JP2001102094A - Optically charging type secondary cell - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide restriction of the defect of photoelectric conversion sheet during charging operation, in the optically charging type secondary cell including combustible photoelectric conversion sheet. SOLUTION: The optically charging type secondary cell comprises a cylindrical outer circumference wall 51 which can rotate with ease, a cylindrical winding core 2 mounted in the outer circumference wall, a photoelectric conversion sheet 3 being photoelectric conversion device which winds the winding core with the freedom of withdrawal. Battery 4 and control circuit part 5 control the charging and discharging. Also, protruding parts 51b whose sectional shape is triangle in the inner surface of the outer circumference wall 51 and is strip shape entirely are formed in a plurality arrays, perpendicular to the withdrawal direction of photoelectric conversion sheet, and in suitable gaps mutually in the circumference direction of the outer circumference wall 51.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photorechargeable secondary battery configured to charge a storage battery with a photoelectric conversion element.

[0002]

2. Description of the Related Art A photoelectric conversion element is also called a solar cell, and is an element for converting light energy such as sunlight into electric energy. This photoelectric conversion element does not emit carbon dioxide or the like when extracting electric energy from light energy, unlike fossil fuels and the like that have been conventionally used. Further, the photoelectric conversion element can extract electric energy from light energy such as sunlight, which is said to be almost inexhaustible, and thus can generate power semipermanently. Therefore, the photoelectric conversion element, in view of global environmental problems,
It is considered that the usage and scale of use will continue to expand.

However, photoelectric conversion elements often have large temporal variations in light energy such as sunlight, and the electrical energy generated by converting this light energy also has large temporal variations. In many cases, it is not suitable for use as a direct power supply for electrical equipment. Also,
A photoelectric conversion element requires a large light receiving area in order to obtain a predetermined amount of power suitable for use since light energy such as sunlight exists in a spatially sparse state. Therefore, the photoelectric conversion element is used as an auxiliary current of an electric device or for a purpose of once charging a storage battery with converted electrical energy and discharging the storage battery for use.

[0004] On the other hand, electrical equipment has been reduced in size due to recent advances in various processing techniques, and is often regarded as a portable equipment. For this reason, dry batteries, which are portable and convenient and can be easily used, are usually used as power sources for electric appliances.

[0005] Therefore, a photorechargeable secondary battery combining the advantages of the photoelectric conversion element as described above and the convenience of a dry battery is disclosed in, for example, Japanese Patent Application Laid-Open No. 63-314780 (Title of Invention: Battery). It is proposed in Japanese Patent Application Laid-Open No. Hei 2-73675 (title of invention: cylindrical rechargeable solar cell). Such a conventional photo-rechargeable secondary battery is a commonly used electric device by using a photoelectric conversion element as a power generation unit and a storage battery as a charge / discharge unit in a cylindrical standard battery type. Is driven by electric power generated by light energy.

[0006]

However, the conventional light rechargeable secondary battery uses a photoelectric conversion element by effectively utilizing light energy such as sunlight radiated from one direction to the entire outer surface area of the storage battery. Not only is it difficult to receive light, but also because of its structure, the light receiving area of the photoelectric conversion element cannot be provided beyond the outer surface area of the storage battery. For this reason, conventional light-rechargeable secondary batteries have a charging time when charging a storage battery that is too long to be practically used, and furthermore, the photoelectric conversion element may not be able to generate even the power required to charge the storage battery. There was a problem.

The inventors of the present invention have made intensive studies and have found that light energy such as sunlight is normally used by combining a flexible photoelectric conversion element and a storage battery. We have invented a photorechargeable secondary battery that can be used as a power source for electrical equipment, and filed a patent application for this (Japanese Patent Application No. 10-351505).
According to the present invention, the present inventors have realized a photorechargeable secondary battery having practical charging performance and easy to use as a power source of a commonly used electric device.

[0008] By the way, the above-mentioned photo-rechargeable secondary battery requires a flexible photoelectric conversion element (more precisely, a plurality of photoelectric conversion elements formed of a flexible sheet substrate) when charging a storage battery. The photoelectric conversion sheet arranged on the upper side is repeatedly used and stretched to increase the light receiving area. At this time, the photoelectric conversion element receives an external force of repeated stretching. As a result of studying the prototype, the present inventor has found that this external force is caused by friction between the flexible photoelectric conversion element and its sliding system, and must be so large that it cannot be overlooked. Further, it has been found that the photoelectric conversion element is damaged or deteriorated by the external force, the power generation efficiency of the entire element is reduced, and the charging performance is reduced.

Accordingly, an object of the present invention is to provide a photorechargeable secondary battery in which a photoelectric conversion sheet is drawn out of a battery core from a winding core and received by the photoelectric conversion sheet to charge a storage battery. An object of the present invention is to provide a photorechargeable secondary battery capable of improving the durability of a conversion sheet and thereby maintaining high power generation efficiency and charging performance of a photoelectric conversion sheet.

[0010]

A light-rechargeable secondary battery according to the present invention (first invention) is provided with a cylindrical core portion and wound around the core portion so as to be freely drawn out. A flexible photoelectric conversion sheet, a chargeable and dischargeable storage battery, and a control circuit unit for controlling the charge and discharge of the storage battery, with the photoelectric conversion sheet wound around the core, The whole is a light rechargeable secondary battery having a substantially cylindrical shape, and the above-mentioned core portion is provided integrally with an upper flange and a lower flange which are located at both ends thereof and are respectively formed in a substantially circular flat plate shape. A cylindrical outer peripheral wall that covers the photoelectric conversion sheet wound around the core portion and has a drawer hole serving as an outlet for the photoelectric conversion sheet; and the outer peripheral wall includes the upper flange and the lower flange. Supported by rotating white By rotating the outer peripheral wall, the extracted photoelectric conversion sheet is wound around an inner space formed by the winding core and the outer peripheral wall, and an inner peripheral surface of the outer peripheral wall is formed. A photorechargeable secondary battery characterized in that a convex portion is formed on the secondary battery.

