KR102700575B1 - Building-integrated solar cell module with fire-resistance - Google Patents

Abstract

The present invention relates to a building-integrated solar cell module, and more specifically, to a building-integrated solar cell module capable of preventing a fire in a building by preventing flames, smoke, and heat from spreading indoors in the event of a fire.
The building-integrated solar cell module according to the present invention can effectively block flames, heat, smoke, etc. from spreading indoors through the insulation material and fire-resistant board in the event of a fire.
In addition, the present invention secures the insulation performance of a building without installing insulation in the building by forming an integral part of the solar cell module with insulation, and simplifies the installation process by omitting the insulation installation process, thereby shortening the construction period.

Description

Building-integrated solar cell module with fire-resistance

The present invention relates to a building-integrated solar cell module, and more specifically, to a building-integrated solar cell module capable of preventing a fire in a building by preventing flames, smoke, and heat from spreading indoors in the event of a fire.

Among the energies that are used to replace fossil fuels, the most widely and universally used is solar power generation. Solar power generation is not only easy to install, but can be constructed in a customized manner according to the amount of power generation required, so it is spreading to the industrial sector as well as the building and housing sectors.

Among these types of solar power generation, the one that has been gaining increasing attention recently is the Building Integrated Photovoltaic System (BIPV). As the name suggests, this technology is a structure that finishes the roof or walls of a building with solar panels. Compared to the existing technology of installing solar panels on existing buildings, it has several major advantages, and research is actively being conducted on it.

Most of the technologies currently being proposed for building-integrated photovoltaic power generation are not only structurally complex, but also require a multi-stage construction process to be implemented, which means that their economic feasibility and constructability are significantly lower than the utility of the technology itself.

In particular, solar panels have the disadvantage of not satisfying the performance as exterior materials, requiring additional insulation, and the disadvantage of not being connected to the building due to simple attachment. Among the required performances as exterior materials, insulation performance and condensation prevention are major indicators of exterior materials, and the building code stipulates the insulation performance of exterior materials by region to save energy by reducing the heating and cooling load.

Republic of Korea registered patent 10-1535125 Republic of Korea registered patent 10-1245167 Republic of Korea Publication Patent No. 10-2009-0030134

The purpose of the present invention is to provide a building-integrated solar cell module that can effectively block flames, heat, smoke, etc. from spreading indoors when a fire occurs in the solar cell module.

In addition, the present invention aims to provide a building-integrated solar cell module that can secure the insulation performance of a building without installing insulation in the building by forming it integrally with a solar cell module including insulation, and can shorten the installation period by simplifying the installation process by omitting the insulation installation process.

In order to achieve the above-described purpose, a building-integrated solar cell module according to the present invention comprises: a solar cell; an encapsulation part including a first encapsulation layer and a second encapsulation layer formed on the front side and the rear side of the solar cell respectively to encapsulate and protect the solar cell; fireproof glass installed on the first encapsulation layer and blocking flame and smoke; a back sheet installed on the second encapsulation layer and having fire resistance and flame retardancy; a back plate installed on the back sheet and having thermal conductivity; and a frame part wrapping around the edges of the fireproof glass and the back plate.

The back plate of the building-integrated solar cell module according to the present invention is formed of aluminum or metal, and is characterized in that a heat dissipation section for dissipating heat generated from the solar cell is formed.

The heat dissipation section of the building-integrated solar cell module according to the present invention is characterized by including a plurality of heat dissipation holes formed in a hexagonal shape and penetrating the back plate.

The heat dissipation section of the building-integrated solar cell module according to the present invention is characterized by including a plurality of communication holes penetrating across a plurality of heat dissipation holes so that the plurality of heat dissipation holes are in communication with each other.

The building-integrated solar cell module according to the present invention further comprises an insulating material installed on one side of the back plate, wherein the insulating material comprises a core material in the shape of a flat plate made by foaming and hardening phenol resin to have fire resistance and insulating properties, and a surface sheet formed of aluminum or glass fiber and attached to at least one of the front and rear surfaces of the core material to block radiant heat, absorb shock, and have waterproof and soundproofing properties.

