JPH03222372A - Solar cell device - Google Patents

Abstract

PURPOSE:To enable a solar cell device to be irradiated with solar rays at a right angle at any place on the sea or the like by a method wherein water is injected into an adequate air chamber out of air chambers in a main body case to form a weight for the main body case, and the angle of inclination of a solar cell module to solar light is adjusted by property choosing the air chambers filled with water. CONSTITUTION:A plate-like amorphous solar cell module 2 subjected to water-proofing so as not to induce an insulation failure is pasted on the side face of a triangular prism-shaped main body case to constitute a solar cell 1, a plurality of partitioned air chambers 3-6 different in size are provided inside the solar cell 1. When the solar cell 1 is made to change in center of gravity by injecting water into the chambers 4-6 out of the air chambers 3-6 or not, the solar cell 1 changes in weight balance to change the angle of inclination of the solar cell module 2 to a water surface 7. In a solar cell 11, where a flexible amorphous solar cell module 12 is pasted on the outer circumferential face of a cylindrical main body case, weight mounting sections 13-15 are provided to the surface of the main body case, and a weight 16 is selectively hung down from the mounting sections, whereby the solar cell 11 is made to change in weight balance. The weight 16 itself can be made to serve as a battery to store electric power.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a solar cell device that is attached to a device such as a buoy that is used while floating on the surface of water or the sea, and serves as a power source for the operation of the device.

(b) Conventional techniques, such as Japanese Patent Application Laid-open No. 1-204892 and Japanese Patent Application Laid-open No. 1983
Publication No. 177747 discloses that a protective film is formed by supplying an electric current to a submerged part of an offshore structure or a net provided under the water surface using a solar cell as a power source. A method for preventing '11 is disclosed.

By the way, these structures position the Xutong solar cell modules parallel to the water surface, and this condition is the same no matter where on the ocean surface on Earth they are installed.

However, since the movement trajectory of the sun, that is, the irradiation angle of sunlight with respect to the sea surface changes depending on latitude, changing the inclination of the solar cell module with respect to the sun in accordance with latitude increases the amount of incident light from the sun. However, there is no known technology that adjusts the dependence of solar cell modules in response to changes in latitude.

(C) Problems to be Solved by the Invention In view of the problems of the prior art described above, the problem to be solved by the present invention is to reduce the inclination of solar cell modules installed on offshore structures, etc. with respect to the solar thinning direction. The objective is to develop a device that can be easily changed to suit the latitude of the country.

(D) The first invention to solve the problem is a prismatic main body case that can be laid flat on a t% surface, and a flat-plate Poet FJA battery that is attached to the outer surface of the main body case. A plurality of air chambers are formed in the main body case, which are divided into ZE-shaped modules, and by selectively injecting water into each of these air chambers, the weight balance of the main body case is changed, and the above-mentioned solar cell The solar cell device is characterized in that the inclination angle of the module with respect to the average water level is made to substantially match the latitude of the point where the main body case is located.

Furthermore, a second invention comprises a cylindrical main body case that can float on the water surface, and a curved solar cell module attached to a part of the convergence surface of the main body case, and the large VA battery module of the main body case The weight balance of the main body case is maintained by forming a plurality of weight attachment parts spaced apart from each other on the circumferential surface excluding the attachment surface, and by providing weights that can be selectively attached to these weight attachment parts. The slope angle of the solar cell module with respect to the average water level is approximately - to the latitude of the point (a) of the main body case.
・This is a solar cell installation that is characterized by:

A third aspect of the invention is a solar cell device, wherein the weight is a storage battery that stores electric power generated by the solar cell module.

(E) Function: By injecting water into an appropriate air chamber of the main body case, the weight of the main body case can be easily formed, and by appropriately selecting the air chamber into which this water is injected, the solar cell The tilt of the module relative to sunlight can be adjusted.

Furthermore, the inclination of the solar cell module with respect to sunlight can be easily adjusted by appropriately attaching a weight to the weight attachment part installed on the outer surface of the main body case.

By using a storage battery as the weight, 1Ih1 of electric power can be effectively generated from solar energy without providing a separate storage pond in the main body case or the like.

(f) Examples The solar cell device of the present invention will be explained in detail below with reference to the drawings.

A first solar cell device is shown in FIGS. 1 to 4. In FIG. 1, (1) is a triangular prism-shaped main body case that is an equilateral triangle with 11 sides on the negative side and 30 cm on a side, and a height of 100 cm in the water direction, and is made of a rust-resistant material such as synthetic resin. One side 4 of this main case is a flat amorphous solar cell module (2) with a size of 20 cm x 60 cm.
Waterproof 9 to prevent insulation failure between each cell! ! ,
II! has been applied and pasted.

Inside the solar cell (1), a plurality of large and small air chambers (3) to (6) are formed which are partitioned from each other. especially(
3) is the large air chamber that obtains the main buoyancy of the main body case (1), and (4> to (6) are the 1st to 3rd small air chambers that obtain the inclination angle of the main body case (1) with respect to the water surface. It is a thing to change.Of these air chambers (3) to (6), (4) to
(6) Depending on whether or not water is injected into the body case (1), the center of gravity of the main body case (1) changes and the weight balance changes;
The inclination of the solar cell module (2> with respect to the water surface (7)) changes.

That is, in Fig. 2, water (seawater) is poured into the empty chamber (6) facing the solar cell module (2), and the solar cell module (2) is parallel to the average water surface (7). .

If such a solar cell device is floated on the sea surface at the equatorial plane F, the efficiency will be improved because sunlight will irradiate it from directly above. This is done by making the angle (θ) between the solar cell module (2) and the water surface (7) parallel, that is, Oo, so that the latitude of the equator is O.

