KR20190012634A - Solar power roof - Google Patents

Abstract

The present invention relates to a solar power generation roof capable of remarkably preventing leakage. According to the present invention, the solar power generation roof comprises: a plurality of H beams (1) disposed by being spaced apart from each other at predetermined intervals and installed by allowing a rear portion of each H beam to be installed by a vertical height difference of Δh in comparison with a front portion; a plurality of purlins (10) including first and second purlins (11, 16) to be spaced apart from each other at predetermined intervals so as to section a space mounting an insulation material (3) therein, and fixed and coupled to the upper surface of the H beam (1); a plurality of spacing adjustment pipes (20) installed on the upper part of the purlin (10) by being spaced apart from each other at predetermined intervals while being perpendicular to the purlin (10), having a cutoff groove (22) longitudinally formed on each upper surface, and having a flowing water guide (24) formed therein; a plurality of connection brackets (30) disposed along the cutoff groove (22) of the spacing adjustment pipe (20) by being spaced apart from each other at predetermined intervals; a support bracket (40) closely placing left and right end parts to left and right sides with respect to the central portion of a first vertical end (34) of each connection bracket (30), respectively, while being perpendicular to each purlin (10); and a solar panel (50) to couple a front portion to a second mounting end (46) of one support bracket from adjacent support brackets (40) and to couple a rear portion to a first mounting end (44) of the other side support bracket from the adjacent support brackets.

Description

Solar power roof {Solar power roof}

The present invention relates to a photovoltaic power generation roof, more specifically, a simpler structure that can be easily applied to buildings having various structures, as well as easy maintenance after installation, and furthermore, Which is about a solar power roof.

As a means of converting light energy transferred from the sun into electric energy, the solar panel is environmentally friendly as compared with a carbon energy source which can cause environmental pollution. Due to the fact that the energy can be supplied infinitely, The installation of industrial buildings as well as houses is rapidly increasing.

In order to install a solar panel on a building, a certain area of installation space is required. However, the installation of a solar panel on a roof or a roof of a conventional building may be performed after dismantling a part of the roof or the roof, As well as a separate mechanism for supporting the solar panels on the roof or roof.

However, in this case, the former may cause rainwater to flow in between the adjoining solar panels, which may lead to the problem of complicated drainage facilities, and the latter may cause damage or modification to the roof or roof of the building There is a problem that the appearance of the building is seriously damaged.

Korean Patent Publication No. 2011-0100979

It is an object of the present invention to provide a photovoltaic (PV) generator roof which can function as a roof of a building and significantly improve the leakage phenomenon.

In order to achieve the above object, the present invention provides an H beam (1) arranged at a predetermined distance from each other, a hollow panel (2) installed at a predetermined distance above the H beam (1) A solar power generating roof comprising a heat insulating material (3) to be laid and a solar panel for sealing the upper surface of the heat insulating material (3), the solar power generating roof comprising a plurality of solar cells An H beam (1) installed with a vertical height difference by? H; A first mounting end 12 for receiving the end portion of one side of the perforated panel 2 is provided on the lower side and a first slide end 13 is provided on the upper end, And a second fixing step 17 for fixing the end portion of the other side perforated panel 2 is provided on the lower side of the first perforation 11, A second slide end 18 spaced apart from the slide end 13 by a predetermined distance is provided and a second bent part 19 protruding outward in the other direction is provided below the second slide end 18, And a second purlin 16 which is in close contact with the central portion of the H beam 1 and is fixedly coupled to the upper surface of the H beam 1 while defining a space in which the heat insulating material 3 is placed in a state of being spaced apart from each other A plurality of purlin (10); (22) is formed on the upper surface of the perforation (10), and a water guide (24) is formed in the upper part of the perforation (10) An interval controlling tube 20 in which the tube 20 is formed; Each having a first vertical end 32 coupled to the support frame 20 and a first vertical end 34 projecting vertically at one end of the first horizontal end 22, A plurality of connection brackets (30) arranged along the cutout grooves (22) of the gap control tube (20); And each has a second vertical end 42 coupled with the first vertical end 34 of the connection bracket 30 and a first horizontal end 34 of the connection bracket 30 at the lower end of the first vertical end 42. [ And a second mounting end 46 protruding in the same direction as the first mounting end 44 at an upper end of the first vertical end 42, A support bracket 40 which is positioned adjacent to the left and right sides of the center of the first vertical end 34 of each connection bracket 30 with the left end and the right end thereof being balanced with the purlin 10; Each of the left side and the right side being formed at a predetermined distance from the cutting gap 22 of each of the gap adjusting pipes 20, And a solar panel 50 coupled to the stationary end 46 and coupled to the first stationary end 44 of the other support bracket among the adjacent support brackets 40 .