The building-integrated solar cell module according to the present invention further comprises a fireproof board having non-combustible and fire-resistant properties, which is installed on one side of the insulating material; and the fireproof board is characterized in that it is a fiber-reinforced cement board obtained by mixing cellulose fibers and portland cement and then undergoing a high-temperature and high-pressure curing process.

The building-integrated solar cell module according to the present invention can effectively block flames, heat, smoke, etc. from spreading indoors through the insulation material and fire-resistant board in the event of a fire.

In addition, the present invention secures the insulation performance of a building without installing insulation in the building by forming an integral part of the solar cell module with insulation, and simplifies the installation process by omitting the insulation installation process, thereby shortening the construction period.

Figure 1 is a perspective view of a building-integrated solar cell module according to the present invention.
Figure 2 is a cross-sectional view of a building-integrated solar cell module according to the present invention.
Figure 3 is a partial cutaway perspective view of a building-integrated solar cell module according to the present invention.
Figure 4 is a partial cut-away perspective view showing the installation structure of a building-integrated solar cell module according to the present invention.

Hereinafter, a building-integrated solar cell module according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

FIGS. 1 to 4 illustrate a building-integrated solar cell module (1) according to the present invention. Referring to FIGS. 1 to 4, a building-integrated solar cell module (1) according to the present invention may be configured to include a solar cell (10), a sealing portion (20), fire-resistant glass (30), a back sheet (40), a back plate (50), an insulating material (60), a fire-resistant board (70), and a frame portion (80).

The solar cell (10) used was a crystalline solar cell (10).

The encapsulation part (20) is configured to include a first encapsulation layer (21) and a second encapsulation layer (22) formed on the front side and the back side of the solar cell (10), respectively, to wrap and protect the solar cell (10). The encapsulation part (20) can be formed of ethylene vinyl acetate (EVA), which is a copolymer of ethylene and vinyl acetate.

Fireproof glass (30) is formed on the first sealing layer (21) and blocks flame and smoke.

The back sheet (40) is formed under the second sealing layer (22) and has fire resistance and flame retardancy.

The back plate (50) is installed under the back sheet (40) and has thermal conductivity so as to be able to release heat generated from the solar cell (10). The back plate (50) can be formed of aluminum. In addition, the back plate (50) is formed with a heat dissipation portion for releasing heat generated from the solar cell (10). The heat dissipation portion can be configured to include a plurality of heat dissipation holes formed in a hexagonal shape and penetrating the upper and lower portions of the back plate. Although not shown in the drawing, the heat dissipation portion can include a plurality of communication holes penetrating across the plurality of heat dissipation holes so that the plurality of heat dissipation holes are connected to each other. The communication holes can extend radially from the heat dissipation holes on one side toward the heat dissipation holes on the other side around the heat dissipation holes.

The heat dissipation section of the building-integrated solar cell module (1) according to the present invention is characterized by including a plurality of heat dissipation holes formed in a hexagonal shape and penetrating the back plate (50).

Insulation (60) is installed on one side of the back plate (50).

The insulation material (60) can be composed of a core material (61) and a surface sheet (62).

The core material (61) is made by foaming and hardening phenol resin to provide fire resistance and insulation, and is formed into a flat plate shape.

The surface sheet (62) is attached to at least one of the front and rear surfaces of the core material (61) to block radiant heat, absorb shock, and provide waterproofing and soundproofing performance. The surface sheet (62) is formed of aluminum or glass fiber.

The fireproof board (70) is installed on one side of the insulation material (60) and is non-combustible and fire-resistant. The fireproof board (70) can be a fiber-reinforced cement board that is made by mixing cellulose fibers and portland cement and then undergoing a high-temperature and high-pressure curing process.

Fiber-reinforced cement board has a thermal conductivity of 0.25 W/mK or less, is manufactured from non-combustible inorganic materials, has excellent fire resistance, and has little change in length due to moisture absorption. In addition, fiber-reinforced cement board is easy and simple to construct, such as in construction processing and attachment, and exhibits high strength and impact resistance as cement, silica, etc. are combined into fibers.

