KR102231752B1 - solar power generation structure for waterproof - Google Patents

Abstract

The present invention relates to a solar power generation structure on a rooftop of a building and, more particularly, to a solar power generation structure on a rooftop of a building which can be installed on the rooftop of the building to generate solar power and increase a waterproof effect of the rooftop. The solar power generation structure on a rooftop of a building of the present invention comprises: a support frame unit installed on a rooftop provided on an upper portion of a building; and a solar roof installed on an upper portion of the support frame unit to enable solar power generation.

Description

Solar power generation structure for waterproof on the roof of a building

The present invention relates to a photovoltaic power generation structure on the roof of a building, and more particularly, to a photovoltaic power generation structure on the roof of a building that is installed on the roof of a building to enable solar power generation and at the same time enhance the waterproofing effect of the roof.

In general, the roof of a building made of reinforced concrete is made of a flat structure, so drainage is not smooth, so rainwater etc. can easily seep into the roof slab and age the building.

Therefore, a waterproof coating formed by applying a waterproofing agent such as rubber asphalt, acrylic, polyurethane, etc. is applied on the roof. While such a waterproof coating is inexpensive, there is a problem in that when exposed to sunlight or the like, cracks are frequently generated and peeled off, resulting in leakage.

On the other hand, solar power generation facilities are largely divided into two types and installed. One is to install a foundation on the land and a structure and solar module on the top (land-type solar power plant), and the other is to install it using the roof, roof, or wall of a building (building-type solar power generation). Equipment). The land-type solar power plant is a method of digging the land and forming a foundation with concrete, etc. to install a structure on the upper part of the foundation, so there is no need to consider the problem of leakage at all.

However, since building-type solar power generation facilities are constructed based on buildings, the problem of leakage must be considered.

Korean Patent Registration No. 10-1730395 discloses a complex waterproof structure on the roof of a building using a solar panel.

The building roof complex waterproof structure is a building roof with drainage passages formed on both sides of the roof layer, a condensing unit disposed on the roof and condensing solar heat, and installed on the roof top, and independently elevating the front and rear ends of the condensing unit. And a control unit for changing a posture so that an end of the condensing unit is inclined toward the drainage channel by using the pair of elevating units when rain is detected on the condensing unit.

The above-described conventional building rooftop complex waterproof structure still has a problem in that the drainage problem on the roof cannot be solved because rainwater flowing along the condenser falls directly to the surrounding rooftop. In addition, when the wind blows in rainy weather, raindrops fall obliquely, so there is a problem that rain falls under the condenser. In addition, since the condensing unit has a structure in which a plurality of solar panels are arranged, rainwater may flow into the gaps between the solar panels, but the above-described conventional technology does not provide any countermeasures against rainwater flowing into the gaps between the solar panels. Not stated.

Republic of Korea Patent Registration No. 10-1730395: Complex waterproof structure on the roof of a building using solar panels

The present invention has been created to improve the above problems, and is installed to cover a certain area of the roof of the building to provide a solar power generation structure on the roof of a building capable of generating photovoltaic power and enhancing the waterproofing effect of the roof. There is a purpose.

In addition, the present invention provides a solar power generation structure capable of increasing the utility and utility of a rooftop by securing an indoor space that can be used as a warehouse, a greenhouse, or various spaces for leisure activities in the solar power generation structure. There is a purpose.

The solar power generation structure on the roof of a building of the present invention for achieving the above object comprises: a support frame part installed on the roof provided on the upper part of the building; A photovoltaic roof installed on the upper part of the support frame and capable of photovoltaic power generation, wherein the photovoltaic roof includes a plurality of photovoltaic panels arranged side by side and spaced apart from each other in a longitudinal and transverse direction, and the photovoltaic panels It is installed at the bottom and supported by the support frame, and includes a rainwater discharge means for discharging rainwater flowing into the spaced gap between the solar panels to the outside, and the rainwater discharge means is spaced in a longitudinal direction among the spaced gaps. And a main drain bracket installed to correspond to the gap, and a sub drain bracket installed to correspond to a gap in the transverse direction among the gaps to guide rainwater to the main drain bracket.

