KR102637873B1 - BIPV system - Google Patents

Abstract

The BIPV system according to one aspect of the present invention includes a frame provided in a grid form to form a plurality of coupling spaces, glass provided in the coupling space of the frame, a ventilation window provided in the coupling space of the frame, and the frame. A solar module is provided in the combination space to absorb sunlight, a power generation auxiliary device is located on the indoor side of the frame and generates power through sunlight absorbed by the solar module, and is fixed to the frame to generate solar energy. It may include a winding device for winding a wire connecting the module and the power generation auxiliary device, and a hinge cover that is detachable from the frame and opens or closes the power generation auxiliary device.

Description

BIPV system{BIPV system}

The present invention relates to a BIPV system, and more specifically, to a BIPV system that can improve usability.

BIPV system (Building Integrated Photovoltaic System) is a PV system integrated into buildings. In addition to producing electricity from solar energy and supplying it to consumers, it refers to a solar power generation system that uses building-integrated photovoltaic modules as building exterior materials.

For this BIPV system, research on BIPV modules and building application techniques has been actively conducted over the past 10 years, and now and in the future, PV modules will be integrated and applied using the roof and facade of the building, serving as a building material and producing electricity. This technology is in the spotlight as a building envelope technology.

Here, the BIPV system must be harmoniously planned and constructed in the building from the design stage. There are various application methods for each building type, and depending on the application area, it can be divided into upper building elements such as the roof, building facade elements such as walls, and shading or lighting elements. there is.

However, these BIPV systems have problems in that power generation efficiency is reduced due to heat generated from solar modules during power generation and maintenance of various electrical devices is not easy.

Republic of Korea Patent Publication No. 10-1638419 (2016.07.12)

The present invention was created to solve the above problems, and the purpose of the present invention is to provide a BIPV system that can improve usability.

The BIPV system according to an embodiment of the present invention to achieve the above object is a frame provided in a grid form to form a plurality of coupling spaces, glass provided in the coupling space of the frame, and a combination of the frames. A ventilation window provided in the space, a solar module provided in the coupling space of the frame to absorb sunlight, and a power generation auxiliary device located on the indoor side of the frame and generating power through sunlight absorbed by the solar module; , a winding device that is fixed to the frame and winds a wire connecting the solar module and the power generation auxiliary device, and a hinge cover that is detachable from the frame and opens or closes the power generation auxiliary device. .

The frame includes a main body part forming the coupling space, a cover part provided on the outdoor side of the main body part, and a coupling part provided on the indoor side of the main body part where the power generation auxiliary device is seated and the hinge cover is coupled. and an internal space formed by the main body portion, the cover portion, and the coupling portion, where the winding device is located.

The coupling portion includes a vertical surface coupled to the main body portion and the insulation material, an upper surface extending vertically from the top of the vertical surface, an upper coupling protrusion provided at one end of the upper surface and coupled to one end of the hinge cover, and a lower end of the vertical surface. A lower surface extending vertically from the upper surface on which the power generation auxiliary device is seated, a fastening protrusion provided on the lower surface to which the fastening part of the power generation auxiliary device is fastened, and a lower surface extending so that a step is formed on the lower surface and installed at the lower part of the lower surface. It may include an extension surface that forms a space, and a lower engaging protrusion provided at one end of the extension surface and coupled to the other end of the hinge cover.

The hinge cover may include a first part whose one end engages with the upper engaging protrusion, and a second part whose one end engages with the lower engaging protrusion.

The first part includes a first body provided in a plate shape, a first coupling piece extending from one end of the first body and coupled to the upper coupling protrusion, and a second part provided at the other end of the first body. A first hinge for coupling may be provided.

The second part includes a second body provided in a plate shape, a second coupling piece provided on one side of the second body to form a perpendicular direction to the second body and coupled to the lower coupling protrusion, and a second coupling piece of the second body. A second hinge may be provided at the other end and coupled to the first hinge.

The lower coupling protrusion may be provided with a gasket to increase coupling force with the second coupling piece.

The facility space may be provided with a heat sink fixed to the lower surface to collect heat generated from the power generation auxiliary device.