Further, the photorechargeable secondary battery according to the present invention (the second invention) may be provided with a cylindrical core portion and wound around the core portion so as to be freely pulled out. A flexible photoelectric conversion sheet, a chargeable / dischargeable storage battery, and a control circuit unit for controlling the charge / discharge of the storage battery are provided. In a state where the photoelectric conversion sheet is wound around the core, the whole is substantially An optically rechargeable secondary battery having a cylindrical shape, wherein the winding core portion is provided with an upper flange and a lower flange formed at substantially both ends thereof and each formed in a substantially circular flat plate shape, The photoelectric conversion sheet wound around the core portion is covered, and a cylindrical outer peripheral wall having a drawer hole serving as an outlet of the photoelectric conversion sheet is provided, and the outer peripheral wall is provided with respect to the upper flange and the lower flange. Rotatably supported and pulled out The obtained photoelectric conversion sheet, by rotating the outer peripheral wall, and configured to be wound around the internal space formed by the core and the outer peripheral wall, of the surface of the photoelectric conversion sheet, A photorechargeable secondary battery, wherein a convex portion is formed on a surface of the outer peripheral wall facing the inner peripheral surface.

In the photorechargeable secondary battery according to the first invention, the operation of pulling out the photoelectric conversion sheet is performed in a state where the surface of the sheet is in contact with the convex portion of the outer peripheral wall, and therefore, the inner peripheral surface of the outer peripheral wall. (Inner surface) without contact. Further, in the photorechargeable secondary battery according to the second invention, the operation is performed in a state where the protrusions of the photoelectric conversion sheet are in contact with the inner surface of the outer peripheral wall, and therefore, the surface of the photoelectric conversion sheet is not in contact with the inner surface of the outer peripheral wall. be able to. For this reason, unlike the conventional photo-rechargeable secondary battery, an excessive force is not generated at the time of the above-mentioned pulling-out operation, so that the breakage of the photoelectric conversion sheet or a shortened life due to this is prevented.
Further, in the sliding state, the frictional force between the photoelectric conversion sheet and the convex portion (the first invention) or the frictional force between the convex portion and the inner surface of the outer peripheral wall (the second invention) is reduced by the conventional light charging. The fact that the frictional force is smaller than the frictional force between the photoelectric conversion sheet and the inner surface of the outer peripheral wall in the type secondary battery also contributes to the prevention of breakage of this sheet. As described above, according to the photorechargeable secondary battery according to the present invention, the problem of the related art, that is, the photoelectric conversion sheet is damaged or deteriorated by the excessive force received from the outer peripheral wall during the drawing operation, and the power generation of the entire sheet is performed. Efficiency is reduced,
As a result, the problem that the charging performance is reduced can be properly solved.

In the photorechargeable secondary battery according to the present invention (the first invention and the second invention), when the photoelectric conversion sheet is wound around the core, a predetermined cylindrical battery standard shape may be obtained. preferable. It is desirable that the storage battery has a discharge voltage of 0.6 V or more and 1.9 V or less. Further, it is preferable that the storage battery is detachable from the core. Further, in the first invention, the photoelectric conversion sheet is
It is preferable that the light receiving surface is inwardly disposed so as to be wound around the winding core portion. In the second invention, the convex portion is formed on a surface opposite to the light receiving surface of the photoelectric conversion sheet. It is preferable that the photoelectric conversion sheet is disposed so as to be wound around the core with the light receiving surface facing inward.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. First Embodiment (First Invention) FIGS. 1A and 1B show a configuration of a photorechargeable secondary battery, in which FIG. 1A is a longitudinal sectional view, and FIG. FIG. FIG. 2 is a perspective view showing a charged state of the photorechargeable secondary battery. FIG. 3 is an enlarged vertical cross-sectional view showing an engagement state between an outer peripheral wall and upper and lower flanges constituting the light rechargeable secondary battery. 4 is a plan view (development view) of the photoelectric conversion sheet, and FIG. 5 is a cross-sectional view taken along line AA of FIG. FIG. 6 is a perspective view showing a state in which the photoelectric conversion sheet of FIG. 4 has been sufficiently drawn out (extended), and FIG. 7 is a transverse sectional view of FIG.

In this photorechargeable secondary battery 1, a photoelectric conversion element 11 (see FIG. 4) is formed on a surface of the photoelectric conversion sheet 3 opposite to a surface facing the inner surface of the outer peripheral wall 51 among both surfaces. On the inner surface of the outer peripheral wall 51, a large number of rows of projections 51b having a triangular cross section and an overall shape of stripes are arranged in a direction perpendicular to the sliding direction of the photoelectric conversion sheet 3 [the direction perpendicular to the plane of FIG. And the outer peripheral wall 51 is formed at appropriate intervals in the circumferential direction.