A plurality of first truss members 7 are zigzagged between the H beam 1 and the auxiliary H beams 6 in the vertical direction below the respective H beams 1, One end of each first truss member 7 is coupled to the H beam 1 and the other end of each first truss member 7 is coupled to the auxiliary H beam 6, A plurality of second truss members (7) are coupled to each other between the beams (6), and one end of each second truss member (7) is connected to a lower portion of the pulley (10) The other end of the member 7 can be coupled to the auxiliary H beam 6.

A roof of a building is constituted by a plurality of continuous solar panels provided with connection brackets and support brackets on the upper part of a perine supported by H beams, and rainwater is guided to the outside between the perine and the connection brackets to discharge It is very easy to install and maintain maintenance even after construction, and furthermore, it can prevent leakage of rainwater into the building due to rainwater.

In addition, the present invention has an advantage in that it can be applied very easily to buildings having various shapes and sizes by proposing a structure in which a separate truss structure is disposed in a lower part of a solar power generating roof.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a solar power generating roof according to the present invention. FIG.
2 is a schematic cross-sectional structural view of line AA 'in FIG.
3 is a schematic cross-sectional structural view of line BB 'in FIG.
Fig. 4 is a schematic view showing a connection structure between a gap adjusting tube, a connecting bracket, and a supporting bracket in the present invention; Fig.
FIG. 5 is a schematic side view illustrating a structure of a lower portion of a solar power generating roof according to the present invention. FIG.
FIG. 6 is a schematic side view of a structure of a lower portion of a solar power generating roof according to the present invention. FIG.
7 is a schematic view of a conventional solar power generating roof.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

1 is a schematic view of a solar power generating roof according to the present invention. As shown in the drawing, the H beam 1, the perforated panel 2, the heat insulating material 3, the purlin 10, An interval adjusting pipe 20, a connecting bracket 30, a supporting bracket 40, and a solar panel 50. [ Hereinafter, each of these configurations will be described in detail.

The H beams 1 have a predetermined length and are arranged so as to be spaced apart from each other by a predetermined distance. The rear portion of each of the H beams 1 is installed to have a difference in vertical height by Δh as compared with the front portion . That is, in the roof of the building, the vicinity of the ridge is arranged to have a certain vertical height with respect to the vicinity of the eave in order to guide the rainwater to the eave of the building through the space controlling pipe 20 to be described later.

The perforated panel 2 is composed of a plurality of apertures spaced apart from each other by a predetermined distance, and is installed above the H beam 1 at a predetermined interval. The specific shape of the perforated panel 2 can be variously changed. The heat insulating material (3) is placed on the upper surface of the perforated panel (2). The width and kind of the insulation can be variously changed according to the structure and use of the building.

The furnace 10 is a means for partitioning the heat insulating material 3 while supporting the perforated panel 2 and is composed of first and second furnaces 11 and 16, And is fixedly coupled to the upper surface of the H beam 1.

4, the first ferrule 11 is provided with a first stationary end 12, a first slide end 13, and a first bent portion 14, as shown in Fig. The first mounting end 12 is provided on the lower side of the first furnace 11 and the end portion of the perforated panel 2 located on one side is mounted on the first mounting end 12 as shown in FIG. The first slide end (13) is provided at the upper end of the first purlin (11). The first bent portion 13 is spaced apart from the first slide end 13 by a predetermined distance, and protrudes outward in one side as shown in the drawing.

The second perforation 16 is provided with a second staging end 17, a second slide end 18 and a second bending portion 19, and the central portion thereof is in close contact with the central portion of the first purin 11 . The second mounting stage 17 is provided on the lower side of the second purlin 16 and the end portion of the perforated panel 2 located on the other side is fixed to the second mounting stage 17 as shown in FIG. The second slide end 18 is provided at the upper end of the second purin 16. The second bending portion 19 is spaced apart from the second slide end 18 by a predetermined distance and protrudes outward in the opposite direction to the first bending portion 14. Accordingly, a certain inner space is formed between the first and second bent portions 14 and 19. [

Reference numerals 112 and 114 denote engaging pieces and fastening bolts, respectively. As shown in FIG. 2, the coupling piece 112 is a part that mediates coupling with the hole panel 2, and the coupling bolt 114 is a means for fixedly coupling the pulley 10 to the H beam 1.