A ventilation device may be further provided at the top or top and bottom of the solar module to exert a ventilation function.

According to the BIPV system according to the present invention, usability can be improved.

1 and 2 are diagrams showing a BIPV system according to an embodiment of the present invention.
Figure 3 is a diagram showing the hinge cover of the BIPV system shown in Figure 2.
FIG. 4 is a diagram showing a heat sink provided in the BIPV system shown in FIG. 2.
Figure 5 is a diagram showing the ventilation device of the BIPV system shown in Figure 2.

Hereinafter, a BIPV system according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

1 and 2 are diagrams showing a BIPV system according to an embodiment of the present invention.

As shown in Figures 1 and 2, the BIPV system 10 according to an embodiment of the present invention includes a frame 100 that is provided in a grid form to form a plurality of coupling spaces 110, and a frame 100 ), a glass 20 provided in the coupling space 110 of the frame 100, a ventilation window 30 provided in the coupling space 110 of the frame 100, and a solar panel provided in the coupling space 110 of the frame 100. A solar module 40 that absorbs energy, a power generation auxiliary device 50 located on the indoor side of the frame 100 that generates electricity through solar energy absorbed by the solar module 40, and fixed to the frame 100. It is provided in a detachable form with the frame 100 and the winding device 60, which winds the wire (unmarked) connecting the solar module 40 and the power generation auxiliary device 50, to open the power generation auxiliary device 50. Alternatively, a hinge cover 200 for closing may be provided.

The frame 100 includes a main body part 120 forming the coupling space 110, a cover part 130 provided on the outdoor side of the main body part 120, and an indoor side of the main body part 120. A coupling portion 140 on which the auxiliary device 50 is seated and the hinge cover 200 is coupled may be provided.

The glass 20, ventilation window 30, and solar module 40 can be installed on the frame 100 regardless of location to configure various elevations.

The solar module 40 is provided in a Z-BAR form to facilitate wiring with another neighboring solar module 40, and the winding device 60 has a wire (not used) before the cover portion 130 is installed. symbol) may be provided in a wound state.

The main body part 120 is provided in a grid shape to form a coupling space 110, and a winding device can be fixed to the main body part 120, which is provided horizontally.

The coupling portion 140 includes a vertical surface 141 coupled to the main body 120 and an insulating material (not denoted), an upper surface 142 extending vertically from the top of the vertical surface 141, and one end of the upper surface 142. It is provided with an upper coupling protrusion 143 coupled to one end of the hinge cover 200, a lower surface 144 extending vertically from the lower end of the vertical surface 141 and on which the power generation auxiliary device 50 is seated, and a lower surface ( The fastening protrusion 145 is provided in 144 and is fastened to the fastening portion 51 of the power generation auxiliary device 50, and extends to form a step at the lower surface 144, forming an equipment space 147 at the lower part of the lower surface 144. It may include an extension surface 146 to be formed, and a lower engaging protrusion 148 provided at one end of the extension surface 146 to which the other end of the hinge cover 200 is coupled.

The vertical surface 141, the upper surface 142, and the lower surface 144 are provided in a 'ㄷ' shape, and the upper surface 142 and the upper coupling protrusion 143 are in a form that covers a portion of the upper part of the power generation auxiliary device 50. It is provided, and the power generation auxiliary device 50 can be fixed by fastening the fastening part 51 to the fastening protrusion 145 while the entire lower part is supported on the lower surface 144.

The extension surface 146 extends to form a step with the lower surface 144, thereby forming an equipment space 147 in the lower part of the lower surface 144 and at the same time forming a space surrounded by the coupling portion 140 and the hinge cover 200. Other equipment other than the power generation auxiliary device 50 can be provided without interference with the power generation auxiliary device 50.

The lower coupling protrusion 148 is provided at one end of the extension surface 146 and is coupled to the other end of the hinge cover 200, so that the hinge cover 200 together with the upper coupling protrusion 143 is detachable from the coupling portion 140. It can be made available.

Next, the hinge cover 200 of the BIPV system 10 according to an embodiment of the present invention will be described. In the following description, only parts that are different from the above-described embodiment will be described in detail, and detailed descriptions of parts that are the same or extremely similar will be omitted.