The light-rechargeable secondary battery 1 has a cylindrical core 2 and a flexible photoelectric conversion sheet 3 wound around the core 2 and disposed so as to be able to be pulled out. When,
A storage battery 4 and a control circuit 5 are provided inside the winding core 2. As shown in FIG. 1, the photorechargeable secondary battery 1 has a cylindrical shape as a whole when the photoelectric conversion sheet 3 is wound around the core 2. In addition, the light rechargeable secondary battery 1
As shown in FIG. 2, the photoelectric conversion sheet 3 is
The storage battery 4 is charged by causing the photoelectric conversion sheet 3 to receive light in a state where the storage battery 4 is extended.

The photoelectric conversion sheet 3 is disposed so that its light receiving surface (the surface of the photoelectric conversion element 11) is inside (opposed to the core 2) in a state of being wound around the core 2. Have been. Therefore, when the photoelectric conversion sheet 3 is pulled out, the sheet-like substrate 10 constituting the photoelectric conversion sheet 3
The surface of (see FIG. 5) slides on the protrusion 51b, but the surface of the photoelectric conversion element 11 does not slide on the protrusion 51b. Thereby, the light rechargeable secondary battery 1
When the photoelectric conversion sheet 3 is wound around the core 2 and used for discharge, the light receiving surface of the photoelectric conversion sheet 3 is not exposed to the outside, and the light receiving surface is damaged and damaged. Can be prevented.

As described above, the photoelectric conversion sheet 3 is wound around the core portion 2 with its light receiving surface inside, but is not limited to such a configuration. If there is no fear of damage to the photo rechargeable battery,
The photoelectric conversion sheet 3 may be provided so as to be wound around the core 2 with its light receiving surface facing outward.

The winding core 2 is formed in a cylindrical shape from a resin material such as ABS resin. Core 2
Is formed slightly longer than the width of the photoelectric conversion sheet 3 wound. Therefore, the light rechargeable secondary battery 1 is
The core 2 can be wound over the entire width of the photoelectric conversion sheet 3. The winding core 2 is provided with an upper flange 6 and a lower flange 7 at both ends thereof.

The upper flange 6 and the lower flange 7 are formed in a substantially circular flat plate shape using the same material as that of the core 2 and are fixed to both ends of the core 2 by fixing means such as an adhesive. I have. The upper flange 6 and the lower flange 7 may be formed integrally with the core 2.

The upper flange 6 and the lower flange 7 are formed such that the diameter thereof is substantially the same as or slightly larger than the diameter of the photoelectric conversion sheet 3 in a state wound around the core 2. Have been. Thereby, the upper flange 6 and the lower flange 7 can protect the side edges of the photoelectric conversion sheet 3 and serve as a guide when the elongated photoelectric conversion sheet 3 is wound around the core 2, The photoelectric conversion sheet 3 can be wound around the winding core 2 without displacement.

The core 2, the upper flange 6 and the lower flange 7 are desirably formed of a material having electrical insulation. Thereby, in the light rechargeable secondary battery 1, the internal wiring and the like are short-circuited through these parts, or the respective parts are electrically short-circuited by contacting, for example, terminals of a battery storage part of an electric device. Can be prevented.

It is desirable that the winding core 2, the upper flange 6 and the lower flange 7 are made of a material having excellent heat insulating properties. Thereby, the light rechargeable secondary battery 1
For example, when exposed to a high temperature such as being left on a dashboard of a car, the temperature of the storage battery 4 housed therein can be prevented from rising and being damaged. Core 2, upper flange 6 and lower flange 7
For the same reason, is preferably colored in a color that does not easily absorb light or heat, such as white.

Further, as shown in FIGS. 1 and 2, the photorechargeable secondary battery according to the present invention has a substantially cylindrical outer peripheral wall 5 having substantially the same diameter as the upper flange 6 and the lower flange 7.
1 is provided. As shown in FIG. 3, the light charging type secondary battery 1 has the upper flange 6 and the lower flange 7, each of which has a side edge portion of the outer peripheral wall 51 rotatable (forward / reverse rotation possible).
Are provided with a groove 6a and a groove 7a. Therefore, in the light rechargeable secondary battery 1, the outer peripheral wall 51
Pivots freely with respect to the winding core 2, the upper flange 6 and the lower flange 7.

As shown in FIGS. 1B and 2, the outer peripheral wall 51 is provided with a slit 51a. The slit 51 a has a width and a thickness sufficient to draw out the photoelectric conversion sheet 3, and is formed in the outer peripheral wall 51. Further, in the light rechargeable secondary battery 1, as shown in FIG. 1B and FIG. 2, the locking portion 3a is formed at the outermost peripheral portion (the leading end in the drawing direction) of the photoelectric conversion sheet 3. . The locking portion 3a is formed to have a sufficient thickness to be joined to the slit 51a when the photoelectric conversion sheet 3 is wound around the core 2. The locking portion 3a has a function of preventing the photoelectric conversion sheet 3 from being completely caught in the outer peripheral wall 51, and also has a function as a handle when pulling out the photoelectric conversion sheet 3.

As described above, in the photorechargeable secondary battery 1, the stripe-shaped projections 51 b having a triangular cross section are formed on the inner surface of the outer peripheral wall 51 in the running direction when the photoelectric conversion sheet 3 is wound and pulled out. (The direction in which the sheet 3 slides on the inner surface). Thereby, the life of the photoelectric conversion sheet 3 is prolonged, and the problem of the related art is solved.