The interval adjusting pipe 20 adjusts the width of the solar panel 50 having various widths to be described later and guides the rainwater flowing into the building through the gap between adjacent solar panels 50 And discharging it to the outside. Since the rear side portions of the H beams 1 are provided so as to have a difference in vertical height by Δh as compared with the front side portions, the spacing regulating plate 20 also has ΔH As shown in FIG.

As shown in FIG. 1, the gap control tubes 20 are formed on the top of the perforation 10 so as to be orthogonal to the perforations 10 and spaced apart from each other by a predetermined distance. And a flow guide 24 is formed in the cut groove 22. The flow guide 24 is formed in the cut groove 22,

The cutout groove 22 is a portion where rainwater flowing through a gap between adjacent solar panels 50 drops and is a portion to which a gap adjusting bolt 31 to be described later is coupled and fixed. The water guide 24 is a passage for rainwater falling through the incision groove 22, and the rainwater through the water guide 24 is drained to the eaves of the building as shown in Fig. The gap adjusting pipe may be made of C-shaped steel.

자 구조로 이룬다. 즉, 각 연결브라켓(30)에는 하측 부위를 이루는 제1수평단(32), 그리고 제1수평단(22)의 일측 단부에서 수직으로 돌출되는 제1수직단(34)이 마련될 수 있다.The connection brackets 30 are spaced apart from each other by a predetermined distance and are arranged along the cutout groove 22 of the gap adjusting pipe 20,

It is formed by self structure. That is, each connecting bracket 30 may be provided with a first horizontal end 32 forming a lower portion and a first vertical end 34 vertically protruding from one end of the first horizontal end 22.

4, the connection bracket 30 is coupled with the first horizontal end 32 through the cutout groove 22 of the support frame 20 by the gap adjusting bolt 31, And are fixedly coupled with each other by a predetermined distance along the cutout grooves 22 of the support frame steel 20 in accordance with the width of the support frame 50.

자 구조로 이루어질 수 있다.The support bracket 40 is a means for supporting the solar panel 50. The support bracket 40 is a means for supporting the solar panel 50. The support bracket 40 is in the state of being balanced with each purlin 10 as shown in Fig. (34). Each support bracket (40)

Structure.

A second vertical end 42 having a predetermined vertical height and engaged with the first vertical end 34 of the connection bracket 30 and a second vertical end 42 coupled to the connection bracket 30 at a lower end of the first vertical end 42, A first mounting end 44 protruding in a direction opposite to the first mounting end 44 and a second mounting end 44 projecting in the same direction as the first mounting end 44 at an upper end of the first vertical end 42 46 may be provided.

자 구조로 이루어질 수 있다. 미설명 도면부호 43은 일측이 개구된 거치공간이다. Each of the left end and the right end of the second vertical end 42 is engaged with the first vertical end 34 of the connection bracket 30 by a separate fastening bolt 35. The second mounting stage (46)

Structure. Reference numeral 43 is a mounting space with one side opened.

The solar panel 50 is made up of a plurality of pieces supported by the support bracket 40. More specifically, as shown in Fig. 2, the front portion of each solar panel 50 is coupled to the second mounting stage 46 of the support bracket installed on one side of the adjacent support bracket 40, Is attached to the first mounting end 44 of the supporting bracket provided on the other side of the adjacent supporting brackets 40.

The reference numeral 35 denotes a means for coupling the rear portion of the solar panel 50 to the first fixed end 44 of the support bracket 40 and the first vertical end 34 of the connection bracket 30, Reference numeral 45 denotes means for coupling the front side portion of the solar panel 50 to the second mounting end 46 of the support bracket 40.

Each of the left side surface and the right side surface of each solar panel 50 is located a certain distance away from the cutting gap 22 of each gap adjusting tube 20, as shown in Figs. 2 and 3, respectively. The rainwater flowing through the gaps between adjacent solar panels 50 is moved into the gap adjusting pipe 20 through the cutout grooves 22 of the gap adjusting pipes 20, 20 through the flow guide 24 of the flow guide.

