KR101982769B1 - Solar Power Generation Structure for Roof and Its Construction Method - Google Patents

Abstract

The present invention relates to a photovoltaic power generation structure for a roof and a construction method therefor. The purpose of the present invention is to install and construct a photovoltaic power generation apparatus on a roof, and specifically, allow a worker to quickly assemble materials on the roof only by bolts (or bolts and nuts) without welding, thereby increasing constructability and preventing a fall of the worker. According to the present invention, the photovoltaic power generation structure for a roof comprises: a support (10) erected on a roof; a pillar (20) assembled on the support to be adjustable in angle; a girder (30) assembled on the pillar; girder assembly brackets (60) assembling the pillar and the girder; a purlin (40) assembled on the girder in the direction orthogonal to the girder; and a solar module (50) assembled on the purlin. The girder assembly brackets assembled to each other through bolts on both sides of the pillar and the girder to cover the pillar and the girder each include: a pillar support portion (61) assembled to the pillar through the bolts while covering the pillar; a girder support portion (62) extending from the pillar support portion and assembled to the girder through the bolts while covering the girder mounted on the pillar; pillar support protrusions (63) protruding from both sides of the pillar support portion to support the pillar; and a girder support protrusion (64) protruding from one or more of upper and lower portions of the girder support portion to support the girder.

Description

Solar Power Generation Structure for Roof and Its Construction Method

The present invention relates to a fixing device for a photovoltaic power generation structure, and more particularly, to install a photovoltaic device on a roof and to assemble a material using only bolts (or bolts and nuts) without welding. It relates to a photovoltaic structure and its construction method.

This section provides background information related to the present application but is not necessarily prior art.

 In general, photovoltaic devices generate power using the light of the sun, and integrate a solar cell that converts solar energy directly into electrical energy into a plate shape to produce a large amount of electrical energy at the same time. As is gradually exhausted, the demand is gradually increasing as one of the alternative energy.

Such a photovoltaic device is typically installed on the roof or rooftop of a building where sunlight is smoothly irradiated, and includes a separate support for installation on the roof.

The support is composed of a pillar standing on the roof, a girder installed on the pillar, a purlin installed on the girder, and a photovoltaic module installed on the perlin.

The solar photovoltaic structure for the roof according to the prior art is constructed by a method in which a worker climbs on the roof and directly installs and assembles a pillar, and the pillar, the girder, the girder, and the perlin are subjected to the work of the worker assembling by welding. Therefore, there is an inconvenience of carrying the welding machine to the roof and carrying it back to the ground after the completion of the work, and the welding work on the roof is a high level work and the welding work has a risk factor, causing a safety accident such as a worker's fall. .

Due to this problem, the worker weakens the welding of pillars and girders, girders and perlins, and poses a risk of collapse of solar structures during strong winds and earthquakes.

Utility Model Registration No. 20-0481087

The present invention is to solve the problems as described above, the solar photovoltaic power generation structure for assembling the material using only bolts (or bolts and nuts) without using welding and installing the solar power generator on the roof and The purpose is to provide a construction method thereof.

The roof fixing device of the solar cell module according to the present invention, the support is built on the roof; A pillar assembled on the support to be adjustable in angle; A girder assembled on the pillar; A girder assembly bracket for assembling the pillar and the girder; Perlin assembled on the girder in a direction orthogonal to the girder; And a solar module assembled on the perlin, wherein the girder assembly bracket covers the pillar and the girder on both sides of the pillar and the girder, and is assembled to each other through bolts, and covers the pillar and through the pillar and the bolt. A pillar support unit to be assembled, a girder support unit extending from the pillar support unit and covering the girder mounted on the pillar and assembled through the girder and the bolt, a pillar support jaw formed to protrude on both sides of the pillar support unit, and supporting the pillar; It is characterized in that it comprises a girder support jaw is formed protruding on one or more of the upper and lower girder support portion to support the girder.

According to the solar photovoltaic power generation structure and construction method thereof according to the present invention, the pillars, girders, girders and perlins are assembled using only bolts or bolts and nuts, and the fastening of the bolts can be performed using only a small portable tool. It is possible to assemble materials with a large combined strength, so it is possible to increase the stability of photovoltaic power generation structure, to make the aerial work on the roof very easy, and to free the worker's activity on the roof, thereby preventing safety accidents such as worker's fall accident. There is.

1 is a side view showing a construction state of a solar photovoltaic structure for a roof according to the present invention.
Figure 2 is a plan view of the support applied to the roof solar power structure according to the present invention.
Figure 3 is a plan view of a column applied to the roof solar power structure according to the present invention.
Figure 4 is a side view showing the assembled state of the support and the pillar applied to the solar photovoltaic structure for the roof according to the present invention.
Figure 5 is an exploded perspective view showing a spacer between the support and the column applied to the roof solar power structure according to the present invention.
Figure 6 is a side view showing a state of assembly of the pillars and girders applied to the solar photovoltaic structure for the roof according to the present invention.
Figure 7 is a front view of the girder assembly bracket applied to the roof solar power structure according to the present invention.
Figure 8 is a perspective view of the girder assembly bracket applied to the roof solar power structure according to the present invention.
Figure 9 is a side view showing a spacer between the column and the girder applied to the roof solar power structure according to the present invention.
Figure 10 is an exploded perspective view of the girder and perlin showing the perlin assembly bracket applied to the roof solar power structure according to the present invention.
11 to 13 are a perspective view and a side view and a plan view showing a foothold applied to the roof solar power structure according to the present invention, respectively.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

As shown in FIG. 1, the roof photovoltaic power generation structure according to the present invention includes a support 10 installed on the roof 1, a pillar 20 assembled on the support 10, and assembled on the pillar 20. Girder (30), Perlin (40) to be assembled on the girder (30), consisting of a solar module 50 supported on the perlin 40, characterized in that they are assembled to each other through a non-welding bolt type There is this.