That is, in the conventional photorechargeable secondary battery, the photoelectric conversion sheet 3 rolls up and sticks to the inner surface of the outer peripheral wall 51 to generate an abnormally large static friction force between the photoelectric conversion sheet 3 and the outer peripheral wall 51. However, a large amount of force is required to pull out the photoelectric conversion sheet 3, and a large tensile stress is applied to the photoelectric conversion sheet 3, which may cause damage to the photorechargeable secondary battery or shorten its life. Was.
On the other hand, in the light rechargeable secondary battery 1 of the present invention,
Sliding between (the surface of) the photoelectric conversion sheet 3 and (the inner surface of) the outer peripheral wall 51 is eliminated, and the photoelectric conversion sheet 3 is drawn out while sliding on the convex portion 51b. Is done. Further, the fact that the kinetic frictional force between the photoelectric conversion sheet 3 and the projection 51b during sliding is smaller than the kinetic frictional force between the photoelectric conversion sheet 3 and the outer peripheral wall 51 also increases the life of the photoelectric conversion sheet 3. Contribute.

Note that, instead of the stripe-shaped protrusions 51b, dot-shaped (third embodiment) and other various shapes of protrusions can be formed. In the case of forming stripe-shaped protrusions, the protrusions may be arranged in a direction parallel to the running direction of the photoelectric conversion sheet 3 at the time of drawing (the second embodiment described below), or processing of the protrusions If there is no problem in the performance, the convex portion may be formed in a direction oblique to the traveling direction. Further, the cross-sectional shape of the convex portion 51b is triangular, but may be formed in a rectangular shape (second embodiment described below), a circular shape, or a part of an elliptical shape.

As shown in FIGS. 1 (b) and 2, the light-rechargeable secondary battery 1 is configured such that when the storage battery 4 is charged, the locking portion 3a is pulled out so that the photoelectric conversion sheet 3 is wound around the core portion. Drawn from 2. In addition, the light rechargeable secondary battery 1 rotates the outer peripheral wall 51 with respect to the winding core 2,
The photoelectric conversion sheet 3 can be wound around the core 2.

Accordingly, the photorechargeable secondary battery 1 has the outer peripheral wall 51 having the slit 51a rotatably provided, so that the photoelectric conversion sheet 3 can be easily pulled out and wound up. In addition, since the photorechargeable secondary battery 1 includes the outer peripheral wall 51, the photoelectric conversion sheet 3 is not unraveled when housed in an electric device. Further, the light rechargeable secondary battery 1 has an outer peripheral wall 51.
By protecting the photoelectric conversion sheet 3, it is possible to prevent the photoelectric conversion sheet 3 from being damaged by dust or impact of the external environment, and to prevent the storage battery 4 from being overheated by direct sunlight or the like. can do.
In order to further improve the overheating prevention effect of the storage battery 4,
The outer peripheral wall 51 is desirably colored in a color that is hard to absorb light or heat, such as white.

The upper flange 6 and the lower flange 7 have
Each has a positive terminal 8 and a negative terminal 9.
The positive electrode terminal 8 and the negative electrode terminal 9 are formed of a dielectric material, and are electrically connected to predetermined terminals of the control circuit unit 5 by connection means (not shown).

As shown in FIGS. 4 and 5, the photoelectric conversion sheet 3 is a sheet-like substrate 10 having flexibility and formed in a substantially rectangular sheet shape, and is disposed on the sheet-like substrate 10. It is constituted by a plurality of photoelectric conversion elements 11.
The sheet-shaped substrate 10 is formed of an insulating material such as polyester, for example, and is formed in a sheet shape so as to have flexibility. When the photoelectric conversion sheet 3 is pulled out, the surface of the sheet substrate 10 slides on the projection 51b.

Each of the photoelectric conversion elements 11 is
The first electrode layer 12, the photoelectric conversion layer 13, and the second electrode layer 14 are formed on the respective layers in that order in the form of thin films. Each layer constituting the photoelectric conversion element 11 is, for example,
Various PVD methods typified by sputtering and vapor deposition, or various CVs typified by plasma CVD and MOCVD
It is formed in a thin film shape on the sheet substrate 10 by the method D. The photoelectric conversion element 11 has sufficient flexibility similarly to the on-sheet substrate 10 because each layer is formed in a thin film shape.

In the photoelectric conversion sheet 3, each photoelectric conversion element 1
1 are electrically connected in series with each other, and a positive electrode terminal 12a and a negative electrode terminal 14a are respectively formed on the electrode layers of the photoelectric conversion element 11 located at both ends in the lateral direction.
The positive terminal 12a and the negative terminal 14a are electrically connected to predetermined terminals of the control circuit 5, respectively.

The photoelectric conversion element 11 is configured to receive light such as sunlight from the main surface 11a on the side opposite to the sheet-like substrate 10, that is, on the side facing outward. The first electrode layer 12 and the second electrode layer 14 are formed of a dielectric material, and function as a pair of electrodes with respect to the photoelectric conversion layer 13. The photoelectric conversion layer 13 is formed to include, for example, an amorphous semiconductor thin film typified by an a-Si pin junction structure, and is configured to generate an electromotive force when light such as sunlight enters. It is formed with a film configuration having a photoelectric conversion effect.

The photoelectric conversion layer 13 is made of, for example, p
A pn junction structure formed of a type organic semiconductor and an n-type organic semiconductor such as copper phthalocyanine may be used. Note that the photoelectric conversion layer 13 is not limited to the above-described thin film structure, and may be formed with a film configuration having sufficient flexibility and a photoelectric conversion effect.

