuration in which a large number of electrode pieces 34 a are radially arranged on the insulating film 33 provided on the semicircular arc portion 31 of the rotating plate 24. ing. That is, in the radial portion 34, a large number of electrode pieces 34a are elongated in the radial direction with a substantially constant width, and the adjacent electrode pieces 34a are arranged with a gap of a constant interval. Further, the radial portion 34 is guided to the side of the insulating film 33 and electrically connected to the rotating plate 24 in a state where a large number of electrode pieces 34a are all connected at the inner peripheral end and the outer peripheral end. Yes.

Thereby, as shown in FIG. 2, the first electrode 32 is electrically connected to the electrode plate 18 that is the negative electrode (−) of the battery case 16 through the rotating plate 24, the rotating shaft 26, and the bearing 27. ing. Further, as shown in FIG. 3, an electret film 35 that is a charge holding member is formed on each electrode piece 34 a in the radial portion 34 of the first electrode 32. The electret film 35 is an insulator having a semi-permanent charge, and is made of a charge holding material such as a fluorocarbon resin or an amorphous fluororesin.

Examples of the charge holding material that can be used as the electret film include polypropylene (PP), polyethylene terephthalate (PET), polyvinyl chloride (PVC), polystyrene (PS), polytetrafluoroethylene (PTFE), and tetrafluoroethylene-perfluoro. Alkyl vinyl ether copolymer (PFA), tetrafluoroethylene-hexafluoropropylene copolymer (FEP), tetrafluoroethylene-ethylene copolymer (ETFE), polyvinylidene fluoride (PVDF), polychlorotrifluoroethylene (PCTFE) ), chlorotrifluoroethylene - ethylene copolymer (ECTFE), and polyvinyl fluoride polymeric charge retaining material such as chloride (PVF) or silicon oxide, (SiO ₂₎ Contact An inorganic charge retaining material such as microcrystalline silicon nitride (SiN).

On the other hand, on the lower surface of the battery substrate 23 facing the rotating plate 24, as shown in FIGS. 2 and 5, a second electrode 36 is provided via an insulating film 37. In this case, as shown in FIG. 3, the insulating film 37 is provided in a semicircular arc shape having the same size as that of the first electrode 32 at a position corresponding to the movement locus on which the first electrode 32 of the rotating plate 24 rotates. The second electrode 36 is provided on the lower surface (the front surface in FIG. 5) of the insulating film 37. The second electrode 36 is made of a conductive metal and includes radial portions 38 that are formed radially from the rotation shaft 26 that is the rotation center portion of the rotating plate 24.

As shown in FIG. 5, the radial portion 38 has a configuration in which a large number of electrode pieces 38a are radially arranged on the insulating film 37 provided on the battery substrate 23 at regular intervals. That is, in the radial portion 38, as in the radial portion 34 of the first electrode 32, a large number of electrode pieces 38a are elongated in the radial direction with a substantially constant width, and the electrode pieces 38a adjacent to each other are formed. They are arranged with gaps at regular intervals.

Further, the radial portion 38 is led to the side of the insulating film 37 in a state in which a large number of electrode pieces 38a are all connected at the inner peripheral end and the outer peripheral end, and as shown in FIG. 23, and is electrically connected to the case body 17 that is the positive electrode (+) of the battery case 16 through the battery substrate 23 and the connection member 25, respectively.

As a result, when the rotating plate 24 rotates and the first electrode 32 provided on the rotating plate 24 rotates relative to the second electrode 36 provided on the battery substrate 23, the power generation unit 20 The electret film 35 formed on the large number of electrode pieces 34a of the first electrode 32 and the large number of electrode pieces 38a of the second electrode 36 move relatively so that the electret film 35 and the second electrode of the first electrode 32 are relatively moved. It is configured to generate electricity by changing the amount of induced charge between them.
That is, when the electret film 35 and the second electrode 36 of the first electrode 32 move relative to each other, the electric charge on the electret film 35 side flows to the opposing second electrode 36 side due to electrostatic induction, thereby generating power. .

Next, the circuit configuration of the battery device 12 will be described with reference to the principle diagram shown in FIG.
In the battery device 12, the first electrode 32 is connected to the first and second rectifiers 40 and 41, and the second electrode 36 is connected to the third and fourth rectifiers 42 and 43. The first rectifier 40 is connected to the positive electrode (+) of the power storage unit 22 of the battery unit 21, the second rectifier 41 is connected to the negative electrode (−) of the power storage unit 22, and the third rectifier 42 is connected to the positive electrode (+) of the power storage unit 22. The fourth rectifier 43 is connected to the negative electrode (−) of the power storage unit 22.

In this case, the first rectifier 40 and the fourth rectifier 43 store electric charge in the power storage unit 22 when the first electrode 32 rotates in one direction (for example, clockwise direction) with respect to the second electrode 36. In this way, the current flow is rectified. The second rectifier 41 and the third rectifier 42 store electric charge in the power storage unit 22 when the first electrode 32 rotates in the reverse direction (for example, counterclockwise direction) with respect to the second electrode 36. In this way, the current flow is rectified.