This means that the solar cell module (2) should face a curve or corner with respect to sunlight.

Figure 3 shows an example of installing a solar cell device in a low latitude (30°) area, where water is injected into the air chambers (5) and (6), respectively, and the center of gravity is ) to tilt the solar module (2) by bringing it between
The angle (θ) with respect to the average water surface (7) is 30°. As a result, in an area with a latitude of 30", the angle at which sunlight hits the water surface is 60 degrees, so the module (
By tilting 2) by 30' with respect to the water surface (7),
Sunlight irradiates the module (2) at right angles.

Historically, the one shown in Figure 1 shows an example of installing a solar cell device in a high latitude (60") area, and the air chamber (4)
Inject water into each of the air chambers (6) to center the gravity between these air chambers (4).
(6'), the inclination angle (θ) of the solar cell module (2) with respect to the average water surface (7) is set to 6
0". In an area with a latitude of 60 degrees, the angle of irradiation to the water surface (7) in the section called rental is 30 degrees, so the module (2) should be tilted 60 degrees with respect to the water surface (7). As a result, sunlight is irradiated at right angles to the module (2).

In addition, when installing a solar cell device in a place other than the latitude region mentioned above, the desired solar cell module (2) can be obtained by finely adjusting the amount of water injected into each air chamber (4) to (6). It is possible to obtain the slope of

Next, a second solar cell device is shown in FIGS. 5 to 8. Fifth
In the figure, (11) has a diameter of 30 cm on the top and bottom and a height of 100 cm.
It has a plastic cylindrical body with a diameter of 1.5 cm and is made of a rust-resistant material such as synthetic resin, and is hollow inside so that it can float on the water surface. A part of the circumferential side of this main case (1) has a diameter of 20 cm x 80 cm.
A flexible amorphous solar cell module (12) with a size of 100 to 100 cm is waterproofed and attached to each cell to prevent insulation failure between them.

In this solar cell device, weight mounting parts (13) to (15) are installed at multiple locations on the surface of the main body (11), and the mounting part (15) is located at the center (0) of the main body case (11). The mounting portions (14) and (13) are installed in order at positions facing the module (12), and the mounting portions (14) and (13) are sequentially installed at positions 30” apart from the mounting portion (15) in the central angle. Selectively double pyramid (16) in parts (13) to (15)
It can be installed by hooking it on.

Figures 6 to 8 show examples of the installation of solar cell devices corresponding to Figures 2 to 4, and the weight (16) is placed in a position facing the module (12) as shown in Figure 6. A certain mounting part (
15), the plane (17) including both edges of the module (12) and the water surface (7) form an r degree (V- line) suitable for installation at the equator,
As shown in Figure 7, by attaching the weight (16) to the mounting part (14), the angle between the 7 planes (17) and the water surface (7) is set to 30 degrees, and the device is installed in an area with a latitude of 30 degrees. By attaching the weight (16) to the mounting part (13) as shown in Figure 8, the angle between the plane (17) and the water surface (7) is set to 60°, and the latitude is 60°. The orientation is suitable for installation in areas of °.

Furthermore, although not shown in the drawings, in other embodiments, magnetic bodies are attached to appropriate positions in place of the attachment parts (13) to (15) of the embodiments shown in FIGS. 5 to 8, and a magnet 7 is attached to the weight (16). ) It is also possible to provide a degree of freedom in the mounting position of the weight (16) by using a material that can be magnetically attracted to the magnetic body.

In general, solar cells are often used in conjunction with storage batteries so that the generated power can be stored during the day and the stored power can be used at night. If the electric power generated in the module (12) is stored using the white body of the weight (16) as a storage battery, there is no need to prepare a separate storage battery.

(g) Effects of the Invention As explained above, the present invention can change the inclination of the solar cell module of the solar cell device with respect to sunlight using a weight, so that it can be used at any location such as on the sea. Even when installed, the module can always be irradiated with sunlight at a nearly right angle, and the effect of making it possible to obtain the maximum amount of t-air energy can be expected.

[Brief explanation of drawings]

FIG. 1 is an external perspective view showing one embodiment of the solar cell device of the present invention, and FIGS. 2 to 4 are diagrams showing the inclination of the solar cell module according to changes in the installation location of the solar cell device in FIG. 1. , Fig. 5 is an external perspective view showing an example of another solar cell device corresponding to Fig. 1, and Figs. 6 to 8 show solar cells according to changes in the installation location of the solar cell device shown in Fig. 5. It is a figure which shows the inclination of a module. (1)(11)...Main body, (2)(12)...Solar cell module, (3)-(6
)...Empty L room, (7)-Water surface, (13)-(15)-Dian weight attachment part, (!6)--Weight, (17)-Plane.

Claims (3)

[Claims] (1) Consisting of a prismatic main body case that can float on the water surface and a flat solar cell module attached to the outer surface of the main body case, a plurality of mutually partitioned air chambers are formed in the main body case. By selectively injecting water into each of these air chambers, the weight balance of the main body case is changed, and the inclination angle of the solar cell module with respect to the average water surface is made to approximately match the latitude of the point where the main body case is located. Features of the solar cell device. (2) Consisting of a cylindrical main body case that can float on the water surface and a curved solar cell module attached to a part of the circumferential side of the main body case, the circumferential surface of the main body case excluding the solar cell module mounting surface A plurality of weight attachment parts are formed at intervals from each other on the side surface, and weights that can be selectively attached to these weight attachment parts are provided, and the weight balance of the main body case is adjusted by the attachment positions of these weights. A solar cell device characterized in that the angle of inclination of the solar cell module with respect to an average water surface is made to substantially match the latitude of a point where the main body case is located. (3) The solar cell device according to claim 2, wherein the weight is a storage battery that stores electric power generated by the solar cell module.