The first electrode layer 12 is made of, for example, A
It is desirable to be formed of a metal material such as g, Al, Cr, Ni, Cu or the like so as to have a high reflectance with respect to light received by the photoelectric conversion layer 13. Thereby, the light transmitted through the photoelectric conversion layer 13 is reflected and made incident on the photoelectric conversion layer 13 again, so that the photoelectric conversion efficiency of the photoelectric conversion layer 13 can be improved. Also, the second electrode layer 14
Is preferably formed as a so-called transparent electrode made of a material mainly containing a metal oxide such as SnO ₂ or In ₂ O ₃ . Thereby, the light received by the photoelectric conversion layer 13 can be efficiently transmitted, and the photoelectric conversion efficiency of the photoelectric conversion layer 13 can be improved.

FIGS. 4 and 5 show that each of the first electrode layer 12 and the second electrode layer 14 of the specific photoelectric conversion element 11 has another photoelectric conversion element 11 adjacent thereto. An example in which a plurality of photoelectric conversion elements 11 are configured to share each electrode layer as the second electrode layer 14 and the first electrode layer 12 of FIG. Thus, the photoelectric conversion sheet 3 has a configuration in which adjacent photoelectric conversion elements 11 are electrically connected in series.

In this case, for example, the first electrode layer 12
And the second electrode layer 14 is formed of a material mainly composed of a metal oxide such as SnO ₂ or In ₂ O ₃ as described above, and is formed between the first electrode layer 12 and the sheet-like substrate 10. For example, a light reflection layer (not shown) formed of a metal material or the like may be provided. Thereby, each photoelectric conversion element 11 can receive a sufficient amount of light via the second electrode layer 14, and the photoelectric conversion efficiency can be improved by the light reflecting layer.

In this case, each photoelectric conversion element 11
These are connected by "lines" by electrodes having a length substantially equal to the length in the longitudinal direction. Therefore,
For example, as compared with a case where the photoelectric conversion elements 11 are connected to each other at “points” by, for example, lead wires, the possibility that a connection failure such as disconnection occurs is reduced.

In the photoelectric conversion sheet 3, each photoelectric conversion element 11 is arranged in parallel with the longitudinal direction. That is, the pair of electrode layers of each photoelectric conversion element 11 is disposed so as to be parallel to the longitudinal direction of the photoelectric conversion sheet 3. Thereby, when the photoelectric conversion sheet 3 is extended in order to charge the storage battery, even if a part of the photoelectric conversion element is not sufficiently irradiated with light, the photoelectric conversion sheet can be used. It is possible to prevent the overall power generation efficiency from decreasing.

Further, the photoelectric conversion sheet 3 includes the core 2
It is wound up and stretched freely,
One side, which is the innermost side, is connected and fixed to the winding core 2. In the photoelectric conversion sheet 3, the above-described positive electrode terminal 12a and negative electrode terminal 14a are provided on one side of the innermost peripheral side.

As shown in FIGS. 6 and 7, when the photoelectric conversion sheet 3 is sufficiently stretched, the photoelectric conversion element 11
(A portion closest to the winding core 2) can be sufficiently outside the slit 51a of the outer peripheral wall 51. That is, the end of the photoelectric conversion sheet 3 on the side of the core 2 is not provided with the photoelectric conversion element 11, and is provided in the region 31 where the positive electrode terminal 12 a and the negative electrode terminal 14 a are provided (not including the photoelectric conversion element 11). The seat portion 31).

Thus, in the charging operation, the entire photoelectric conversion element 11 can be received. further,
The photoelectric conversion element 11 can be moved from the inner peripheral side having a large curvature to the outer peripheral side having a small curvature.
1 can reduce fatigue deterioration due to bending. Further, the flexibility of the sheet portion 31 having no photoelectric conversion element can be made higher than that of the portion having the photoelectric conversion element, and the durability of the connection and fixing of the photoelectric conversion sheet 3 to the core 2 can be improved. Can be improved. In this case, the sheet portion 31 can be formed integrally with the photoelectric conversion sheet 3, but can be formed by connecting sheets of the same or different materials as necessary.

Further, as the photoelectric conversion sheet 3, as shown in FIG.
May be employed. The polymer laminate sheet 15 covers the photoelectric conversion sheet 3, more precisely, the light receiving portion (main surface 11 a) of the photoelectric conversion element 11, and this portion has at least light transmittance. In this case, it is preferable that the polymer laminated sheet 15 covers one entire surface of the photoelectric conversion sheet 3, and is formed so as to protrude from an end of the photoelectric conversion sheet 3 to protect the end of the photoelectric conversion sheet 3. Is preferred. It is more preferable to provide the polymer laminate sheet 15 on both the light receiving surface side of the photoelectric conversion sheet 3 and the back side as shown in FIG.

The provision of the polymer laminate sheet 15 allows the flexible photoelectric conversion sheet 3 to be repeatedly extended and used to increase the light receiving area. Damage or deterioration is reduced. Furthermore, since the durability of the photoelectric conversion element 3 against repeated sliding on the surface of the photoelectric conversion element during the repeated stretching operation is improved, the power generation efficiency of the photoelectric conversion element 3 as a whole and, consequently, the charging performance are increased. Can be maintained. If the photoelectric conversion sheet 3 is in a rolled state for a long period of time, it is plastically deformed (has a so-called winding habit), which hinders effective light reception of the photoelectric conversion element 11. The plastic deformation is reduced, and efficient light reception is maintained.

When the polymer laminate sheet 15 is used on the front and back of the photoelectric conversion sheet 3 as described above, it can be made of the same sheet material on the front and back, or can be made of different sheet materials as appropriate. . However, the material of at least the portion covering the light receiving portion (main surface 11a) of the photoelectric conversion element 11 needs to be light transmissive. It is also desirable to use a material having wear resistance and weather resistance to light.