FIG. 3 is a diagram showing the hinge cover of the BIPV system shown in FIG. 2.

Referring to Figures 1 to 3, the hinge cover 200 of the BIPV system 10 according to an embodiment of the present invention includes a first part 210 at one end coupled to the upper engaging protrusion 143, and one end A second part 220 coupled to the lower coupling protrusion 148 may be provided.

The first part 210 is coupled with the upper coupling protrusion 143 and is horizontal to the lower surface 144 and the extension surface 146 of the coupling part 140 to cover the remaining part of the power generation auxiliary device 50. In addition, the second part 220 may be provided to be perpendicular to the first part 210 by being combined with the lower engaging protrusion 148 while being integrated with the first part 210.

For this purpose, the first part 210 includes a first body 211 provided in a plate shape, and a first coupling piece 212 extending from one end of the first body 211 and coupled to the upper coupling protrusion 143. and a first hinge 213 provided at the other end of the first body 211 and coupled to the second part 220, and the second part 220 is provided in a plate shape. and a second coupling piece 222 provided on one side of the second body 221 to form a perpendicular position to the second body 221 and coupled to the lower coupling protrusion 148, and the other end of the second body 221. It may be provided with a second hinge 223 coupled to the first hinge 213.

The first coupling piece 212 is provided in a form that is inserted into the upper coupling protrusion 143 and then draped over, and the second coupling piece 222 is provided in a form fitted in the lower coupling protrusion 148 so that the hinge cover 200 is provided. By being provided to be detachable from the coupling portion 140, maintenance such as inspection or replacement of the power generation auxiliary device 50 can be easily performed.

Here, the lower coupling protrusion 148 is provided with a gasket 160, which has the effect of increasing the coupling force between the lower coupling protrusion 148 and the second coupling piece 222 when the second coupling piece 222 is coupled in a fitting form. It can be performed.

The first hinge 213 and the second hinge 223 are provided in different ring shapes, and one end of the second hinge 223 is located inside the first hinge 213, forming the first portion 210. By coupling the and second parts 220 and simultaneously rotating the first part 210 and the second part 220 with each other, the hinge cover 200 can be easily attached and detached.

Next, the heat sink 170 provided in the BIPV system 10 according to an embodiment of the present invention will be described. In the following description, only parts that are different from the above-described embodiment will be described in detail, and detailed descriptions of parts that are the same or extremely similar will be omitted.

FIG. 4 is a diagram showing a heat sink provided in the BIPV system shown in FIG. 2.

Referring to Figures 1 to 4, the frame 100 of the BIPV system 10 according to an embodiment of the present invention is provided on the indoor side of the main body 120, on which the power generation auxiliary device 50 is seated and the hinge cover. (200) is provided with a coupling part 140 that is coupled, and the coupling part 140 extends to form a step at the lower surface 144, so that an equipment space 147 is formed in the lower part of the lower surface 144. (146) can be provided.

Additionally, the equipment space 147 may be provided with a heat sink 170, one end of which is fixed to the lower surface 144.

The heat sink 170 collects the heat generated by the power generation auxiliary device 50 provided on the upper part of the lower surface 144 during power generation and allows the heat to be released from the power generation auxiliary device 50, thereby causing overheating of the power generation auxiliary device 50. This can be effective in preventing performance degradation.

Next, the ventilation device 300 provided in the BIPV system 10 according to an embodiment of the present invention will be described. In the following description, only parts that are different from the above-described embodiment will be described in detail, and detailed descriptions of parts that are the same or extremely similar will be omitted.

FIG. 5 is a diagram showing the ventilation device of the BIPV system shown in FIG. 2.

Referring to FIGS. 1 to 5, the BIPV system 10 according to an embodiment of the present invention further includes a ventilation device 300 provided on the top or upper and lower sides of the solar module 40 to exert a ventilation function. can do.

As shown in FIG. 5(a), the ventilation device 300 is provided on the upper part of the solar module 40 and uses heat generated from the solar module 40 or the heat sink 170 when the heat sink 170 is provided. ) can be used to discharge the heat generated to the outside.