Next, the case where the electronic wristwatch is used by being attached to the arm will be described.
First, when the electronic wristwatch is lightly shaken while walking while waving an arm, the rotating plate 24 of the power generation unit 20 in the battery device 12 in the electronic wristwatch is a semicircular arc portion provided on the outer peripheral portion of the small-diameter circular portion 30. It rotates by the inertia by 31 weight part 31a. At this time, since the weight portion 31 a is provided on the outer peripheral portion of the semicircular arc portion 31, an inertial force is generated in the rotating plate 24 according to the swing of the arm, and the rotating plate 24 is applied to the battery substrate 23 by this inertial force. Rotate at regular intervals.

At this time, the rotating plate 24 does not necessarily rotate once (360 ° angle rotation), but swings within an angle range corresponding to the inertial force caused by arm swing. For this reason, for example, the rotating plate 24 rotates clockwise by a predetermined angle and then rotates counterclockwise by a predetermined angle. By repeating this operation, the power generation is repeated and stored in the power storage unit 22 of the battery unit 21. At this time, when the rotating plate 24 rotates within an angle range of 180 °, the electret film 35 formed on the many electrode pieces 34a of the first electrode 32 and the many electrode pieces 38a of the second electrode 36 are always Since they move relative to each other in a state of facing each other, power is generated continuously.

That is, when the rotating plate 24 rotates clockwise at an angle within an angular range of 180 °, a large number of electret films 35 and a large number of electrodes of the second electrode 36 formed on the large number of electrode pieces 34 a of the first electrode 32. The pieces 38a move relative to each other, and the amount of induced charges between the many electret films 35 of the first electrode 32 and the many electrode pieces 38a of the second electrode 36 changes. Store in the battery unit 22 of the battery unit 21.

Further, when the rotating plate 24 rotates counterclockwise at an angle within an angle range of 180 °, the electret films 35 and the second electrodes 36 formed on the many electrode pieces 34 a of the first electrode 32 are also many. Of the first electrode 32 and the plurality of electret films 35 of the first electrode 32 and the plurality of electrode pieces 38a of the second electrode 36 change, thereby generating electric power. The electric charge is stored in the power storage unit 22 of the battery unit 21.

On the other hand, when the arm to which the electronic watch is attached is bent and moved quickly in the vertical direction, the rotating plate 24 of the power generation unit 20 in the battery device 12 is a semicircular arc portion 31 provided on the outer peripheral portion of the small-diameter circular portion 30. Are continuously rotated in the same direction (clockwise or counterclockwise) by the inertia of the weight portion 31a.

At this time, the first electrode 32 having a large number of electret films 35 is provided in the semicircular arc portion 31 in a semicircular arc shape, and the second electrode 36 having a large number of electrode pieces 38a is formed in the semicircular arc shape on the battery substrate 23. Therefore, when the rotating plate 24 makes a half rotation (180 ° rotation), the second electrode 36 and a part of the first electrode 32 always face each other, but the next half rotation (180 ° to 360). Angle rotation), the range in which the second electrode 36 and the first electrode 32 face each other is narrow, and there is a position where both the first and second electrodes 32 and 36 do not face each other for a moment.

For this reason, when the rotating plate 24 rotates halfway with the second electrode 36 facing a part of the first electrode 32, the electret film 35 formed on the many electrode pieces 34a of the first electrode 32 and the second electrode A large number of electrode pieces 38a of the electrode 36 move relatively, and the amount of induced charge between the many electret films 35 of the first electrode 32 and the many electrode pieces 38a of the second electrode 36 changes. The electric power is generated and the electric charge is stored in the power storage unit 22 of the battery unit 21.

In the next half rotation (angle rotation of 180 ° to 360 °), since the range in which the second electrode 36 and the first electrode 32 face each other becomes narrow, the multiple electret films 35 of the first electrode 32 and the first electrode 32 The range in which the amount of induced charge between the multiple electrode pieces 38a of the two electrodes 36 changes is narrowed, the amount of power generation is reduced, and when both the first and second electrodes 32, 36 do not face each other for a moment, power generation occurs. I am interrupted. As a result, when the rotating plate 24 continuously rotates in one direction, the first electrode 32 and the second electrode 36 generate power almost continuously except for the moment when the second electrode 36 does not face at all, and the electric charge is stored in the power storage unit 22. To do.

As described above, according to the battery device 12 of the electronic wristwatch, the power generation unit 20 housed in the battery case 16 includes the flat battery substrate 23 and the rotating plate that rotates to face the plane of the battery substrate 23. 24, a first electrode 32 having a radial portion 34 formed radially from the center of rotation of the rotating plate 24, and a radial portion 34 of the first electrode 32. The second electrode 36 provided with the radial portion 38 and the electret film 35 which is a charge holding body provided on the first electrode 32, and the battery portion 21 housed in the battery case 16 is the first electrode Since the power storage unit 22 that stores electric charges generated by the relative rotation between the electret film 35 of the electrode 32 and the second electrode 36 is provided, the entire apparatus can be downsized with a simple structure, and Efficient It can be a power storage and electric.