Examples of such materials include halogenated olefins, particularly polymers of fluorinated olefins, or copolymers of these with olefins. Further, an adhesive layer may be provided to fix the polymer laminate sheet 15 made of these materials to the photoelectric conversion sheet 3. As a material of the adhesive layer, a copolymer of ethylene and vinyl acetate is exemplified.

In the present embodiment, the photoelectric conversion sheet 3 is provided so as to be wound around the core 2 with its light receiving surface inside, but is not limited to such a configuration. Instead, for example, when there is little concern about the breakage, the photoelectric conversion sheet 3 may be provided so as to be wound around the core 2 with its light receiving surface outside.

The storage battery 4 is housed in the internal space of the core 2 and is a chargeable / dischargeable secondary battery. Storage battery 4
Specifically, for example, nickel-hydrogen secondary battery, nickel-cadmium secondary battery, nickel-zinc secondary battery,
Zinc-silver oxide secondary batteries, iron-nickel secondary batteries, and the like.

The storage battery 4 is preferably a nickel-hydrogen secondary battery. Thereby, the storage battery 4 can improve the energy density per unit volume, and does not use heavy metals such as lead and cadmium, and has excellent environmental compatibility.

The storage battery 4 may be a standard dry battery having a predetermined battery standard shape. The storage battery 4 is, specifically,
R6 type battery called so-called AA type, R03 type battery called AA type, defined by IEC, JIS, etc.
It may be an R1 type battery called an AA type battery, an R44 type battery called a button type battery, an R1220 type battery, or the like. Thereby, in the light rechargeable secondary battery 1, development and manufacturing costs can be reduced.

However, when the storage battery 4 is viewed from the viewpoint of the storage capacity, it is also desirable that a storage battery component such as an electrolytic solution is directly enclosed in the internal space of the core 2 without using a standard storage battery. Thereby, the storage battery 4 can enclose the storage battery component in a space corresponding to the exterior part of the standard storage battery, and the storage capacity can be increased.

The storage battery 4 may be configured to be detachable from the core 2. Specifically, for example, a configuration may be adopted in which a part of the lower flange 7 can be opened and closed, and the storage battery 4 is inserted into and removed from the winding core 2 from this opening / closing portion. Alternatively, for example, a configuration in which a part of the core part 2 exposed to the outside in a state where the photoelectric conversion sheet 3 is stretched can be freely opened and closed, and the storage battery 4 is attached to and detached from the core part 2 from the opening / closing part. May be.

As a result, in the photorechargeable secondary battery 1, even when the storage battery 4 has been repeatedly charged and discharged and its life has expired, only the storage battery 4 can be replaced. Therefore, the light rechargeable secondary battery 1 does not need to discard other parts having a longer life than the storage battery 4 together with the storage battery 4 whose life has expired, which is desirable from the viewpoint of effective utilization of resources.

In addition, the light rechargeable secondary battery 1
Can be used as a charger for charging the storage battery 4. That is, the storage battery 4 can be charged by the light-rechargeable secondary battery 1, the charged storage battery 4 can be taken out from the light-rechargeable secondary battery 1, and the storage battery 4 can be used as a power source of an electronic device.

Further, the storage battery 4 may use a standard storage battery as described above, and may be detachable from the core 2. In this way, by using a standard storage battery as the storage battery 4 detachably, the light rechargeable secondary battery 1 can
When the storage battery 4 is replaced, the replacement operation can be performed easily and easily. Also in this case, as described above, the light rechargeable secondary battery 1 may be used as a charger for charging the storage battery 4. Thereby, the storage battery 4 having the standard storage battery shape is detachable from the light rechargeable secondary battery 1 and can be easily used for electric equipment using a normal standard battery as a power source.

The storage battery 4 has a discharge voltage of 0.6.
It is desirable that the voltage be V or more and 1.9 V or less. As a result, when the light-rechargeable secondary battery 1 is used for electric equipment using a normal cylindrical standard battery as a power supply, it cannot be operated without satisfying the operating voltage of the electric equipment. In addition, it is possible to prevent the device from being damaged by exceeding the allowable voltage.

As shown in FIG. 1, the control circuit unit 5 is disposed in the internal space of the core 2. The control circuit unit 5
A function selected from a function of rectifying the photoelectric conversion sheet 3 and the storage battery 4, a function of preventing the storage battery 4 from being overcharged by the photoelectric conversion sheet 3, a function of preventing the storage battery 4 from being overdischarged, and the like is provided as appropriate. The control circuit unit 5 can be specifically configured by an electric circuit using a diode, an operational amplifier, or the like, but includes a rectifier circuit, an overcharge prevention circuit, and an overcharge circuit, which are generally used in the electric / electronic field. Since it can be configured by a discharge prevention circuit, detailed description of the circuit configuration is omitted.

The control circuit section 5 has at least four terminals, and these terminals are electrically connected to the positive terminal 12 and the negative terminal 14 of the photoelectric conversion sheet 3 and the positive terminal and the negative terminal of the storage battery 4, respectively. Connected. The control circuit unit 5 functions so that the storage battery 4 can be efficiently charged by the photoelectric conversion sheet 3 and discharged from the storage battery 4 efficiently.

The photorechargeable secondary battery 1 is configured as described above, and has a substantially cylindrical shape as shown in FIG. 2 in a state where the photoelectric conversion sheet 3 is wound around the core 2. . In this state, the light-rechargeable secondary battery 1 can be easily attached to and detached from electric devices as a power source for the electric devices.