The frame part (80) is formed to surround fireproof glass (30), back plate (50), insulation material (60), and fireproof board (70).

In more detail, the frame portion (80) can be configured to include a lower frame (81) and an upper frame (86) that are formed to be capable of being combined and separated.

The lower frame (81) can be configured to include a first horizontal frame (82), a second horizontal frame (83), and a first vertical frame (84).

The first horizontal frame (82) extends parallel to the refractory board (70) so as to wrap around a portion of the lower edge of the refractory board (70). Only a portion of the first horizontal frame (82) contacts the lower surface of the refractory board (70) to support the refractory board (70).

The second horizontal frame (83) extends parallel to the insulation (60) so as to cover a portion of the upper edge of the insulation (60) placed on the fireproof board (70). The second horizontal frame (83) supports the insulation (60) by contacting only a portion of the upper surface of the insulation (60) like the first horizontal frame (82). The outer edge of the second horizontal frame (83) is further provided with a frame joint (85) that extends outwardly and is bent from one side of the second horizontal frame (83) so that an upper frame (86) described later can be detachably coupled. The frame joint (85) is configured to include a vertical joint rib extending downward from the lower surface of the second horizontal frame (83) perpendicular to the second horizontal frame (83) by a certain length, and a horizontal joint rib extending from an end of the vertical joint rib toward the outside of the second horizontal frame (83) by a certain length parallel to the second horizontal frame (83). The frame joint (85) forms an insertion joint groove into which one side of the upper frame (86) can be inserted and joined between the second horizontal frame (83). In addition, a back plate (50) of a solar cell module (1) is secured and supported on the upper surface of the second horizontal frame (83).

The first vertical frame (84) extends in a direction perpendicular to the first horizontal frame (82) and the second horizontal frame (83) to connect the first horizontal frame (82) and the second horizontal frame (83), and its inner surface comes into contact with the side surface of the fireproof board (70) and the insulation material (60).

The upper frame (86) is formed to surround the fireproof glass (30), the solar cell (10), the sealing portion (20), the back sheet (40), and the back plate (50). More specifically, the upper frame (86) can be configured to include an insertion frame (87), a second vertical frame (88), and a third horizontal frame (89).

The insertion frame (87) has a length and thickness corresponding to the depth and thickness of the insertion-coupling groove provided in the lower frame (81) so that it can be inserted into the insertion-coupling groove. The insertion frame (87) is inserted into the insertion-coupling groove and is coupled to the second horizontal frame (83). Although not shown in the drawing, the insertion frame (87) may be firmly fixed to the second horizontal frame (83) by fastening a fixing piece so as to penetrate the insertion frame (87) and the second horizontal frame (83) on the horizontal coupling rib side.

The second vertical frame (88) extends upward from the end of the insertion frame (87) to a certain length perpendicular to the insertion frame (87) and the second horizontal frame (83) to wrap and protect the side surfaces of the fireproof glass (30), solar cell (10), sealing portion (20), back sheet (40), and back plate (50).

The third horizontal frame (89) is extended a certain length toward the center of the solar cell module (1) parallel to the second horizontal frame (83) and perpendicular to the second vertical frame (88) so as to cover a portion of the upper edge of the fireproof glass (30) from the top of the second vertical frame (88).

The upper frame (86) can be inserted into the insertion-joining groove in a direction parallel to the first and second horizontal frames (83) on the outside of the lower frame (81) and connected to the lower frame (81) so as to surround the fireproof glass (30) or the back plate (50).

The frame part (80) as described above has the advantage of being able to easily and quickly combine and separate the upper frame (86) and the lower frame (81), so that the solar cell module (1) can be easily replaced when damaged or broken, making maintenance very easy.

The building-integrated solar cell module (1) according to the present invention can effectively block flames, heat, smoke, etc. from spreading to the interior through the insulation material (60) and the fire-resistant board (70) in the event of a fire.

In addition, the present invention can secure the insulation performance of a building without installing the insulation (60) in the building by forming the solar cell module (1) integrally with the insulation (60), and can shorten the construction period by simplifying the installation process by omitting the installation process of the insulation (60).