That is, according to the battery device 12, the rotating plate 24 of the power generation unit 20 is rotated by facing the plane of the battery substrate 23 due to external vibration. The rotating plate 24 can be rotated at a constant interval by the rotating shaft 26. In addition, an electret film 35 as a charge holding member is formed on the first electrode 32 provided on the rotating plate 24, and the electret film 35 of the first electrode 32 and the second electrode 36 provided on the battery substrate 23 are formed. Since it rotates relatively, the mechanical rotational kinetic energy of the rotating plate 24 can be efficiently converted into electric energy. Therefore, the structure is simple, the entire apparatus can be reduced in size, and the power can be generated and stored efficiently.

In this case, the rotating plate 24 includes a circular portion 30 having a small diameter, and a semicircular arc portion 31 having a larger diameter than the circular portion 30 and formed in a substantially semicircular arc shape on the outer peripheral portion of the small diameter circular portion 30. Therefore, when the rotating plate 24 is rotatably attached to the battery substrate 23 by the rotating shaft 26 and receives external vibration, inertia occurs in the semicircular arc portion 31 of the rotating plate 24. Due to this inertia, Since the rotating plate 24 can be rotated at a constant interval with respect to the battery substrate 23, the rotating plate 24 can be favorably rotated according to external vibration.

For example, when an electronic wristwatch is attached to an arm and the arm is shaken while walking, the rotating plate 24 in the power generation unit 20 of the battery device 12 does not necessarily make one rotation (an angle of 360 °), and responds to the inertial force caused by the arm swing. Since the rotating plate 24 swings within an angular range, the rotating plate 24 rotates clockwise at a predetermined angle, and then rotates counterclockwise at a predetermined angle. By repeating this operation, the power storage unit 22 of the battery unit 21 generates power. Can be stored. Also, if the arm to which the electronic wristwatch is attached is bent and moved quickly in the vertical direction, the rotating plate 24 continuously rotates in the same direction (clockwise or counterclockwise) due to its inertial force. Electricity can be generated by rotation, and the electric charge can be stored in the power storage unit 22 of the battery unit 21.

  In the battery device 12, the radial portion 24 of the first electrode 32 has a large number of electrode pieces 34 a arranged in a semicircular arc shape on the semicircular arc portion 31 of the rotating plate 24, and the radial portion of the second electrode 36. 38, the large number of electrode pieces 38a are arranged in a substantially semicircular arc shape on the battery substrate 23, so that the rotating plate 24 does not necessarily rotate once (360 ° angle rotation), and inertial force due to arm swinging. When swinging in a range corresponding to the angle (for example, an angle of 180 °), the multiple electrode pieces 28a of the second electrode 36 are always opposed to the electret film 35 formed on the multiple electrode pieces 34a of the first electrode 32. Since it can be moved relatively in the state of being made, it can generate electric power continuously.

Further, when the rotating plate 24 is continuously rotated according to the inertial force due to the swing of the arm, the radial portion 24 of the first electrode 32 is formed in a semicircular arc shape on the semicircular arc portion 31 of the rotating plate 24. Therefore, when the rotating plate 24 makes a half rotation (180 ° rotation), the second electrode 36 can generate power while facing a part of the first electrode 32, and the next half rotation (180 ° to 360). The range in which the second electrode 36 is opposed to the first electrode 32 is narrowed at the time of the angle rotation (°), the power generation amount is reduced, and both the first and second electrodes 30 and 26 are not opposed to each other for a moment. However, since the power generation is continued except at this time, the power generation can be performed almost continuously when the rotating plate 24 rotates continuously.

Furthermore, according to the battery device 12, the battery unit 21 includes the power storage unit 22 that stores electric charges generated by the relative rotation of the first electrode 32 and the second electrode 36. The electric charge generated between the electret film 35 of the first electrode 32 and the second electrode 36 provided on the battery substrate 23 according to the operation can be stored in the power storage unit 22 in a good and reliable manner. Can be incorporated and used well.

Further, according to the battery device 12, the rotating plate 24 is made of a conductive metal, and the rotation center portion of the rotating plate 24 is rotatably attached to the bearing 27 provided on the electrode plate 18. The negative electrode (−) of the battery unit 21 is electrically connected to the rotating shaft 26 by the connecting member 28, and the first electrode 32 and the power storage unit 22 of the battery unit 21 are connected to each other. 28, the rotating shaft 26, and the rotating plate 24 are electrically connected to each other, and the second electrode 36 and the power storage unit 22 are electrically connected to each other via the connecting member 25 and the battery substrate 23, respectively. Therefore, the first electrode 22 and the power storage unit 22 can be reliably and satisfactorily connected even if the rotating plate 24 rotates about the axis of the rotating shaft 26 by an angle of 360 ° or more with a simple structure. .

In the first embodiment described above, the radial portion 38 of the second electrode 36 provided on the lower surface of the battery substrate 23 is formed in a semicircular arc shape having the same shape and the same size as the radial portion 34 of the first electrode 32. Although the case has been described, the present invention is not limited thereto. For example, as in the modification shown in FIG. 7, the radial portion 46 of the second electrode 45 provided on the lower surface of the battery substrate 23 is rotated by the radial portion 34 of the first electrode 32. You may make it the structure formed in the circular ring shape corresponding on a movement locus | trajectory.