The dimensions and the like of each part of the photorechargeable secondary battery 1 may be determined so that the photoelectric conversion sheet 3 has a predetermined cylindrical battery standard shape in a state where the photoelectric conversion sheet 3 is wound around the core 2. desirable. The light rechargeable secondary battery 1 is, for example, a so-called single battery defined by IEC, JIS, or the like.
An R20 type battery called an AA type, an R14 type battery called an AA type, or an R6 type battery called an AA type may be used.

As a result, the light rechargeable secondary battery 1 can be easily used for electrical equipment designed to house and use a normal cylindrical standard battery.
Therefore, in this case, the light rechargeable secondary battery 1 converts the light energy of sunlight into electric energy and stores it, and uses the light energy as a power source for electric equipment using a cylindrical standard battery as is generally used. Can be.

The light rechargeable secondary battery 1 is shown in FIG.
As shown in FIG. 2 and FIG.
The storage battery 4 is charged in a state where the storage battery 4 is extended. At this time, the light rechargeable secondary battery 1 can direct the entire light receiving area of the photoelectric conversion sheet 3 in the light irradiation direction.
The power generation of the photoelectric conversion sheet 3 can be improved. Therefore, the light charging type secondary battery 1 can shorten the charging time for charging the storage battery 4 sufficiently for practical use.

In the light-chargeable secondary battery according to the present invention, the shape, number, storage position, etc. of the storage batteries 4 are not limited. The storage battery 4 is, for example, a light rechargeable secondary battery 1.
May be provided inside and may be supported and fixed by an elastic body such as a coil spring or a leaf spring so as not to be displaced.

Further, the photorechargeable secondary battery according to the present invention
As described above, the innermost side of the photoelectric conversion sheet 3 is not limited to the configuration in which one side of the photoelectric conversion sheet 3 is connected and fixed to the winding core 2. The battery 1 may be detachable. Thus, when the photoelectric conversion sheet 3 is physically or electrically damaged, the photorechargeable secondary battery 1 can be replaced with a normal photoelectric conversion sheet 3 for use. That is, the photorechargeable secondary battery according to the present invention may have a configuration in which the photoelectric conversion sheet 3 is electrically connected to the storage battery 4 at least at the time of charging.

Second Embodiment (First Invention) FIG. 9 is a sectional view showing the structure of a main part of a photorechargeable secondary battery 1. In the secondary battery 1, a large number of convex portions 51b having a rectangular cross section are formed on the inner surface of the outer peripheral wall 51 in a stripe shape parallel to the sliding direction of the photoelectric conversion sheet 3 (the direction perpendicular to the plane of FIG. 9). It is. The configuration of the other parts and the operation and effect thereby are the same as in the first embodiment.

Third Embodiment (Second Invention) FIG. 10 is a cross-sectional view showing a photoelectric conversion sheet 3. Also in this case, similarly to the photorechargeable secondary battery 1 of FIG. 1, when the photoelectric conversion sheet 3 is wound around the core 2, the light receiving surface (photoelectric conversion element 11) is attached to the core 2. The opposite surface (the surface of the sheet-like substrate 10) faces the inner peripheral surface of the outer peripheral wall 51. In the light-chargeable secondary battery 1, a large number of conical convex portions 32 are formed in a dot shape on the surface of the sheet-like substrate 10. As described above, the photoelectric conversion sheet 3 is wound around the core 2 with the light receiving surface inside, but is not limited to such a configuration. If there is no fear of damage to the secondary battery or a decrease in power generation efficiency, the convex portion 32 is formed on the light receiving surface, and the photoelectric conversion sheet 3 is wound around the core 2 with the light receiving surface outside. You may arrange so that it may be.

It should be noted that a hemispherical projection may be formed instead of the conical projection 32. Further, instead of the convex portion, a stripe-shaped convex portion can be formed in parallel with or in a direction perpendicular to the sliding direction of the photoelectric conversion sheet 3. In this case, the cross-sectional shape of the stripe-shaped convex portion may be any one of a rectangle, a triangle, a circle, and an ellipse. Furthermore, when there is no problem in the workability of the projection, the stripe-shaped projection can be formed in a direction oblique to the sliding direction of the photoelectric conversion sheet. By forming the convex portion 32, the same operation and effect as those of the first embodiment can be obtained.

[0070]

As described above, in the photorechargeable secondary battery according to the present invention, a convex portion is formed on the inner surface of the cylindrical outer peripheral wall, and the core is slid while the photoelectric conversion sheet slides on the convex portion. Or to be drawn out of the battery from the portion, or, on both surfaces of the photoelectric conversion sheet, a convex portion is formed on the surface sliding on the cylindrical outer peripheral wall, and the photoelectric conversion sheet is formed on this. The protrusion is pulled out of the battery from the core while sliding the protrusion on the inner surface of the cylindrical outer peripheral wall.

According to the photorechargeable secondary battery of the present invention, the operation of pulling out the photoelectric conversion sheet can be performed without the surface of the sheet coming into contact with the inner surface of the outer peripheral wall. It is possible to prevent the photoelectric conversion sheet from being damaged or shortened in life due to excessive force. Also,
In the sliding state, the frictional force between the photoelectric conversion sheet and the convex portion is smaller than the frictional force between the photoelectric conversion sheet and the outer peripheral wall, and also contributes to the prevention of breakage of the sheet. There is an effect that the power generation efficiency and the charging performance of the photoelectric conversion sheet can be maintained high.

Therefore, according to the photorechargeable secondary battery of the present invention, it is practical to use light energy such as sunlight as a power source for electric equipment, and to prevent environmental pollution due to generation of harmful emissions. And make effective use of global resources.

