KR102290423B1 - Coating type solar light reflecting system - Google Patents

Abstract

Coating type solar reflection system according to the present invention,
double-sided light-receiving solar cell module;
a frame for arranging the double-sided light-receiving solar cell module on the upper side of the hard surface; and
It is located on the rear side of the double-sided light-receiving type solar cell module, and includes a reflective layer formed by coating on the hard surface,
The reflective layer avoids the double-sided light-receiving solar cell module and directly enters the hard side, or passes through the double-sided light-receiving solar cell module and enters the hard side of the sunlight, 80% or more of the sunlight in the 380 to 1100 nm wavelength range , characterized in that diffuse reflection to the rear side of the double-sided light-receiving solar cell module.

Description

Coating type solar light reflection system {COATING TYPE SOLAR LIGHT REFLECTING SYSTEM}

The present invention relates to a solar reflection system.

In general, a solar module receives light only from the front side to generate power, so there is a limit to the increase in the amount of power generation. Recently, a double-sided light-receiving solar cell capable of generating power by receiving light from both front and back surfaces has been developed.

Korean Patent Laid-Open Publication (10-2018-0002015) discloses a backsheet for a solar module for increasing the amount of power generation of a double-sided light-receiving solar cell.

However, no matter how excellent the backsheet for a photovoltaic module is, the amount of power generation of the double-sided light-receiving solar cell is inevitably different depending on the state of the floor where sunlight is reflected.

For example, if the floor is soil, if the floor is covered with concrete, if the floor is painted white, if snow has accumulated on the floor, if the floor is wet, if the floor is dry, etc. must vary greatly.

In addition, in order to use the photovoltaic module backsheet, there is a problem in that all of the already installed double-sided light-receiving solar cells need to be replaced with the double-sided light-receiving solar cells described in Korean Patent Application Laid-Open (10-2018-0002015).

In order to solve this problem, the present applicant has developed and applied for a solar reflection system that increases the amount of power generation by 30% or more by laying a high reflective film on the bottom surface of the rear side of the double-sided light-receiving type solar cell module. (Application No.: 10 -2018-0016957)

Furthermore, it is intended to develop a coating-type solar reflection system that can be installed in any place with a hard surface for such a solar reflection system.

Korean Patent Publication (10-2018-0002015)

It is an object of the present invention to provide a coating type solar reflection system that can be installed anywhere as long as there is a hard surface.

Coating-type solar reflection system for achieving the above object,

double-sided light-receiving solar cell module;

a frame for arranging the double-sided light-receiving solar cell module on the upper side of the hard surface; and

It is located on the rear side of the double-sided light-receiving type solar cell module, and includes a reflective layer formed by coating on the hard surface,

The reflective layer avoids the double-sided light-receiving solar cell module and enters directly into the hard surface, or passes through the double-sided light-receiving solar cell module and enters the hard surface, 80% or more of sunlight in the 380 to 1100 nm wavelength range , characterized in that diffuse reflection to the rear side of the double-sided light-receiving solar cell module.

The reflective layer of the present invention is formed by coating on a hard surface. Therefore, as long as there is a hard surface, the solar reflection system can be installed anywhere, and the installation area of the solar reflection system can be expanded compared to when a reflection film is used.

The reflective layer of the present invention includes glass beads sprinkled on the surface. For this reason, the surface strength of a reflective layer becomes high, and it is prevented that a reflective layer comes off. In addition, the diffuse reflectance of sunlight is increased due to the glass beads, and the power generation efficiency of the solar reflection system is increased.

The reflective layer of the present invention is composed of two layers of an upper reflective layer and a lower reflective layer. For this reason, _{when a water-based paint containing titanium oxide (TiO 2} ) is applied to a hard surface, the surface is hardened first and the inside is hardened later, thereby preventing cracks from occurring. Here, the lower the amount of titanium oxide (TiO ₂₎ of the upper reflective layer to increase than the amount of titanium oxide (TiO ₂₎ of the reflective layer, it is possible to increase the power generation efficiency of the solar reflection system.

1 is a view showing a coating-type solar reflection system according to an embodiment of the present invention.
2 is a view for explaining the relationship between the height and the upper surface length of the double-sided light-receiving solar cell module and the distance relationship between the double-sided light-receiving solar cell module.
FIG. 3 is a view showing a state in which both-side light-receiving solar cell modules are vertically arranged. FIG. 3 (a) is a view viewed from the front, and FIG.
FIG. 4 is a view showing a reflective layer formed on the hard surface shown in FIG. 1 .
5 is a view showing a reflective layer including glass beads on the surface according to the first modification.
6 is a view showing a reflective layer composed of two layers according to a second modification.
7 is a view showing a state in which the reflective layer of the application-type solar reflection system according to an embodiment of the present invention is formed on the bottom surface of the water tank.
8 is a view showing a state in which the reflective layer of the application-type solar reflection system according to an embodiment of the present invention is formed on an inclined surface.