A wall portion installed below the solar roof, and an indoor space portion provided inside the wall portion and covered by the solar roof.

The main drainage bracket has an upper portion open to form a drainage passage inside and a longitudinally elongated water passage portion, and a first horizontal side extending horizontally outward from the upper side of both sides of the water passage portion to be coupled to the lower portion of the solar panel. A portion, a vertical side portion extending vertically downward from an end portion of the first horizontal side portion, and a second horizontal side portion extending horizontally outward from an end portion of the vertical side portion and coupled to the support frame portion.

The sub-drainage bracket is a plate part formed long in a horizontal direction and spanned between two adjacent solar panels in a vertical direction, and a vertical bend that extends vertically downward from both ends of the plate part to contact the vertical side part. And a horizontal bent portion extending horizontally inward from an end portion of the vertical bent portion and coupled to the second horizontal side portion.

The sub-drainage bracket is a pair of protruding protrusions formed on the upper part of the plate part, and a watertight kit filled with an adhesive so as to leak the adhesive when pressed against the side surface of the solar panel and installed to be detachably attached to the protruding protrusion. It has more wealth.

As described above, the present invention covers a certain area of the roof by installing the solar power generation structure on the roof of a building, so that the waterproofing effect of the roof can be increased together with solar power generation.

In addition, the present invention can form an indoor space surrounded by a wall under the solar roof, so that the solar power generation structure can be used as a warehouse, a greenhouse, and various spaces for leisure activities.

In addition, the present invention has the advantage of saving the fuel cost inside the building because the solar power generation structure installed on the roof blocks direct sunlight in summer and acts as a thermal insulation layer in winter.

1 is a perspective view showing a photovoltaic structure installed on the roof of a building according to an example of the present invention,
Figure 2 is a side view of Figure 1,
3 is an exploded perspective view of an excerpt of the main part applied to FIG. 1,
4 is a cross-sectional view of the main drain bracket applied to FIG. 1,
5 is a cross-sectional view of the sub drainage bracket applied to FIG. 1,
6 is a perspective view of a main drain bracket applied to a photovoltaic structure according to another example of the present invention,
7 is a cross-sectional view of a sub-drainage bracket applied to a photovoltaic structure according to another example of the present invention,
8 is a perspective view showing a photovoltaic structure installed on the roof of a building according to another example of the present invention,
9 is a cross-sectional view of FIG. 8.

Hereinafter, a solar power generation structure on the roof of a building according to a preferred embodiment of the present invention will be described in detail.

Referring to Figures 1 to 5, the solar power generation structure of the present invention is installed on the top of the support frame 11 and the support frame 11 installed on the roof (1) provided on the upper part of the building to generate photovoltaic power generation. It is equipped with a solar roof 20 capable of this.

The support frame 11 is composed of a post 13 and a horizontal pipe 15 coupled to the upper portion of the post 13.

A number of posts 13 are installed at regular intervals. In the illustrated example, the posts are installed in three rows. The columns in the front row are separated from each other in the left and right directions, and a number of them are installed. And the middle row of pillars are separated from each other in the left and right direction, and a number of them are installed. The pillars in the middle row are formed higher than the pillars in the front row. In addition, a number of posts in the back row are spaced apart from each other in the left and right directions to be installed. The back row struts are formed higher than the middle row struts.

Posts 13 are installed in a certain sized area of the rooftop 1. Each post 13 may be fixed to the roof (1) floor with anchor bolts.

The horizontal pipe (15) is installed one for each row of the post (13). The horizontal pipe 15 is formed to be elongated to the left and right. The transverse pipe 15 is coupled to the upper end of the post 13.

The solar roof 20 is supported by the support frame 11 and can be generated by sunlight. The solar roof 20 is installed facing the south, and is installed inclined so that the front side is low and the rear side is high.

The solar roof 20 is installed under the solar panels 21 and is supported by the support frame 11 and a plurality of solar panels 21 spaced in the vertical and transverse directions and arranged in parallel. And a rainwater discharge means for discharging rainwater flowing into the spaced gap between the solar panels 21 to the second waterproofing means 50.

The solar panel 21 has a square shape, and a solar cell is mounted on the upper surface to generate electricity by sunlight.

The solar panels 21 are spaced apart in the longitudinal and transverse directions and are arranged side by side. In the illustrated example, 7 lines are made up of a total of 4 lines. Therefore, the total number of solar panels 21 is 28. It goes without saying that the size and number of solar panels can be appropriately changed depending on the size or shape of the solar roof 20, unlike shown.

In the solar roof 20, since a plurality of solar panels 21 are combined, a spaced gap is formed between the solar panels 21 adjacent to each other. For example, a gap 22 is formed in the longitudinal direction between the solar panels 21 adjacent to each other in the left and right direction, and a gap 22 is separated in the horizontal direction between the photovoltaic panels 21 adjacent to each other in the front and rear direction ( 23) is formed. Since rainwater flows in during rain through the spaced gaps 22 and 23 in the longitudinal and transverse directions, a rainwater discharging means for blocking the rainwater is provided.

The rainwater discharging means is located under the solar panels 21 and discharges rainwater flowing into the spaced gaps 22 and 23 in the longitudinal and transverse directions to the outside.

The rainwater discharging means is installed to correspond to the main drainage bracket 30 installed to correspond to the longitudinal separation gap 22 among the separation gaps, and the main drainage bracket 30 installed to correspond to the lateral separation gap 23 among the separation gaps. It is provided with a sub-drainage bracket 40 leading to 30).

The main drain bracket 30 is formed long in the longitudinal direction, that is, in the front-rear direction. The main drain bracket 30 is installed inclined so that the front is low and the rear is high. The main drain bracket 30 is coupled to the upper portion of the horizontal pipe 15. The main drain bracket 30 is installed in a direction crossing the horizontal pipe 15. The main drainage bracket 30 is spaced apart in the transverse direction, that is, in the left and right direction, and a plurality of the main drain brackets are installed side by side.

The main drainage bracket 30 forms a drainage channel inside and extends horizontally outward from the upper side of both sides of the channel 31 and the channel portion 31 formed to be elongated in the longitudinal direction, so that the lower portion of the solar panel 21 and the lower portion of the solar panel 21 The first horizontal side portion 33 to be coupled, the vertical side portion 35 extending vertically downward from the end of the first horizontal side portion 33, and horizontally outward from the end of the vertical side portion 35 It has a second horizontal side portion 37 which is extended and coupled to the horizontal pipe 15.

The channel portion 31 has an open top. For example, the waterway part 31 is formed by bent in the shape of a U-shaped open upward. The inner space of the water passage part 31 becomes a drainage passage through which rainwater flows.

The first horizontal side portion 33 is formed to be bent outward at the upper left and right sides of the channel portion 31. A plurality of elongated holes 34 are formed in the first horizontal side portion 33 to be coupled to the solar panel 21 by the bolts 5 at regular intervals. The long hole 34 is formed long in the front-rear direction.

The vertical side portion 35 is formed to be bent downward at the end of the first horizontal side portion 33.

The second horizontal side portion 37 is formed to be bent outward at the end of the vertical side portion 35. A plurality of through holes are formed in the second horizontal side portion 37 at regular intervals so that the bolts 6 can be coupled to the horizontal pipe 15.

In addition, as shown in FIG. 6, the second horizontal side portion 39 may be formed to extend horizontally inward from the end of the vertical side portion 35.

The sub-drainage bracket 40 is installed side by side with a plurality of the main drainage brackets 30 spaced back and forth.

The sub-drainage bracket 40 spans between two solar panels 21 adjacent to each other in the longitudinal direction and extends in the transverse direction and is vertically downward at both ends of the plate 41. A vertical bent portion 43 extending and in contact with the vertical side portion 35, and a horizontal bent portion 45 extending horizontally inward from the end of the vertical bent portion 43 and coupled to the second horizontal side portion 37 ).

