KR102421845B1 - Combined structure of solar modules in block shape - Google Patents

Abstract

The coupling structure of the photovoltaic module having a block shape according to the present invention includes a metal panel 110 that is detachably coupled to the building; a fixing bracket 120 that is slidably disposed on the metal panel 110; and a photovoltaic panel 130 having a block shape that is detachably coupled to the metal panel 110 through the fixing bracket 120 , wherein the photovoltaic panel 130 is the photovoltaic panel The solar panel is bound to the metal panel 110 through one-touch sliding coupling between the end brackets disposed on each corner and the fixing bracket 120 .

Description

Combined structure of solar modules in block shape

The present invention relates to a combination structure of a photovoltaic module having a block shape, and more particularly, a photovoltaic module attaching and detaching method having a metal substrate structure that can be installed in a state of being independent of a building shape while having a simple structure in a one-touch method It's about development.

Buildings are the best place to install solar modules that occupy a significant portion of the Earth's surface that receives sunlight every day on Earth. It is the best place to be. In addition, a significant portion of the world's electricity consumption is consumed by buildings, particularly 50% of the total amount of electricity produced artificially.

Taking the existing building-type photovoltaic power generation product as an example, the photovoltaic power generation product with the initial building attachment form has a uniform design in which a flat photovoltaic module is installed on the roof or roof of a building, but the aesthetic sense of the building is improved. There is a problem that it cannot be saved.

Currently, the construction of curved solar modules is increasing by emphasizing the design elements of buildings, but the shape of solar cells outside the building is emerging as a problem that hinders the aesthetics of exposure.

Patent Publication Nos. 10-1260301 and 10-1868299 and the like are disclosed for a building or wall-integrated photovoltaic power generation system.

The present invention is intended to solve the above problems, and unlike general solar modules, crystalline silicon solar cells and metal substrate materials are used to enable urban distributed photovoltaic power generation. It is to provide a coupling structure of a solar module having a block shape having a required capacity in a narrow area.

An object of the present invention is to provide a block-type module having a one-touch detachable structure to which durability is secured through a metal substrate shape design and an EP material is applied.

In addition, it is to provide a block-type module that guarantees power generation performance by improving the aesthetics of the building and improving transmittance by wavelength because solar cells and busbars are not exposed to the outside through chroming coating for color diversification on the surface of tempered glass.

In addition, through the application of lightweight materials and structural design, it is possible to reduce weight and secure durability compared to solar modules of the same standard, so that it is possible to provide a block-type module that can be used in various spaces such as mobile houses and outdoor performance halls without external walls. .

The coupling structure of the photovoltaic module having a block shape according to the present invention for achieving the above object includes a metal panel 110 detachably coupled to the building; a fixing bracket 120 that is slidably disposed on the metal panel 110; and a photovoltaic panel 130 having a block shape that is detachably coupled to the metal panel 110 through the fixing bracket 120 , wherein the photovoltaic panel 130 is the photovoltaic panel It may be preferable to bind the solar panel to the metal panel 110 through one-touch sliding coupling between the end brackets disposed on each corner and the fixing bracket 120 .

It may be preferable that the metal panel 110 has a bracket guide groove 112 that enables a sliding motion in a state in which the fixing bracket 120 is accommodated.

It may be preferable that the metal panel 110 is configured in a form in which upper and lower ends can correspond to a plurality of the metal panels 110 so that they can be continuously coupled along the upper and lower directions.

The end bracket has a bracket body having a 'L' shape coupled along a corner of the metal panel 110 and a bracket leg portion extending from the rear surface of the bracket body, and the fixing bracket 120 is a bracket formed with a predetermined thickness. It may be preferable to have a coupling structure of a solar module having a block shape, in which the bracket legs are coupled to be in contact with the groove side.

The combined structure of the photovoltaic module having a block shape according to the present invention as described above uses a crystalline silicon solar cell and a metal substrate material to have the capacity required in a small area so that it can be attached to and detached from the wall and roof of a building. Unlike photovoltaic modules, it enables urban distributed photovoltaic power generation.

The present invention enables attachment and detachment regardless of the shape of the wall and roof of a building through a one-touch detachable structure to which durability is secured through design of a metal substrate and EP material is applied.

In addition, the present invention guarantees the power generation performance by improving the aesthetics of the building and improving the transmittance for each wavelength by preventing the solar cells and busbars from being exposed to the outside through the chroming coating for color diversification on the surface of the tempered glass.

In addition, through the application of lightweight materials and structural design, it reduces weight and secures durability compared to solar modules of the same standard, enabling use in various spaces such as mobile houses and outdoor performance halls without external walls.

1 shows the overall coupling state of a solar module having a block shape according to an embodiment of the present invention.
2 shows an exploded perspective view and a side view of a solar module having a block shape.
3 shows the structure of a metal substrate constituting a photovoltaic module having a block shape.
4 shows a bonding process between a photovoltaic module and a metal substrate equipped with a fixing bracket.
5 shows a coupled state between the photovoltaic module and the metal substrate equipped with the fixing bracket.
6 shows a state in which a plurality of photovoltaic modules are coupled to the exterior wall of a building through a metal substrate and a fixing bracket.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art. It is provided for complete disclosure. In the drawings, like reference numerals refer to like elements.

In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, a solar module having a block shape according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6 .

The present invention uses a crystalline silicon solar cell and a metal substrate material to enable urban distributed photovoltaic power generation, unlike a general photovoltaic module, in a block form having a required capacity in a small area so that it can be attached to and detached from the wall and roof of a building. It is a key feature to provide a coupling structure of a solar module having a.