And, as shown in FIG. 5(b), when provided at the top and bottom of the solar module 40, the heat generated from the solar module 40 through the ventilation device 300 provided at the top or When the heat sink 170 is provided, heat generated from the heat sink 170 can be discharged to the outside and at the same time, overheating can be prevented by introducing outside air through the ventilation device 300 provided at the bottom.

In this way, the ventilation device 300 releases heat generated from the solar module 40 or the power generation auxiliary device 50 and prevents overheating, thereby preventing the performance of the power generation auxiliary device 50 from being deteriorated due to overheating. It can have a preventing effect.

In addition, by cutting off the water flow during rainy weather to prevent rainwater from entering, it is possible to prevent breakdowns or damage due to rainwater inflow.

In the above, the BIPV system according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiment presented in this specification. In addition, a person skilled in the art who understands the spirit of the present invention will be able to easily suggest other embodiments by adding, changing, deleting, or adding components within the scope of the same spirit, but it is said that this is also within the spirit scope of the present invention. will be.

10: BIPV system 20: glass
30: Ventilation window 40: Solar module
50: Power generation auxiliary device 51: Fastening part
60: winding device 100: frame
110: coupling space 120: main body part
130: cover part 140: coupling part
141: vertical surface 142: upper surface
143: upper coupling protrusion 144: lower surface
145: fastening protrusion 146: extension surface
147: Equipment space 148: Bottom coupling protrusion
160: gasket
170: heat sink 200: hinge cover
210: first part 211: first body
212: first coupling piece 213: first hinge
220: second part 221: second body
222: second coupling piece 223: second hinge
300: Ventilation device

Claims (9)

A frame provided in a grid form to form a plurality of joining spaces,
Glass provided in the coupling space of the frame,
a ventilation window provided in the coupling space that is different from the coupling space in which the glass is provided so as to be adjacent to the glass left and right or up and down;
a solar module provided in the coupling space provided with the glass and the ventilation window and another coupling space adjacent to the glass and the ventilation window in the vertical direction to absorb sunlight;
A power generation auxiliary device located on the indoor side of the frame and connected to the solar module,
A winding device fixed to the frame and winding a wire connecting the solar module and the power generation auxiliary device;
A hinge cover is provided in a detachable form with the frame to open or close the power generation auxiliary device,
The frame includes a main body part forming the coupling space, a cover part provided on the outdoor side of the main body part, and
It is provided on the interior side of the main body portion and has a coupling portion on which the power generation auxiliary device is seated and the hinge cover is coupled,
The coupling portion includes a vertical surface coupled to the main body portion, an upper surface extending vertically from the top of the vertical surface, an upper coupling protrusion provided at one end of the upper surface and coupled to one end of the hinge cover, and a vertical surface at the lower end of the vertical surface. a lower surface on which the power generation auxiliary device is seated at the upper end, a fastening protrusion provided on the lower surface to which the fastening part of the power generation auxiliary device is fastened, and a lower surface extending so that a step is formed on the lower surface to create an equipment space in the lower part of the lower surface. It has an extension surface to be formed, and a lower engaging protrusion provided at one end of the extension surface and coupled to the other end of the hinge cover,
The hinge cover has a first part whose one end engages with the upper engaging protrusion and a second part whose one end engages with the lower engaging protrusion,
The first part includes a first body provided in a plate shape, a first coupling piece extending from one end of the first body and coupled to the upper coupling protrusion, and a second part provided at the other end of the first body. Provided with a first hinge for coupling,
The second part includes a second body provided in a plate shape, a second coupling piece provided on one side of the second body to form a perpendicular direction to the second body and coupled to the lower coupling protrusion, and a second coupling piece of the second body. A second hinge is provided at the other end and coupled to the first hinge,
The lower coupling protrusion is provided with a gasket to increase coupling force with the second coupling piece,
A BIPV system, characterized in that the equipment space is provided with a heat sink fixed to the lower surface to collect heat generated from the power generation auxiliary device.
delete delete delete delete delete delete delete According to clause 1,
A BIPV system characterized in that it further includes a ventilation device provided on the top or upper and lower sides of the solar module to exert a ventilation function.

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