Also in this case, the radial portion 46 may be configured such that a large number of electrode pieces 46a are radially arranged on the insulating film 37 provided on the battery substrate 23 as shown in FIG. If comprised in this way, since the 1st electrode 32 of the rotating plate 24 always rotates and respond | corresponds to the 2nd electrode 45, it can always produce electric power continuously, no matter how the rotating plate 24 rotates. At the same time, power generation can be stabilized according to the rotation speed, and therefore power generation can be performed more efficiently than in the first embodiment.

(Embodiment 2)
Next, a second embodiment of an electronic wristwatch to which the present invention is applied will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected and demonstrated to the same part as Embodiment 1 shown by FIGS.
In this electronic wristwatch, the first electrode 52 and the second electrode 53 of the power generation unit 51 in the battery device 50 are configured differently from those in the first embodiment, and the other configurations are substantially the same as those in the first embodiment.

That is, the battery device 50 has a configuration in which the power generation unit 51 and the battery unit 21 are housed in the battery case 16 as in the first embodiment. The power generation unit 51 includes a battery substrate 23 fixed to the electrode plate 18 of the battery case 16 and a rotating plate 24 that rotates to face the battery substrate 23. As shown in FIG. 9, the rotating plate 24 includes a small-diameter circular portion 30 and a semicircular arc portion 31 having a larger diameter than the small-diameter circular portion 30 and formed in a substantially semicircular arc. The battery substrate 23 is configured to rotate while maintaining a constant interval.

Further, as shown in FIGS. 8 and 9, a first electrode 52 is provided on the upper surface of the rotating plate 24 via an insulating film 54. In this case, the insulating film 54 is provided in a circular shape over substantially the entire upper surface of the circular portion 30 of the rotating plate 24. The first electrode 52 provided on the insulating film 54 includes radial portions 55 that are formed radially from the shaft hole 24 a that is the rotation center portion of the rotating plate 24. As shown in FIG. 9, the radial portion 55 has a configuration in which a large number of electrode pieces 55 a are radially arranged on the insulating film 54 provided on the circular portion 30 of the rotating plate 24 at regular intervals.

That is, in the radial portion 55, a large number of electrode pieces 55a are elongated in the radial direction with a substantially constant width, and the electrode pieces 55a adjacent to each other are arranged with a gap of a constant interval. In addition, the radial portion 55 is guided to the side of the insulating film 54 and electrically connected to the rotating plate 24 in a state in which a large number of electrode pieces 55a are all connected at the inner peripheral end and the outer peripheral end. Yes.

Accordingly, the first electrode 52 is electrically connected to the electrode plate 18 that is the negative electrode (−) of the battery case 16 via the rotating plate 24, the rotating shaft 26, and the bearing 27, as in the first embodiment. Yes. Also in this case, the electret film 35 which is a charge holding body is formed on each electrode piece 55a of the first electrode 52 as in the first embodiment. The electret film 35 is made of the same material as that of the first embodiment.

On the other hand, the second electrode 53 is provided on the lower surface of the battery substrate 23 facing the rotating plate 24 with an insulating film 56 interposed therebetween as shown in FIGS. The insulating film 56 is formed in a circular shape having the same size as the first electrode 52 at a position corresponding to the first electrode 52 of the rotating plate 24, and is formed on the lower surface (the front surface in FIG. 10) of the insulating film 56. The second electrode 53 is provided. Similarly to the first embodiment, the second electrode 53 is made of a conductive metal, and includes circular radial portions 57 that are formed radially from the rotation shaft 26 that is the rotation center portion of the rotating plate 24.

As shown in FIG. 10, the radial portion 57 has a configuration in which a large number of electrode pieces 57 a are radially arranged at a predetermined interval on an insulating film 56 provided in a circular shape on the battery substrate 23. That is, in the radial 57, as in the radial portion 55 of the first electrode 52, a large number of electrode pieces 57a are elongated in the radial direction with a substantially constant width, and the electrode pieces 57a adjacent to each other are constant. They are arranged with gaps between them.

In addition, the radial portion 57 is guided to the side of the insulating film 56 and electrically connected to the battery substrate 23 in a state where a large number of electrode pieces 57a are all connected at the inner peripheral end and the outer peripheral end. In addition, it is electrically connected to the case body 17 that is the positive electrode (+) of the battery case 16 through the battery substrate 23 and the connection member 25.

As a result, in the battery device 50, the rotating plate 24 of the power generation unit 51 rotates, and the first electrode 52 provided on the rotating plate 24 is relative to the second electrode 53 provided on the battery substrate 23. When rotating, the electret film 35 formed on the large number of electrode pieces 55a of the first electrode 52 and the large number of electrode pieces 57a of the second electrode 53 move relatively, so that the large number of electret films of the first electrode 52. The electric charge is generated by changing the amount of induced charges between the electrode pieces 57a of the second electrode 53 and the second electrode 53.