The plate portion 41 is coupled to the lower portion of the adjacent two solar panels 21 to block the gap 23 in the transverse direction. Accordingly, the plate portion 41 is formed to have a wider width than the gap 23 in the transverse direction.

The vertical bent portion 43 is formed to be bent at a right angle at both left and right ends of the plate portion 41. The vertical bent portion 43 is in close contact with the vertical side portion 35 of the main drain bracket 30.

The horizontal bent portion 47 is formed to be bent at a right angle at the end of the vertical bent portion 43. A through hole into which the bolt 7 is inserted is formed in the horizontal bent portion 47. The horizontal bent portion 47 is fixed to the horizontal bent portion 47 of the main drain bracket 30 by the bolt 7. A through hole 38 is also formed in the horizontal bent portion 47 so that the bolt 7 can pass.

When raindrops fall into the solar roof 20 in rainy weather, rainwater flows through the solar panel 21 and flows into the longitudinal gap 22 and is discharged along the main drainage bracket 30. In addition, rainwater flowing into the lateral gap 23 moves along the sub drainage bracket 40, flows into the main drainage bracket 30 located in the left and right directions, and is discharged.

As described above, the present invention covers a certain area of the rooftop 1 by installing the solar power generation structure on the rooftop 1 of a building, so that the waterproofing effect of the rooftop 1 can be increased together with solar power generation. Therefore, the present invention can solve the waterproof problem that occurs on the conventional roof, thus extending the life of the building and increasing the value of the building.

Meanwhile, the present invention may further include a wall part 45 and an indoor space part 46 as another embodiment.

8 and 9, a wall part 45 is installed under the solar roof 20, and an indoor space part 46 is provided inside the wall part 45.

The wall part 45 may be installed on the outside or inside of the post 13. The wall portion 45 may be formed to surround the lower space of the solar roof 40 in the front, rear, left and right directions. Unlike this, one side of the wall portion 45 may be open. In addition, an entrance door may be installed on one side of the wall part 45.

The wall portion 45 may be provided with a lower wall 47 made of metal or synthetic resin, and an upper wall 49 made of transparent synthetic resin or glass.

The above-described wall part 45 has an indoor space part 46 of a certain size formed inside.

The upper part of the indoor space 46 is covered by the solar roof 20. The indoor space unit 46 can be used as a warehouse, a greenhouse, or a variety of spaces for leisure activities, thereby increasing the usefulness and utility of the building rooftop (1).

In addition, the indoor space unit 46 has an advantage of reducing the temperature fluctuation range inside the building because it serves as an insulating layer. Therefore, by blocking direct sunlight in summer, the temperature rise inside the building is reduced, and in winter, the cold is prevented to reduce the temperature drop inside the building.

7 shows another example of the sub drainage bracket 40 applied to the present invention.

Referring to FIG. 7, the sub-drainage bracket 40 is installed to be detachably attached to a pair of protruding protrusions 60 and protruding protrusions 60 formed on the upper portion of the plate part 40. A watertight kit part 70 filled with an adhesive 77 is further provided therein so as to leak the adhesive 77 when pressed against the side surface.

The protruding jaw 60 is formed on the plate portion 41. The protruding jaw 60 is formed to be elongated along the length direction of the plate portion 41. The protruding jaws 60 are formed around both edges of the plate portion 41, respectively. The protruding jaw 60 is made of a right triangle having a cross section. The side surface of the solar panel 21 is in close contact with the protruding jaw 60.

The watertight kit part 70 is installed on one surface of the protruding protrusion 60. The watertight kit part 70 may be spaced up and down so that two watertight kit parts 70 may be installed side by side. The watertight kit part 70 is coupled to the protruding jaw 60 so as to be detachable. A coupling groove is formed in the protruding jaw 60. The coupling groove is formed in a form with a narrow entrance and a wide interior. The coupling groove is formed to be elongated along the length direction of the protruding jaw (60).