The building-integrated solar cell module (1) according to the present invention described above has been described with reference to the attached drawings, but this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this.

Therefore, the true scope of technical protection of the present invention should be determined solely by the technical idea of the appended claims.

1: Solar cell module
10: Solar cell
20: Envelope
30 : Fireproof glass
40 : Back seat
50 : Backplate
60 : Insulation
70 : Fireproof board
80 : Frame part

Claims (6)

Solar cells;
An encapsulation part including a first encapsulation layer and a second encapsulation layer formed on the front side and the back side of the solar cell, respectively, to surround and protect the solar cell;
Fireproof glass installed on the first sealing layer and blocking flame and smoke;
A back sheet installed on the second sealing layer and having fire resistance and flame retardancy;
A back plate installed on the above back sheet and having thermal conductivity;
An insulating material installed on one side of the above back plate;
A fireproof board installed on one side of the above insulation material and having non-combustible and fire-resistant properties;
It has a frame part that wraps around the edge of the above fireproof glass, the above back plate, the above insulation material, and the above fireproof board;
The above frame portion includes a lower frame and an upper frame formed so as to be combined and separated,
The above subframe
A first horizontal frame extending parallel to the fireproof board to wrap around a portion of the lower edge of the fireproof board and supporting the fireproof board,
A second horizontal frame having a frame joint portion that extends parallel to the insulation to support the insulation so as to surround a portion of the upper edge of the insulation placed on the upper side of the fireproof board, and has an outer edge that is bent outwardly to enable detachable attachment of the upper frame;
Including a first vertical frame extending in a direction perpendicular to the first horizontal frame and the second horizontal frame to connect the first horizontal frame and the second horizontal frame, and having an inner surface in contact with the side surface of the fireproof board and the insulation material,
The frame joint includes a vertical joint rib extending downward from the lower surface of the second horizontal frame perpendicular to the second horizontal frame by a predetermined length, and a horizontal joint rib extending from an end of the vertical joint rib toward the outside of the second horizontal frame by a predetermined length so as to be parallel to the second horizontal frame, and forms an insertion joint groove capable of inserting and joining one side of the upper frame between the second horizontal frame and the second horizontal frame.
The above upper frame
An insertion frame having a length and thickness corresponding to the depth and thickness of the insertion-joining groove so that it can be inserted into the insertion-joining groove provided in the lower frame, and which is inserted into the insertion-joining groove and connected to the second horizontal frame;
A second vertical frame extending upwardly from an end of the above insertion frame to a certain length perpendicular to the above insertion frame and the second horizontal frame,
A third horizontal frame is included, which is perpendicular to the second vertical frame and extends a certain length toward the center of the solar cell module parallel to the second horizontal frame so as to cover a portion of the upper edge of the fire-resistant glass from the upper end of the second vertical frame.
A building-integrated solar cell module, characterized in that the upper frame is connected to the lower frame by being inserted into the insertion-joining groove in a direction parallel to the first and second horizontal frames on the outside of the lower frame. In the first paragraph,
The above back plate is formed of aluminum or metal,
A building-integrated solar cell module characterized in that a heat dissipation section is formed to dissipate heat generated from the solar cell. In the second paragraph,
A building-integrated solar cell module, characterized in that the heat dissipation portion penetrates the back plate and includes a plurality of heat dissipation holes formed in a hexagonal shape. In the third paragraph,
A building-integrated solar cell module, characterized in that the heat dissipation unit includes a plurality of communication holes penetrating across the plurality of heat dissipation holes so that the plurality of heat dissipation holes are connected to each other. In the first paragraph,
A building-integrated solar cell module characterized in that the insulation material comprises a core material in the shape of a flat plate made by foaming and hardening phenol resin to have fire resistance and insulating properties, and a surface sheet formed of aluminum or glass fiber and attached to at least one of the front and rear surfaces of the core material to block radiant heat, absorb shock, and have waterproof and soundproofing properties. In the first paragraph,
The above fireproof board is a building-integrated solar cell module characterized in that it is a fiber-reinforced cement board that is made by mixing cellulose fibers and portland cement and then undergoing a high temperature and high pressure curing process.

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