[Brief description of the drawings]

FIGS. 1A and 1B show a configuration of a photorechargeable secondary battery according to a first embodiment, in which FIG. 1A is a longitudinal sectional view, and FIG. 1B is a transverse sectional view of a state where a photoelectric conversion sheet has begun to be stretched. is there.

FIG. 2 is a perspective view showing a charged state of the photo-chargeable secondary battery of FIG.

FIG. 3 is an enlarged vertical sectional view showing an engagement state between an outer peripheral wall and upper and lower flanges constituting the photorechargeable secondary battery of FIG.

FIG. 4 is a plan view (developed view) of a photoelectric conversion sheet constituting the photorechargeable secondary battery of FIG.

FIG. 5 is a sectional view taken along line AA of FIG. 4;

FIG. 6 is a perspective view showing a state where the photoelectric conversion sheet of FIG. 4 is sufficiently stretched.

FIG. 7 is a cross-sectional view of FIG.

FIG. 8 is a cross-sectional view showing another example of the photoelectric conversion sheet.

FIG. 9 is a cross-sectional view illustrating a main structure of a photorechargeable secondary battery according to a second embodiment.

FIG. 10 is a cross-sectional view illustrating a photoelectric conversion sheet according to a third embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Light rechargeable secondary battery, 2 ... Core part, 3 ... Photoelectric conversion sheet, 3a ... Locking part, 4 ... Storage battery, 5 ... Control circuit part, 6
... upper flange, 6a ... groove, 7 ... lower flange, 7a
... Groove, 8 ... Positive electrode terminal, 9 ... Negative electrode terminal, 10 ... Sheet-like substrate, 11 ... Photoelectric conversion element, 11a ... Main surface, 12 ... First
, Positive electrode terminal, 13 ... photoelectric conversion layer, 14
... second electrode layer, 14a ... negative electrode terminal, 15 ... polymer laminated sheet, 31 ... sheet part without photoelectric conversion element, 32
... convex part, 51 ... outer peripheral wall, 51a ... slit, 51b ... convex part

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tomichi Watanabe 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Inside Sony Corporation (72) Inventor Hiroshi Miyazawa 6-35, Kita-Shinagawa, Shinagawa-ku, Tokyo No. F term in Sony Corporation (reference) 5F051 BA15 BA18 EA01 EA20 GA05 JA17 5G003 AA06 BA01 CB05 FA01 5H030 AA06 AS11 BB07 DD07 5H032 AA10 AS16 HH08

Claims (10)

[Claims] 1. A cylindrical core, a flexible photoelectric conversion sheet wound around the core and disposed so as to be able to be pulled out, a chargeable / dischargeable storage battery, and the storage battery A light-rechargeable secondary battery having a substantially cylindrical shape in a state where the photoelectric conversion sheet is wound around the core, wherein the core is An upper flange and a lower flange, each formed in a substantially circular plate shape and located at both ends thereof, are integrally provided, cover the photoelectric conversion sheet wound around the core, and A cylindrical outer peripheral wall having a drawer hole serving as a sheet outlet is provided, and the outer peripheral wall is rotatably supported by the upper flange and the lower flange, and the drawn photoelectric conversion sheet is moved to the outer periphery. Rotating the wall A light-rechargeable secondary battery characterized by being wound around an inner space formed by the winding core and the outer peripheral wall, and having a convex portion formed on an inner peripheral surface of the outer peripheral wall. . 2. The photorechargeable secondary battery according to claim 1, wherein the photoelectric conversion sheet has a predetermined cylindrical battery standard shape when the photoelectric conversion sheet is wound around the core. 3. The photorechargeable secondary battery according to claim 2, wherein the storage battery has a discharge voltage of 0.6 V or more and 1.9 V or less. 4. The photorechargeable secondary battery according to claim 2, wherein the storage battery is detachable from the core. 5. The photorechargeable secondary battery according to claim 2, wherein the photoelectric conversion sheet is provided so as to be wound around the core with the light receiving surface facing inward. . 6. A cylindrical winding core, a flexible photoelectric conversion sheet wound around the winding core and disposed so as to be freely drawn out, a chargeable / dischargeable storage battery, and the storage battery A light-rechargeable secondary battery having a substantially cylindrical shape in a state where the photoelectric conversion sheet is wound around the core, wherein the core is An upper flange and a lower flange, each formed in a substantially circular plate shape and located at both ends thereof, are integrally provided, cover the photoelectric conversion sheet wound around the core, and A cylindrical outer peripheral wall having a drawer hole serving as a sheet outlet is provided, and the outer peripheral wall is rotatably supported by the upper flange and the lower flange, and the extracted photoelectric conversion sheet is placed on the outer peripheral wall. Rotating By this, it is configured to be wound around the internal space formed by the core and the outer peripheral wall, and the surface of the photoelectric conversion sheet is convex on the surface facing the inner peripheral surface of the outer peripheral wall. A light rechargeable secondary battery characterized by forming a part. 7. The photorechargeable secondary battery according to claim 6, wherein the secondary battery has a predetermined cylindrical battery standard shape when the photoelectric conversion sheet is wound around the core. 8. The photorechargeable secondary battery according to claim 7, wherein the storage battery has a discharge voltage of 0.6 V or more and 1.9 V or less. 9. The light rechargeable secondary battery according to claim 7, wherein the storage battery is detachable from the core. 10. The projection is formed on a surface of the photoelectric conversion sheet opposite to the light receiving surface, and the photoelectric conversion sheet is disposed so as to be wound around the core with the light receiving surface inside. The photorechargeable secondary battery according to claim 7, wherein: