JP2010098271A - Photovoltaic cell using radiation of nuclear waste - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a photovoltaic cell using radiation of nuclear waste, which irradiates a phosphor layer with the radiation of nuclear waste for emitting light which is used for power generation with a solar battery, with its structure being excellent in power generation efficiency. <P>SOLUTION: In the photovoltaic cell using radiation of nuclear waste, a solar battery sheet is wound in multiple layers around a post-like nuclear waste with a glass tube in between, and a phosphor layer is formed on the surface of the solar battery. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a photovoltaic cell using nuclear waste radiation that can efficiently generate high-power generation using the nuclear waste radiation.

Japanese Laid-Open Patent Publication No. 2007-303823 (see Patent Document 1) has proposed power generation using radiation.
In JP 2007-303823 A (see Patent Document 1), when a phosphor is spread on a solar cell and plutonium is positioned thereon, α rays generated from plutonium pass through the phosphor. Fluorescence is generated in the solar cell and power is generated by the solar cell. The plutonium is arranged on both sides of the transparent conductive film, and the phosphor plate solar cells are arranged in order on both sides. It is a thing.
JP 2007-303823 A

By the way, high-level radioactive waste is generally spent fuel. In Japan, it refers to vitrified materials, mainly fission products and transuranium nuclides. The former emits strong radiation and the latter emits radiation for a long time. Release.
These nuclear wastes contain long-lived nuclides with a long half-life (particularly 700 million years for uranium 235 and 4.5 billion years for uranium 238). For the purpose of decaying large amounts of radioactive materials, geological disposal that is buried and disposed deep underground in order to isolate it from the human world after being managed for a certain period of time is being studied mainly in related countries. . And, concrete measures are already under consideration by burying in underground salt layer and abandoned mine site.
In addition, 30-year decay storage management of fission products is expensive, and long-lived nuclides with a long half-life cannot be managed for hundreds of millions of years. The treatment method that burns up is also being studied.

Nonetheless, even if nuclear waste is buried in underground rock salt layers and waste mines, alpha rays generated from plutonium generate fluorescence when passing through the phosphor, and this fluorescence generates power from solar cells. The actual situation is that no consideration is given to secondary use of nuclear waste as disclosed in Japanese Patent Application Laid-Open No. 2007-303823 (see Patent Document 1).

Therefore, the present invention utilizes the fact that nuclear waste emits radiation, irradiates the radiation with a fluorescent layer, emits light, and uses the obtained light to generate power with a solar cell, and its structure is The present invention aims to provide a photovoltaic cell using nuclear waste radiation with very high power generation efficiency.

That is, in the photovoltaic cell using the nuclear waste radiation of the present invention, a solar cell sheet is wound around the columnar nuclear waste in a multilayer manner through a glass tube, and a fluorescent layer is formed on the surface of the solar cell. It is characterized by that.

The photovoltaic cell using nuclear waste radiation according to the present invention is characterized in that the solar cell sheet is formed by mounting a large number of solar cells on a flexible substrate.

The photovoltaic cell using nuclear waste radiation according to the present invention is characterized in that the solar cell sheet is formed by laminating a flexible solar cell on a flexible substrate. It is.

In the photovoltaic cell using the nuclear waste radiation according to the present invention, the fluorescent layer is integrated with the flexible base material by incorporating the fluorescent material into the flexible base material. Another feature is that light is emitted from both the front and back surfaces of the material.

In the photovoltaic cell using nuclear waste radiation according to the present invention, a solar cell sheet is wound around the columnar nuclear waste in a multilayer manner through a glass tube, and a fluorescent layer is formed on the surface of the solar cell. In addition, it is also characterized in that a unit housed in a housing made of a radiation shielding material is one unit, and that each unit can be carried into and out of the installation position.

The principle of power generation of the photovoltaic cell using the nuclear waste radiation of the present invention is considered as follows.
a) Nuclear waste irradiates radiation b) Fluorescent layer emits light c) Fluorescence is applied to the solar cell to give the solar cell a large electromotive force. The used photovoltaic cell is considered to continue to pass current until either the solar cell or the fluorescent layer is deteriorated, and can provide a photovoltaic cell using radiation of nuclear waste having a very long life.

In addition, the present invention has a structure in which a flexible solar cell sheet is wound around a columnar nuclear waste in a multilayer manner, and a fluorescent layer is formed on the surface of the solar cell.
Therefore, the solar cell sheets are stacked in multiple layers around the columnar nuclear waste, and the radiation passes through the layers of the solar cell sheets, so that the solar cells can be arranged at a very high density. Efficiency can be greatly improved.
Of course, the connection method between the solar cells can be appropriately determined according to the required voltage and current generated.

Embodiments of a photovoltaic cell using nuclear waste radiation according to the present invention will be described below in detail with reference to the drawings.
FIG. 1 is a perspective view of a basic structure showing one embodiment of a photovoltaic cell using nuclear waste radiation according to the present invention, FIG. 2 is a developed view of a solar cell sheet, and FIGS. Sectional drawing which shows the example of the solar cell sheet which provided the layer, FIG. 4 is schematic which shows the mechanism for carrying in and carrying out a photovoltaic cell unit to a predetermined position.

As shown in FIG. 1 and FIG. 3, the photovoltaic cell using the nuclear waste radiation of the present invention has a flexible solar cell sheet 21 wound around a rigid glass tube 12 and a columnar shape thereon. The nuclear waste 11 is embedded in the glass tube 12.
As the nuclear waste 11 to which the present invention is applicable, high-level radioactive waste such as spent fuel mainly composed of fission products and transuranium nuclides can be used. These nuclear wastes are used as columnar nuclear waste 11 formed into a columnar shape having a diameter of several tens cm to several m.
As the rigid glass tube 12, it is desirable to use radiation resistant glass having excellent resistance to radiation. As such a radiation resistant glass, a radiation resistant glass manufactured by SCHOTT can be used, and it is said that it contains cerium with very little discoloration or reduced transmittance even when exposed to radiation. Yes. Of course, it is also possible to use glass fiber woven fabrics and nonwoven fabrics made of these materials.
Some transparent quartz glass has excellent radiation resistance.
In any case, it is necessary that the material does not hinder radiation transmission, and it is desirable that the material has excellent radiation resistance.

As shown in FIG. 2, the flexible solar cell sheet 21 has a large number of solar cells 23 mounted on a flexible base material 22 at a predetermined interval.
The flexible base material 22 prevents radiation of PEEK (polyetheretherketone), PVDF (polyvinylidene fluoride), ETFE (tetrafluoroethylene / ethylene copolymer), PBI (polybenzimidazole), etc. In addition, a flexible resin material having excellent radiation resistance can be used.
As the flexible base material 22, radiation resistant glass having excellent radiation resistance can also be used. As such a radiation resistant glass, a radiation resistant glass manufactured by SCHOTT can be used, and it is said that it contains cerium with very little discoloration or reduced transmittance even when exposed to radiation. Yes. Of course, it is also possible to use glass fiber woven fabrics and nonwoven fabrics made of these materials.
Some transparent quartz glass has excellent radiation resistance.
In any case, it is necessary that the material does not hinder radiation transmission, and it is desirable that the material has excellent radiation resistance.

Next, as the solar cell 23, a pn junction type or a dye-sensitized solar cell can be used.
Currently common solar cells have a structure in which p-type and n-type semiconductors are joined. That is, it is a large pn junction type diode (photodiode). Silicon and compound solar cells fall under this category. That is, the energy of light is absorbed into the electron through the reverse process of the light emitting diode (photoexcitation), and the electron having energy is directly taken out as electric power by utilizing the properties of the semiconductor.

In the dye-sensitized solar cell, electrons in the dye adsorbed on titanium dioxide are excited by incident light. The excited electrons are led to an electrode (cathode) through titanium dioxide and taken out as a direct current. The sent-out electrons return to the counter electrode (anode) via an external circuit, and return to the dye adsorbing portion again via ions in the electrolyte sandwiched between the electrodes.
In any case, the solar cell 23 needs to be made of a material that does not interfere with radiation transmission, and is preferably excellent in radiation resistance.

The flexible solar cell sheet 21 may be a unit in which the unit of the solar cell 23 is mounted on a flexible substrate 22 as shown in FIG. If the solar cell 23 in this case is arranged with a narrow width with respect to the winding direction around the glass tube 12, it is not necessary to have anything flexible, and it is made of a hard plate material. It can be.
As the flexible solar cell sheet 21, a laminate of a flexible base material 22 and a flexible solar cell 23 as shown in FIG. 3B can be used.
For example, an amorphous silicon solar cell can form an element with a thin film on an arbitrary substrate. That is, it becomes an ultralight film solar cell having flexibility using a polymer film as a substrate, and the solar cell sheet 21 having flexibility can be obtained by using such a film solar cell. It is.

A fluorescent layer 24 is formed on the solar cell 23. As the fluorescent material, the following materials can be preferably used.
X-ray phosphor (Blue) CaWO ₄
X-ray phosphor (Green) Gd ₂ O ₂ S: Tb
X-ray phosphor (UV) (Y, Sr) TaO ₄ : Nb
For example, a sheet-form molding in which an organic fluorescent pigment or an inorganic fluorescent pigment is blended in a paint material is applied onto the solar cell 23, or the radiation-resistant film material, glass fiber cloth, glass fiber nonwoven fabric, or the like is blended with the pigment. The fluorescent layer 24 can be formed by attaching a product. When the latter is a sheet-like fluorescent layer 24, it can be used as a cushioning material between the solar cell sheets 21.
Incidentally, by using a woven fabric or nonwoven fabric made of glass fiber containing a fluorescent pigment as the flexible base material 22 of the solar cell sheet 21, the flexible base material 22 of the solar cell sheet 21 is used. It can also be used as the fluorescent layer 24.
In the solar cell sheet 21 composed of the flexible base material 22 also serving as the fluorescent layer 24, light can be emitted from both the front and back surfaces of the base material 22, so that a large amount of light can be obtained more efficiently. Therefore, the power generation efficiency can be further increased.
FIGS. 3A and 3B show a flexible base material 22 of the solar cell sheet 21 that also serves as such a fluorescent layer 24.