Next, the case where the electronic wristwatch is used by being attached to the arm will be described.
First, when the electronic wristwatch is lightly shaken while walking with the arm swinged, the rotating plate 24 of the power generation unit 51 in the battery device 50 in the electronic wristwatch is in response to the arm swinging as in the first embodiment. Rotate at regular intervals. At this time, the rotating plate 24 does not necessarily rotate once (360 ° angle rotation), but swings within an angle range corresponding to the inertial force caused by arm swing. For this reason, for example, the rotating plate 24 rotates clockwise by a predetermined angle and then rotates counterclockwise by a predetermined angle. By repeating this operation, the power generation is repeated and stored in the power storage unit 22 of the battery unit 21.

That is, when the rotating plate 24 rotates clockwise by a predetermined angle, the electret film 35 formed on the many electrode pieces 55a of the first electrode 52 and the many electrode pieces 57a of the second electrode 53 move relatively. Then, the amount of induced charge between the many electret films 35 of the first electrode 52 and the many electrode pieces 57a of the second electrode 53 changes, so that electric power is generated and stored in the power storage unit 22 of the battery unit 21. To do.

Even when the rotating plate 24 rotates counterclockwise by a predetermined angle, the electret film 35 formed on the multiple electrode pieces 55a of the first electrode 52 and the multiple electrode pieces 57a of the second electrode 53 The amount of induced charge between the multiple electret films 35 of the first electrode 52 and the multiple electrode pieces 57a of the second electrode 53 changes relative to each other, thereby generating electric power and storing the battery unit 21. The unit 22 stores electricity.

On the other hand, when the arm to which the electronic wristwatch is attached is bent and moved quickly in the vertical direction, the rotating plate 24 of the power generation unit 51 is a weight part 31a of the semicircular arc part 31 provided on the outer peripheral part of the small-diameter circular part 30. Rotate continuously in the same direction (clockwise or counterclockwise) due to inertia. At this time, the many electret films 35 of the first electrode 52 and the many electrode pieces 57a of the second electrode 53 always face each other and relatively rotate.

That is, the first electrode 52 having a large number of electret films 35 is provided in a circular shape on the circular portion 30 of the rotating plate 24, and the second electrode 53 having a large number of electrode pieces 57 a is formed on the battery substrate 23. Since the first electrode 52 is provided in a circular shape at a position facing the first electrode 52, a large number of electret films 35 of the first electrode 52 and a large number of electrode pieces 57 a of the second electrode 53 always face each other and relatively rotate. To do. Thereby, since the amount of induced charges between the many electret films 35 of the first electrode 52 and the many electrode pieces 57a of the second electrode 53 is changed, power generation is performed continuously, and the power storage unit 22 of the battery unit 21 is operated. To store electricity.

As described above, according to the battery device 50 of the electronic wrist watch, the same effect as that of the first embodiment is obtained, and the radial portion 55 of the first electrode 52 in the power generation portion 51 is circularly formed in the circular portion 30 of the rotating plate 24. Since the second electrode 53 is formed in a circular shape corresponding to the first electrode 52 on the battery substrate 23, the electret film 35 formed on the multiple electrode pieces 55a of the first electrode 52 and the second electrode 53 are formed. The electrode 53 can be relatively moved in a state of being opposed to the large number of electrode pieces 57a at all times, so that the power generation can be continuously performed according to the rotation of the rotating plate 24 due to the swing of the arm. It is possible to generate power more efficiently than in the first embodiment.

(Embodiment 3)
Next, a third embodiment of an electronic wristwatch to which the present invention is applied will be described with reference to FIGS. In this case, the same reference numerals are given to the same portions as those in the second embodiment shown in FIGS.
In this electronic wristwatch, the first electrode 62 and the second electrode 63 in the power generation unit 61 of the battery device 60 are different from those in the second embodiment, and the other configurations are the same as those in the second embodiment.

That is, the first electrode 62 is provided on the upper surface of the rotating plate 24 via the insulating film 64 as shown in FIGS. The insulating film 64 is provided on almost the entire upper surface of the circular portion 30 and the semicircular arc portion 31 of the rotating plate 24. The first electrode 62 provided on the insulating film 64 includes a radial portion 65 formed radially from the shaft hole 24 a that is the rotation center portion of the rotating plate 24.

As shown in FIG. 12, in the radial portion 65, a large number of electrode pieces 65a are radially arranged on the insulating film 64 provided across the circular portion 30 and the semicircular arc portion 31 of the rotating plate 24 at regular intervals. It has a configuration. That is, in the radial portion 65, a portion of the electrode piece 65a located in the circular portion 30 of the rotating plate 24 is formed in a circular shape, and a portion of the electrode piece 65a located in the semicircular portion 31 of the rotating plate 24 is formed in a semicircular shape. Is formed.

Also in this case, the radial portion 65 has a large number of electrode pieces 65a elongated in the radial direction with a substantially constant width, and the electrode pieces 65a adjacent to each other are arranged with a gap of a constant interval. . The radial portion 65 is guided to the side of the insulating film 64 and electrically connected to the rotating plate 24 in a state where a large number of electrode pieces 65a are all connected at the inner peripheral end and the outer peripheral end. Yes.