Hereinafter, a coating-type solar reflection system according to an embodiment of the present invention will be described in detail.

As shown in FIG. 1 , the application-type solar reflection system 1 according to an embodiment of the present invention includes a double-sided light-receiving solar cell module M, a frame F, and a reflection layer 10 .

The double-sided light-receiving solar cell module (M) can be configured by a known technology, and the double-sided light-receiving solar cell module (M) configuration itself is not the gist of the present invention, and thus a description thereof will be omitted.

The frame (F) arranges the double-sided light-receiving solar cell module (M) to be inclined on the upper side of the hard surface (R). Here, the hard surface R is a concept including all solid surfaces such as a concrete road surface, an asphalt road surface, a tank bottom, and a rock in a mountainous area.

The frame (F) is a first frame (F1) supporting the edge of the double-sided light-receiving solar cell module (M), a second frame (F2) fixing the frame (F) to a hard surface (R), a second frame ( It consists of a third frame (F3) for reinforcing F2).

The present invention puts the second frame (F2) fixed to the hard surface (R) at least (4 to 6), avoiding the double-sided light-receiving solar cell modules (M) and the lower hard side (R) of the frame (F) ) to prevent the sunlight L2 directly entering the second frame F2 from being caught.

In the present invention, in order to reinforce the minimum second frame F2, the side surfaces of the second frames F2 are connected to the third frame F3.

The first frame (F1) supports the double-sided light-receiving solar cell modules (M) to receive sunlight well, inclined upward at 20° to 45°.

The number of the double-sided light-receiving solar cell modules (M) supported in the upward direction by the first frame (F1) is a maximum of four. The reason is that, even if the number in the upward direction is more than four, the sunlight L3 reaching the rear of the top fifth double-sided light-receiving solar cell module (M) is small, so the rear surface of the double-sided light-receiving solar cell module (M) power is no longer increased. Therefore, the number of upwards is preferably four at most. On the other hand, the number of the double-sided light-receiving solar cell module (M) supported by the first frame (F1) in the width direction is not limited.

According to the upward number of the double-sided light-receiving solar cell module (M), the lowermost height (H) of the hard side (R) and the double-sided light-receiving solar cell module (M) is adjusted to 0.5 to 3m.

The reason is that, in order to avoid the double-sided light-receiving solar cell modules (M) and direct sunlight (L2) to the lower hard surface (R) of the frame (F), a minimum height (H) is required.

For example, if the upward number of the double-sided light-receiving solar cell module (M) is one, the height of the lowermost end of the hard side (R) and the double-sided light-receiving solar cell module (M) is 0.5 m is sufficient.

However, if the upward number of the double-sided light-receiving solar cell module (M) is 4, the bottom height of the hard side (R) and the double-sided light-receiving solar cell module (M) must be 3m, and both sides light receiving at the top The sunlight L2 may be reflected up to the rear surface of the solar cell module M.

As shown in FIG. 2 , the distance D between the double-sided light-receiving solar cell modules M is equal to or greater than 1/3 of the vertical length HL of the double-sided light-receiving solar cell module M.

The distance (D) between the double-sided light-receiving solar cell modules (M) should be at this level, so that the sunlight (L2) enters directly into the hard side (R) through between the double-sided light-receiving solar cell modules (M). can

As shown in FIG. 3( a ), in order to make the most of a narrow space, the double-sided light-receiving solar cell modules M may be vertically disposed. As shown in Fig. 3(b), the double-sided light-receiving solar cell modules (M) are arranged at regular intervals in the front, rear, left and right, and receive the maximum amount of light from the sun moving from the east to the south through the west during the daytime.

The reflective layer 10 shown in FIG. 1 is formed by being coated on the hard surface R. Due to this, the installation area of the solar reflective system can be expanded anywhere there is a hard surface, such as on an abandoned concrete road, on an abandoned asphalt road, on an abandoned building in a redevelopment area, or in a mountainous area with rocks.

The reflective layer 10 avoids the double-sided light-receiving solar cell modules (M) and enters directly into the lower hard side (R) of the frame (F), or passes through the double-sided light-receiving solar cell module (M) to the hard side (R) Among the sunlight (L1, L2) that enters through, 80% or more of the sunlight (L3) in the 380 to 1100 nm wavelength band is reflected to the rear side of the double-sided light-receiving type solar cell module (M), and the amount of power generation compared to the case without the reflective layer (10) increase by more than 30%. Here, reference numeral L denotes the entire solar cell, L1 denotes sunlight entering the hard side R through the double-sided light-receiving solar cell module M, and L2 denotes the double-sided light-receiving solar cell module (M). It represents sunlight directly entering the lower hard surface R of the damaged frame F, and L3 represents sunlight reflected to the rear surface of the double-sided light-receiving solar cell module M by the reflective layer 10 .