The photovoltaic module having the block shape includes a metal panel 110 that is detachably coupled on a building, a fixing bracket 120 that is arranged to be slidable on the metal panel 110, and a metal panel through the fixing bracket 120 . It includes a solar panel 130 having a block shape that is detachably coupled on the 110 .

The metal panel 110 has an uneven bracket guide groove that enables sliding motion in the state in which the fixing bracket 120 is accommodated. The metal panel 110 includes a panel body 111 to which a solar panel is directly surface-coupled, a bracket guide groove 112 in which a groove is formed along the left and right direction on the central portion of the panel body 111, and an upper portion of the panel body 111 . It includes panel binding holes 113 and 114 that are bent backward on the end and the lower end.

The bracket guide groove 112 is made of an empty space having a rectangular cross-sectional shape to facilitate the left and right movement of the fixing bracket 120 . That is, through the process of bending the middle region with respect to the metal panel 110 having a flat plate shape, a groove having a hollow chamber shape inserted therein to have a rectangular cross section is formed.

The metal panel 110 is configured in such a way that the upper and lower ends can correspond to each other so that a plurality of them can be continuously coupled along the upper and lower directions. Specifically, the upper panel binding hole 113 forming the upper end of the metal panel 110 and the lower panel binding hole 114 forming the lower end of the metal panel 110 protrude upward in the process of extending rearward, respectively. It has first binding points 113a and 114a and second binding points 113b and 114b extending downward from the first binding points 113a and 114a.

In the above state, in the plurality of metal panels 110 arranged in the upper and lower directions, the first binding point constituting the upper metal panel is seated on the first binding point constituting the lower metal panel, and at the same time, the second binding point constituting the upper metal panel Through a method of being seated on the second binding point constituting the lower panel, it is stably coupled to each other.

The metal panel 110 is configured so that the upper panel binding part 113 and the lower panel binding hole 114 are caught on the square pipe 11 disposed on the wall surface 10 of the building. The metal panel 110 is spaced apart from the wall surface by a predetermined distance through the square pipe.

The photovoltaic panel 130 connects the photovoltaic panel to the metal panel 110 through one-touch sliding coupling between a plurality of end brackets 135 and the fixing bracket 120 disposed on each corner of the photovoltaic module. bind to the top.

The plurality of end brackets 135 include a bracket body 136 having an 'L' shape coupled along a corner of a solar panel having a rectangular panel shape, respectively, and a bracket leg part 137 extending from the rear surface of the bracket body. and the fixing bracket 120 is coupled to the bracket leg portion so as to be in contact with the side of the bracket groove formed to a predetermined thickness.

The bracket body 136 has a structure that is bent at 90 degrees along the corners of the solar panel, and the bracket legs extend from the center and both ends of the bracket body to the rear.

The fixing bracket 120 has a bracket inner protrusion 121 formed therein so that the bracket leg part can be inserted. The fixing bracket 120 is formed with a leg fixing groove 123 on the upper and lower portions of the bracket inner protrusion 121 into which the bracket leg portion can be inserted. That is, it has a structure in which a plurality of bracket legs spaced apart along the upper and lower directions on the rear surface of the end bracket 135 are inserted into the leg fixing grooves 123 . As described above, the solar panel is stably fixed on the fixing bracket 120 through the leg fixing groove formed in the upper and lower layers. The present invention provides a simple coupling structure between a photovoltaic panel and a metal panel 110, enabling easy attachment using the interlocking fixing bracket 120, and at the same time enabling the unlocking using a simple tool when a failure occurs. Ensure the convenience of replacement.

Meanwhile, FIG. 6 shows a state in which a plurality of photovoltaic panels are coupled to the outer wall of the building through the metal substrate and the fixing bracket 120 .

Three metal panels 110 along the upper and lower parts are arranged to be continuously coupled through binding points, and a plurality of end brackets arranged on the corners of each solar panel are fixed brackets arranged in the bracket guide groove 112 ( 120) to form a stable bond.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

110: metal panel
120: fixed bracket
130: solar panel

Claims (4)

a metal panel that is detachably coupled to the building (110);
a fixing bracket 120 that is slidably disposed on the metal panel 110; and
A solar panel 130 having a block shape that is detachably coupled to the metal panel 110 through the fixing bracket 120 ;
The photovoltaic panel 130 binds the photovoltaic panel on the metal panel 110 through one-touch sliding coupling between the end brackets disposed on each corner of the photovoltaic panel and the fixing bracket 120 . and
The end bracket has a bracket body having a 'L' shape coupled along a corner of the metal panel 110 and a bracket leg extending from the rear surface of the bracket body,
The fixing bracket 120 has a bracket inner protrusion 121 formed on the inside so that the bracket leg part can be inserted, and the fixing bracket 120 is the bracket leg on the upper and lower parts with the bracket inner protrusion 121 as the center. It is characterized in that the leg fixing groove 123 into which the part can be inserted is formed, so that the bracket leg portions formed to be spaced apart along the upper and lower directions on the rear surface of the end bracket are inserted into the leg fixing groove 123,
A combined structure of a solar module having a block shape.
The method of claim 1,
The metal panel 110 is a coupling structure of a photovoltaic module having a block shape in which a bracket guide groove 112 that enables a sliding motion in a state in which the fixing bracket 120 is accommodated is formed.
3. The method of claim 2,
The metal panel 110 is a combination structure of a photovoltaic module having a block shape, in which a plurality of upper and lower ends are configured to correspond to each other so that a plurality of them can be continuously coupled along the upper and lower directions.
3. The method of claim 2,
The fixing bracket 120 is a coupling structure of a photovoltaic module having a block shape, in which the bracket leg is coupled to the side of the bracket groove formed to a predetermined thickness.

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