Thus, the first electrode 62 is electrically connected to the battery plate 18 that is the negative electrode (−) of the battery case 16 via the rotary plate 24, the rotary shaft 26, and the bearing 27. In addition, on each electrode piece 65a in the radial portion 65 of the first electrode 62, an electret film 35, which is a charge holding body, is formed as in the second embodiment.

On the other hand, on the lower surface (front surface in FIG. 13) of the battery substrate 23 facing the rotating plate 24, a second electrode 63 is provided via an insulating film 66 as shown in FIGS. 11 and 13. The insulating film 66 is provided at a location corresponding to a rotational movement locus on which the first electrode 62 of the rotating plate 24 rotates, that is, a location corresponding to the small-diameter circular portion 30 of the rotating plate 24 and a semicircular arc portion of the rotating plate 24. It is formed in substantially the same shape as the first electrode 62 over both portions corresponding to the rotational movement locus 31.

Similar to the second embodiment, the second electrode 63 provided on the lower surface of the insulating film 66 includes radial portions 67 that are formed radially from the rotation shaft 26 that is the rotation center portion of the rotating plate 24. As shown in FIG. 13, the radial portion 67 has a configuration in which a large number of electrode pieces 67 a are radially arranged on the insulating film 66 provided on the battery substrate 23 at regular intervals. That is, the radial portion 67 includes an electrode piece 67 a corresponding to the small-diameter circular portion 30 of the rotating plate 24 and an electrode piece 67 a corresponding to the semicircular arc portion 31 of the rotating plate 24.

In this case, as shown in FIG. 13, in the radial portion 67, a portion of the electrode piece 67 a corresponding to the semicircular arc portion 31 of the rotating plate 24 is formed in a semicircular arc shape having substantially the same size as the first electrode 62. It is configured. Similarly to the second embodiment, the radial portion 67 is also guided to the side of the insulating film 66 in a state where a large number of electrode pieces 67a are all connected at the inner peripheral end and the outer peripheral end thereof. In addition to being electrically connected, the battery case 23 and the connection member 25 are electrically connected to the case body 17 that is the positive electrode (+) of the battery case 16.

Thereby, in the battery device 60, the rotating plate 24 of the power generation unit 61 rotates, and the first electrode 62 provided on the rotating plate 24 is relative to the second electrode 63 provided on the battery substrate 23. When rotating, the electret film 35 formed on the large number of electrode pieces 65a of the first electrode 62 and the large number of electrode pieces 67a of the second electrode 63 move relatively, and the large number of electret films of the first electrode 62 are moved. When the amount of induced charge between the first electrode 35 and the multiple electrode pieces 67a of the second electrode 63 changes, power is generated and stored in the power storage unit 22 of the battery unit 21.

As described above, also in the battery device 60 of the electronic wristwatch, the radial portion 65 of the first electrode 62 in the power generation unit 61 is formed across the circular portion 30 and the semicircular arc portion 31 of the rotating plate 24, thereby The electret film 35 formed on the large number of electrode pieces 65a of the one electrode 62 can be relatively moved in a state where the electret film 35 is always opposed to the large number of electrode pieces 67a of the second electrode 63. Since electric power can be generated continuously according to the rotation of the plate 24, the electric power can be generated efficiently and stored in the power storage unit 22 of the battery unit 21 as in the first and second embodiments.

That is, a part of the radial part 65 of the first electrode 62 is provided in a circular shape on the small-diameter circular part 30 of the rotary plate 24, and a part of the radial part 67 of the second electrode 63 is a rotary plate. Since it is provided in a circular shape corresponding to 24 small-diameter circular portions 30, as in the second embodiment, it is possible to efficiently generate power and store it in the power storage unit 22 of the battery unit 21.

The other part of the radial portion 65 of the first electrode 62 is provided in a semicircular arc shape in the semicircular arc portion 31 of the rotating plate 24, and the second electrode 63 is the other part of the radial portion 67. Since the part is provided in a semicircular arc shape at a position corresponding to the rotational movement locus of the first electrode 62 of the rotating plate 24, the power is generated and stored in the power storage unit 22 of the battery unit 21 as in the first embodiment. be able to. As a result, it is possible to generate power more efficiently than in the first and second embodiments, and it is possible to store power in the power storage unit 22 of the battery unit 21 better.

(Embodiment 4)
Next, a fourth embodiment of an electronic wristwatch to which the present invention is applied will be described with reference to FIGS. In this case, the same parts as those in the third embodiment shown in FIGS.
In this electronic wristwatch, the first electrode 72 and the second electrode 73 in the power generation unit 71 of the battery device 70 have a configuration slightly different from that in the third embodiment, and the other configurations are the same as those in the third embodiment.

That is, the first electrode 72 is provided on the upper surface of the rotating plate 24 via the insulating film 74 as in the third embodiment. This insulating film 74 is also provided on almost the entire upper surface of the circular portion 30 and the semicircular arc portion 31 of the rotating plate 24. The first electrode 72 provided on the insulating film 74 includes first and second radial portions 75 and 76 that are formed radially from the shaft hole 24 a that is the rotation center portion of the rotating plate 24. As shown in FIG. 15, the first radial portion 75 has a configuration in which a large number of electrode pieces 75a are radially arranged on the insulating film 74 located in the circular portion 30 of the rotating plate 24 at regular intervals.