The watertight kit part 70 includes a sliding rail 71 coupled to the coupling groove, a watertight feather 75 formed on one side of the sliding rail 71 to protrude out of the protruding jaw 60, and a watertight feather It has a pressure-sensitive adhesive (77) filled in the inside of (75).

The sliding rail 71 has a shape corresponding to the coupling groove. These sliding rails 71 are inserted into one side of the coupling groove to allow sliding movement along the coupling groove.

The watertight blade 75 is formed on one side of the sliding rail 71. The watertight feather 71 is made of an elastic material such as rubber or silicone, which is easily elastically deformed.

The inside of the watertight feather 75 is empty, and the adhesive 77 is filled in the empty inner space. As the pressure-sensitive adhesive, a conventional polymeric binder in a liquid or paste state or a silicone resin for sealing may be used.

The watertight feather 75 is formed to become narrower toward the end. And the watertight feather 75 is formed to be inclined downward.

An incision slit 76 cut into a straight line is formed on the top of the watertight feather 75. Since the watertight feather 75 is made of an elastic material, the incision slit 76 is closed in normal times.

When the side surface of the solar panel 21 is in close contact with the protruding jaw 60, the watertight blade 75 is compressed, and when the watertight blade 75 is compressed, the end of the solar panel 21 is bent downward and the incision slit 76 is opened. Accordingly, the adhesive 77 filled in the watertight blade 75 flows out through the incision slit 76, and the spilled adhesive 76 fills the contact gap between the watertight blade 75 and the solar panel 21. .

The watertight kit portion 70 described above can effectively seal between the plate portion 41 and the solar panel 21, so that water leakage can be prevented in advance.

In the above, the present invention has been described with reference to an embodiment, but this is only exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent embodiments are possible therefrom. Therefore, the true scope of protection of the present invention should be determined only by the appended claims.

1: roof top 11: support frame 13: support 15: horizontal pipe
20: solar roof 21: solar panel
30: main drain bracket 40: sub drain bracket
45: wall part 51: cover

Claims (5)

A support frame part installed on the roof provided on the upper part of the building;
It has a solar roof installed on the upper part of the support frame and capable of photovoltaic power generation,
The solar roof is a plurality of solar panels spaced in vertical and transverse directions and arranged side by side, installed under the solar panels, supported by the support frame, and formed into a spaced gap between the solar panels. It has a rainwater discharge means for discharging the incoming rainwater to the outside,
The rainwater discharging means includes a main drain bracket installed to correspond to a gap in a longitudinal direction among the gaps, and a sub drain bracket installed to correspond to a gap in a lateral direction among the gaps to guide rainwater to the main drain bracket. And,
The main drainage bracket has an upper portion open to form a drainage passage inside and a longitudinally elongated water channel portion, and a first horizontal side that extends horizontally outward from the top of both sides of the water channel portion and is coupled to the lower portion of the solar panel. A portion, a vertical side portion extending vertically downward from an end portion of the first horizontal side portion, and a second horizontal side portion extending horizontally outward from an end portion of the vertical side portion and coupled to the support frame portion,
The sub-drainage bracket is a plate part formed long in a horizontal direction and spanned between two adjacent solar panels in a longitudinal direction, and a vertical bent extending vertically downward from both ends of the plate part to contact the vertical side part. And a horizontal bent portion extending horizontally inward from an end portion of the vertical bent portion and coupled to the second horizontal side portion,
The sub-drainage bracket is a pair of protruding jaws formed on the upper portion of the plate portion, and is installed to be detachably attached to the protruding jaws, and a watertight kit filled with an adhesive to leak the adhesive when pressed against the side surface of the solar panel. A solar power generation structure on the roof of a building, characterized in that it further comprises a part. The sun on a roof of a building according to claim 1, further comprising a wall part installed below the solar roof, and an indoor space part provided inside the wall part and covered by the solar roof. Photovoltaic structures. delete delete delete

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