As shown in FIG. 4 , the reflective layer 10 is composed of water-based paint (P) and titanium oxide (TiO _{2 ).} Titanium oxide (TiO ₂ ) is present in a mixed state in the water-based paint (P). The reflective layer 10 is formed by applying a water-based paint (P) mixed with _{titanium oxide (TiO 2 ) on the hard surface (R).} Titanium oxide (TiO ₂ ) 10 to 35% is included in the reflective layer 10 .

1st variation

As shown in FIG. 5 , glass beads G may be sprinkled on the surface of the reflective layer 10 ′. Due to the glass beads G, the surface strength of the reflective layer 10' is increased and the reflective layer 10' is prevented from peeling off. In addition, the diffuse reflectance of sunlight is increased due to the glass beads (G), and the power generation efficiency of the solar reflection system is improved.

2nd variation

As shown in Fig. 6, the reflective layer 10" is composed of two layers of a lower reflective layer A1 and an upper reflective layer A2. As the reflective layer 10" is composed of two layers, titanium oxide (TiO ₂ ) When the included water-based paint is applied to a hard surface, the surface hardens first and the inside hardens later, preventing cracks from occurring.

The lower reflective layer A1 is composed of water-based paint P and titanium oxide (TiO _{2 ).} Titanium oxide (TiO ₂ ) is present in a mixed state in the water-based paint (P). Titanium oxide (TiO ₂ ) is contained in less than 10% in the lower reflective layer (A1).

The upper reflective layer A2 is composed of water-based paint P and titanium oxide (TiO _{2 ).} Titanium oxide (TiO ₂ ) is present in a mixed state in the water-based paint (P). Titanium oxide (TiO ₂ ) is included in the upper reflective layer (A2) by 10 to 35%.

_{By making the amount of titanium oxide (TiO 2} ) of the upper reflective layer (A2) positioned on the upper _{side larger than the amount of titanium oxide (TiO 2} ) of the lower reflective layer (A1) positioned on the lower side, the power generation efficiency of the solar reflection system is improved can do it

Hereinafter, a case in which the reflective layer of the application-type solar reflection system according to an embodiment of the present invention is formed on the bottom surface of the water tank will be described.

The reflective layer 10 shown in FIG. 7 is formed by applying an aqueous paint containing _{titanium oxide (TiO 2 ) to the bottom surface (B) of the water tank (W).} Reference numeral L denotes the entire solar light.

The double-sided light-receiving solar cell module (M) is arranged by a frame (F) installed on the water tank (W). The tank (W) is filled with water and the fish are put in it. Of course, it does not matter even if there is no water in the empty water tank (W). In addition, the water tank W may be an abandoned water tank abandoned in a demolished fish market.

Hereinafter, a case in which the reflective layer of the application-type solar reflection system according to an embodiment of the present invention is formed on an inclined surface will be described.

The reflective layer 10 shown in FIG. 8 is formed by applying a water-based paint containing _{titanium oxide (TiO 2 ) to a hard inclined surface (C).} Reference numeral L denotes the entire solar light.

The double-sided light-receiving solar cell module (M) is arranged by a frame (F) installed on an inclined surface. Here, the hard slope (C) does not matter, such as a slope of a cement structure, a slope of a concrete structure, a slope of an asphalt structure, a slope of a rock in a mountainous area, and the like.

1: coating type solar reflective system 10: reflective layer
M: Double-sided light-receiving solar cell module
F: Frame R: Hard side
G: Glass beads W: Aquarium
A1: lower reflective layer A2: upper reflective layer

Claims (5)

a frame including a second frame vertically installed on an upper surface of an edge forming the water tank and a first frame inclined on the second frame to install the double-sided light-receiving solar cell module in the upper space of the water tank;
the double-sided light-receiving solar cell module inclinedly disposed on the first frame;
It is applied and formed on the bottom surface of the water tank located below the rear surface of the double-sided light-receiving solar cell module,
Consists of two layers of the applied lower reflective layer and the upper reflective layer coated on the upper surface of the lower reflective layer,
The upper reflective layer is composed of water-based paint and 10 to 35% of titanium oxide (TiO 2 ) mixed in the water-based paint,
The lower reflective layer is composed of water-based paint and less than 10% titanium oxide (TiO2) mixed in the water-based paint,
80% or more of sunlight in the 380 to 1100 nm wavelength band of sunlight entering the bottom of the water tank directly avoiding the double-sided light-receiving solar cell module or entering the bottom of the water tank through the double-sided light-receiving solar cell module , a reflective layer for diffusely reflecting to the rear side of the double-sided light-receiving solar cell module; and
When the water tank is filled with water, by the reflection layer formed by coating on the bottom surface of the water tank and sunlight reflected from the water contained in the water tank, power is generated from the rear surface of the double-sided light-receiving solar cell module,
When the water tank is empty, by the sunlight reflected from the reflection layer formed by coating on the bottom surface of the water tank, power is generated from the rear surface of the double-sided light-receiving type solar cell module. delete delete delete delete

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