In addition, as shown in FIG. 15, the second radial portion 76 has a large number of electrode pieces 76 a on the insulating film 74 located on the semicircular arc portion 31 of the rotating plate 24 and a different interval from the electrode pieces 75 a of the first radial portion 75. The configuration is arranged radially. That is, the second radial portion 76 is formed such that a large number of electrode pieces 76 a are wider than the interval between the electrode pieces 75 a of the first radial portion 75.

These first and second radial portions 75 and 76 are formed on the side of the insulating film 74 in a state where the electrode pieces 75a and 76a are all connected at the inner peripheral end and the outer peripheral end, as in the third embodiment. And is electrically connected to the rotating plate 24. Thus, the first electrode 72 is electrically connected to the output electrode plate 18 that is the negative electrode (−) of the battery case 16 via the rotating plate 24, the rotating shaft 26, and the bearing 27. Also in this case, the electret films 35 as charge holding bodies are formed on the electrode pieces 75a and 76a of the first and second radial portions 75 and 76, respectively, as in the third embodiment.

On the other hand, on the lower surface (front surface in FIG. 16) of the battery substrate 23 facing the rotating plate 24, a second electrode 73 is provided via an insulating film 77 as shown in FIGS. 14 and 16. Similarly to the third embodiment, the insulating film 77 also corresponds to a location corresponding to the rotational movement locus on which the first electrode 72 of the rotating plate 24 rotates, that is, a location corresponding to the small-diameter circular portion 30 of the rotating plate 24, and the rotation. The first electrode 72 is formed in substantially the same shape over both of the portions corresponding to the rotational movement locus of the semicircular arc portion 31 of the plate 24.

The second electrode 73 provided on the lower surface of the insulating film 77 is provided with third and fourth radial portions 78 that are formed radially from the rotation shaft 26 that is the rotation center portion of the rotating plate 24, as in the third embodiment. 79. That is, as shown in FIG. 16, the third radial portion 78 is provided in a circular shape corresponding to the first radial portion 75 of the first electrode 72, and the fourth radial portion 79 is provided on the first electrode 72. The second radial portion 76 is provided in a semicircular shape at a location corresponding to the rotational movement locus of the second radial portion 76.

In this case, as shown in FIG. 16, the third radial portion 78 includes a plurality of electrode pieces 78 a on the insulating film 77 provided on the battery substrate 23 and each electrode piece 75 a of the first radial portion 75 of the first electrode 72. The structure is arranged radially at the same interval. In addition, as shown in FIG. 16, the fourth radial portion 79 has a large number of electrode pieces 79 a on the insulating film 77 provided on the battery substrate 23, and the same spacing as each electrode 76 a of the second radial portion 76 of the first electrode 72. The configuration is arranged radially.

That is, the fourth radial portion 79 is formed such that a large number of electrode pieces 79 a are wider than the interval between the electrode pieces 78 a of the third radial portion 78. The electrode pieces 78a and 79a of the third and fourth radial portions 78 and 79 are connected to each other at the inner peripheral end and the outer peripheral end in the same manner as in the third embodiment. To the battery substrate 23 and electrically connected to the case body 17 that is the positive electrode (+) of the battery case 16 through the battery substrate 23 and the connection member 25. .

As a result, in the battery device 70, the rotating plate 24 of the power generation unit 71 rotates, and the first electrode 72 provided on the rotating plate 24 is relative to the second electrode 73 provided on the battery substrate 23. When rotating, the electret films 35 formed on the multiple electrode pieces 75a and 76a of the first and second radial portions 75 and 76 of the first electrode 72 are transferred to the third and fourth of the second electrode 73, respectively. The plurality of electret films 35 of the first and second radial portions 75, 76 of the first electrode 72 move relative to the large number of electrode pieces 78 a, 79 a of the radial portions 78, 79. The two electrodes 73 are configured to generate electric power by changing the amount of induced charges between the multiple electrode pieces 78a and 79a of the third and fourth radial portions 78 and 79 of the two electrodes 73.

As described above, also in the battery device 70 of this electronic wristwatch, the first and second radial portions 75 and 76 of the first electrode 72 are formed by the circular portion 30 and the semicircular arc portion 31 of the rotating plate 24 as in the third embodiment. The electret film 35 formed on the multiple electrode pieces 75 a and 76 a of the first and second radial portions 75 and 76 of the first electrode 72 and the second electrode 73 of the first electrode 72. The plurality of electrode pieces 78a and 79a of the third and fourth radial portions 78 and 79 can be relatively moved, and accordingly, as in the third embodiment, according to the rotation of the rotating plate 24 by the swing of the arm. Power can be continuously generated and stored in the power storage unit 22 of the battery unit 21.