The flexible solar cell sheet 21 is attached to the columnar nuclear waste 11 as follows.
That is, as shown in FIG. 1, a structure in which the flexible solar cell sheet 21 is wrapped around an outer periphery of a glass tube 12 in advance is prepared, and a columnar nuclear waste is formed inside the glass tube 12. 11 is inserted.
The number of solar cell sheets 21 wound around the glass tube 12 is set to such a thickness that the intensity of radiation emitted from the columnar nuclear waste 11 can generate sufficient visible light to the fluorescent layer 24. Can do. And what is necessary is just to accommodate the whole in the housing 31 which consists of radiation shielding substances, such as lead glass, after having comprised as mentioned above.

A unit in which a columnar nuclear waste 11 is fitted inside the glass tube 12 on which the flexible solar cell sheet 21 is overlapped and accommodated in a housing 31 made of a radiation shielding material. The unit can be carried into and out of the installation position. An example of such a mechanism is shown in FIG.
That is, in FIG. 4, the wire 33 is passed through at least a pair of suspension rings 32 provided at the upper end of the housing 31 and wound up by using a winch 35 that is movably mounted on a rail 34 that is installed, so that each unit is removed from the floor. It can be lifted and carried into a predetermined position or carried out.
Therefore, even when a problem such as stoppage of power generation or leakage of radiation occurs in the photovoltaic cell, the power generation loss can be suppressed in a very short time, and the problem of the photovoltaic cell can be solved safely and promptly.

In the photovoltaic cell using the nuclear waste radiation of the present invention configured as described above, desired power can be obtained by electrically connecting the solar cells 23.
Moreover, the photovoltaic cell using nuclear waste radiation according to the present invention is maintenance-free, can obtain stable power for a very long period of time, and can be operated as a power-free apparatus for a long period of time.

The photovoltaic cell using the nuclear waste radiation according to the present invention can be distributed by making an electrical connection between the solar cells 23 so as to obtain a necessary voltage, and alternating current through an inverter circuit.
Moreover, if it is used for the electrolysis of water with a direct current, it is possible to generate a large amount of hydrogen that is attracting attention as clean energy for various uses.
In addition, when the columnar nuclear waste is buried in an underground rock salt layer or abandoned mine site, if this invention is applied in the facility, the nuclear waste treatment and power generation can be performed simultaneously. It is very effective.
Of course, the power loss associated with power transmission can be minimized by installing the photovoltaic cell using the nuclear waste radiation of the present invention near the place where the power is used.

It is a perspective view of the basic structure which shows one Example of the photovoltaic cell using the radiation of the nuclear waste of this invention. It is an expanded view of a solar cell sheet. (A), (b) is sectional drawing which shows the example of the solar cell sheet which provided the fluorescent layer, respectively. It is the schematic which shows the mechanism for the state which carries in and carries out a photovoltaic cell unit to a predetermined position.

Explanation of symbols

11 Columnar nuclear waste 12 Transparent glass tube 21 Solar cell sheet 22 Flexible base material 23 Solar cell 24 Fluorescent layer 31 Housing 32 Suspension ring 33 Wire 34 Rail 35 Winch

Claims (5)

A photovoltaic cell using nuclear waste radiation, wherein a solar cell sheet is wound around a columnar nuclear waste in a multilayer manner through a glass tube, and a fluorescent layer is formed on the surface of the solar cell. . 2. The photovoltaic cell using the nuclear waste radiation according to claim 1, wherein the solar cell sheet is formed by mounting a large number of solar cells on a flexible base material. 2. The photovoltaic cell using nuclear waste radiation according to claim 1, wherein the solar cell sheet is formed by laminating a flexible solar cell on a flexible substrate. 3. The fluorescent layer contains a fluorescent material in a flexible base material and is integrated with the flexible base material so that light is emitted from both the front and back sides of the flexible base material. A photovoltaic cell using the nuclear waste radiation according to claim 1. A solar cell sheet is wound around the columnar nuclear waste in a multilayered manner via a glass tube, and a fluorescent layer is formed on the surface of the solar cell, and then stored in a housing made of a radiation shielding material. 2. The photovoltaic cell using radiation of nuclear waste according to claim 1, wherein the unit is one unit, and can be carried into and out of the installation position for each unit.

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