In the meantime, the present invention does not exclude the case where the structure as described in each of Figs. 5 and 6 is provided in the lower part of the solar power generating roof. That is, the auxiliary H beam 6 is installed in the vertical lower portion of each H beam 1, the H beam 1 and the auxiliary H beam 6 are connected to each other by the first truss member 7, 10 and the auxiliary H beams 6 are connected to each other by the second truss member 8.

At this time, a plurality of first truss members 7 are zigzagged between the H beam 1 and the auxiliary H beam 6 as shown in the figure, and one end portion of each first truss member 7 is connected to the H beam 1 , And the other end portion of each first truss member 7 is fixedly coupled to the auxiliary H beam 6. [ The second truss member 8 is composed of a plurality of members spaced apart from each other by a predetermined distance between the purlin 10 and the auxiliary H beam 6. One end of each second truss member 7 is connected to the pulley 10, And the other end portion of each second truss member 7 extending at a predetermined angle inclination is fixedly coupled to the auxiliary H beam 6. [

In this case, the H beam 1 is connected to the auxiliary H beam 6 by the plurality of first truss members 7, and the perine 10 is connected to the auxiliary H beam 6 by the plurality of second truss members 8 6), the solar power generating roof can be more stably supported by the truss structure, so that the present invention can be applied to large buildings. Each of the first and second truss members may be formed of a tube or a circular tube, and at both ends thereof, an H-beam, an auxiliary H-beam, and a coupling end for coupling with each of the pulleys are preferably provided.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

1: H beam 2: perforated panel
3: Insulation 10: Purine
20: spacing tube 30: connection bracket
40: support bracket 50: solar panel

Claims (2)

An H beam 1 disposed at a predetermined distance from each other, a perforated panel 2 spaced at a predetermined distance above the H beam 1, a heat insulating material 3 placed on the upper surface of the perforated panel 2, A solar power generating roof comprising a solar panel sealing an upper surface thereof,
An H-beam (1) having a plurality of vertically spaced-apart H-beams, each of which has a height difference of? H with respect to a front portion thereof;
A first mounting end 12 for receiving the end portion of one side of the perforated panel 2 is provided on the lower side and a first slide end 13 is provided on the upper end, And a second fixing step 17 for fixing the end portion of the other side perforated panel 2 is provided on the lower side of the first perforation 11, A second slide end 18 spaced apart from the slide end 13 by a predetermined distance is provided and a second bent part 19 protruding outward in the other direction is provided below the second slide end 18, And a second purlin 16 which is in close contact with the central portion of the H beam 1 and is fixedly coupled to the upper surface of the H beam 1 while defining a space in which the heat insulating material 3 is placed in a state of being spaced apart from each other A plurality of purlin (10);
(22) is formed on the upper surface of the perforation (10), and a water guide (24) is formed in the upper part of the perforation (10) An interval controlling tube 20 in which the tube 20 is formed;
Each having a first vertical end 32 coupled to the support frame 20 and a first vertical end 34 projecting vertically at one end of the first horizontal end 22, A plurality of connection brackets (30) arranged along the cutout grooves (22) of the gap control tube (20);
And each has a second vertical end 42 coupled with the first vertical end 34 of the connection bracket 30 and a first horizontal end 34 of the connection bracket 30 at the lower end of the first vertical end 42. [ And a second mounting end 46 protruding in the same direction as the first mounting end 44 at an upper end of the first vertical end 42, A support bracket 40 which is positioned adjacent to the left and right sides of the center of the first vertical end 34 of each connection bracket 30 with the left end and the right end thereof being balanced with the purlin 10;
Each of the left side and the right side being formed at a predetermined distance from the cutting gap 22 of each of the gap adjusting pipes 20, A solar panel 50 coupled to the stationary end 46 and coupled to the first stationary end 44 of the other support bracket among the adjacent support brackets 40
A photovoltaic roof comprising: The method according to claim 1,
A plurality of first truss members 7 are zigzagged between the H beam 1 and the auxiliary H beams 6 in the vertical direction below the respective H beams 1, One end of each first truss member 7 is coupled to the H beam 1 and the other end of each first truss member 7 is coupled to the auxiliary H beam 6, A plurality of second truss members (7) are coupled to each other between the beams (6), and one end of each second truss member (7) is connected to a lower portion of the pulley (10) And the other end of the member (7) is coupled to the auxiliary H beam (6).

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