That is, the first radial portion 75 of the first electrode 72 is provided in a circular shape in the small-diameter circular portion 30 of the rotating plate 24, and the third radial portion 78 of the second electrode 73 is the first electrode 72. Since it is provided in a circular shape at the location of the battery substrate 23 corresponding to the first radiation upper portion 75, it is possible to generate electric power in the same manner as in the second embodiment and to store power in the power storage unit 22 of the battery unit 21. .

In addition, the second radial portion 76 of the first electrode 72 is provided in a semicircular arc shape on the semicircular arc portion 31 of the rotating plate 24, and the fourth radial portion 79 of the second electrode 73 is the first electrode 72. Since the second radial portion 76 is provided in a semicircular arc shape at the location of the battery substrate 23 corresponding to the rotational movement trajectory of the second radial portion 76, power generation can be performed in the same manner as in the first embodiment, and the power storage unit 22 of the battery unit 21. Can be charged. Thereby, like Embodiment 3, it can generate electric power more efficiently than Embodiment 1, 2, and can be stored in the electrical storage part 22 of the battery part 21. FIG.

In this case, the interval between the multiple electrode pieces 75a in the first radial portion 75 of the first electrode 72 and the interval between the multiple electrode pieces 78a in the third radial portion 78 of the second electrode 73 correspond to the same interval. Therefore, it is possible to generate electric power at a predetermined frequency, and the distance between the multiple electrode pieces 76a in the second radial portion 76 of the first electrode 72 and the multiple electrode pieces in the fourth radial portion 79 of the second electrode 73. Since the interval 79a is the same interval and is different from the interval between the electrode pieces 75a and 76a of the first and third radial portions 75 and 76, the first and third radial portions 75 and 76 are provided. It is possible to generate power at a frequency different from the frequency generated at

In the above-described first to fourth embodiments and the modifications thereof, the case where the rotating plate 24 is configured to include the small-diameter circular portion 30 and the large-diameter semicircular arc portion 31 is described. For example, as in the modification shown in FIG. 17, the rotary plate 80 may be formed in a circular disc shape, and the weight portion 81 may be provided in the semicircular arc shape on the outer peripheral edge thereof. If comprised in this way, since the 1st electrode 82 can be continuously formed in the circular ring shape on the rotating plate 80, the 1st electrode 82 of the rotating plate 80 is always 2nd electrode 36, 45, 53, 63. , 73 can be rotated in correspondence with each other, so that no matter how the rotating plate 80 rotates, it is possible to continuously generate power and to stabilize power generation according to the rotational speed.

In the above-described first to fourth embodiments and the modifications thereof, the case where the electret film 35 is provided on the first electrodes 32, 52, 62, 72, and 82 has been described, but the first electrodes 32, 52, and 62 are not necessarily provided. 72, 82 need not be provided with the electret film 35, and the electret film 35 may be provided on the second electrodes 36, 45, 53, 63, 73 instead of the first electrodes 32, 52, 62, 72, 82. good. Even if comprised in this way, there exists an effect similar to Embodiment 1-4 and each modification.

In addition, in the above-described first to fourth embodiments and the modifications thereof, a case where the present invention is applied to an electronic wristwatch has been described. The present invention can be widely applied to portable electronic devices.

DESCRIPTION OF SYMBOLS 1 Watch case 6 Watch module 12, 50, 60, 70 Battery device 16 Battery case 17 Case main body 18 Electrode plate 20 Power generation part 21 Battery part 22 Power storage part 23 Battery substrate 24, 80 Rotating plate 26 Rotating shaft 30 Small diameter circular part 31 Large-diameter semicircular arc portion 31a, 81 Weight portion 32, 52, 62, 72, 82 First electrode 33, 37, 54, 56, 64, 66, 74, 77 Insulating film 34, 55, 65 Radiation of first electrode Part 34a, 55a, 65a Electrode piece 35 Electret film 36, 45, 53, 63, 73 Second electrode 38, 46, 57, 67 Radial part of second electrode 38a, 46a, 57a, 67a Electrode piece 75, 76 First Electrode first and second radial portions 75a and 76a Electrode pieces 78 and 79 Third and fourth radial portions 78a and 79a of the second electrode Electrode pieces

Claims (5)

A battery device that houses a power generation unit and a battery unit in a battery case,
The power generation unit
A flat substrate;
A rotating member that rotates to face the plane of the substrate;
A first electrode provided with a radiating portion radially formed from the rotation center of the rotating member on the rotating member;
A second electrode provided with a radiation portion formed on the flat substrate so as to face the radiation portion of the first electrode;
A charge holding body provided on one of the first electrode and the second electrode;
The battery device includes a power storage unit that stores electric charges generated by relative rotation of the first electrode and the second electrode.   The rotating member includes a small-diameter circular portion, and a semicircular arc portion formed in a substantially semicircular arc shape having a larger diameter than the circular portion on an outer peripheral portion of the small-diameter circular portion. Item 2. The battery device according to Item 1.   The battery device according to claim 2, wherein the radiating portion of the first electrode is formed in a substantially semicircular arc shape in the semicircular arc portion of the rotating member.   The battery device according to claim 2, wherein the radiating portion of the first electrode is formed in a circular shape in the small-diameter circular portion of the rotating member. An electronic device comprising the battery device according to claim 1 in a device case.

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