The support 10 is preferably a square tube (square), and a fixing plate fixed to the roof 1 at the bottom thereof, and a flange 11 for assembling the pillar 20 at the upper portion thereof.

As shown in FIG. 2, the flange 11 is quadrangular and bolt holes 12 are provided at four corners.

As shown in Figs. 3 and 4, the column 20 is preferably a square tube (square) and the bottom is provided with a fixing plate 21 which is assembled corresponding to the flange 11 of the support 10.

The pillar 20 is assembled to adjust the angle with respect to the support 10 so that the photovoltaic module 50 can be installed at an optimal angle regardless of the angle of the roof 1, and the bolt hole 12 of the support 10 And a total of eight angle adjusting holes 23 for adjusting angles of the bolt holes 22 and the pillars 20, and fixing bolts 24 and angle adjusting fastened to the bolt holes 12 and 22. Bolts 25 are configured together.

Angle adjustment holes 23 are formed on the left and right sides with respect to the bolt hole 22, respectively. That is, two angle adjusting holes 23 are formed in one bolt hole 22, and a total of eight angle adjusting holes 23 are formed, and the pillar 20 is minutely formed by eight angle adjusting bolts 25. It is possible to adjust the angle.

The angle adjusting bolt 25 is screwed into the angle adjusting hole 25 formed in the fixing plate 21 of the pillar 20, and the end thereof contacts the flange 11 of the support 10 so that the pillar 20 is angle-adjusted. Keep it.

The fixing bolt 24 passes through the bolt hole 22 of the pillar 20 and the bolt hole 12 of the support 10, and then assembles the support 10 and the pillar 20 by fastening nuts. The fastening of the fixing bolt 24 is to be fastened to the support 10 and the pillar 20 in an angle adjusted by the angle adjusting bolt 25.

In addition, a spacer 26 (see FIG. 5) interposed between the flange 11 of the support 10 and the fixing plate 21 of the pillar 20 may be included.

The spacer 26 is an elastic material (rubber or the like) that is elastically deformed by an external force so as not to interfere with the angle adjustment of the pillar 20, that is, the compression deformation when the angle of the fixing plate 21 is adjusted.

The support 10 and the pillar 20 are installed in a quantity depending on the size of the photovoltaic module 50 and the like, and a plurality of them are installed in the form of points at regular intervals along the vertical and horizontal directions. That is, the pillar 20 may be installed in a plurality of rows and one row may support one girder 30.

The girder 30 is preferably a square tube (square) and is assembled on three rows of pillars 20 based on FIG. 1.

6 to 8, the girder 30 is assembled with the pillar 20 by the girder assembly bracket 60.

The girder assembly bracket 60 is configured as follows so that the pillar 20 and the girder 30 do not fall off due to strong winds and earthquakes. The girder assembly bracket 60 has an area covering the pillar 20 and one or more pillars 20 and one or more (in the drawings, 2). Column support 61 is fixed to the bolt of the bolt, the upper portion of the column support 61 is formed in a wider area to the left and right than the pillar support 61, and the girder 30 and one or more (shown as two in the drawing) It consists of a girder support portion 62 is fixed with a bolt of, the pillar support portion 61 and the girder support portion 62 is formed in the same plane, the form to cover and fix the pillar 20 and the girder 30 on both sides. Used as

Here, at least one pillar support jaw 63 and girder support 62 which are formed to protrude in a direction orthogonal to the pillar support 61 on both left and right sides of the pillar support 61, respectively surrounding both sides of the pillar 20. One or more girder support jaw 64 is formed to protrude in the direction orthogonal to the girder support 62, respectively, at the upper or upper portion of the girder support 62.

According to such an assembly structure, the girder assembly bracket 60 is fixed to the pillar 20 and the girder 30 with bolts, respectively, and the pillar 20 and the pillar support jaw 63 and the girder support jaw 64. Because it wraps the girder 30 to prevent the twist and fall of the pillar 20 and the girder 30 during a strong wind or earthquake.

A triangular empty space is formed between the upper end of the pillar 20 and the bottom of the girder 30, and a spacer 65 (see FIG. 9) may be applied to the space.

The spacer 65 may be triangular and elastic material or iron plate, and may be inserted between the pillars 20 and the girders 30 and then fixed by the girder assembly brackets 60 on both the left and right sides.

In addition, a bottom pipe inserted into the pillar 20 may be added to the bottom of the girder 30.

The girder 30 and the perlin 40 are assembled via the perlin side saddle 70.

The furlin side saddle 70 is formed to surround three surfaces (bottom, left and right sides) of the girder 30 and has flanges 71 provided with bolt holes at both ends thereof.

The perlin 40 is preferably a square tube, and a fixing plate 41 having a bolt hole formed on the bottom thereof is fixed by welding. Of course, the perlin 40 is provided with a bolt through hole communicating with the bolt hole of the fixing plate 41 at the bottom. Welding is the work done in the factory.

The girder 30 and the perlin 40 are inserted by inserting the perlin side saddle 70 from the bottom of the girder 30 to the top and fastening bolts to the bolt holes formed in the flange 71 and the fixing plate 41 of the perlin 40. Fix it.

The solar module 50 is a known product and is assembled to the perlin 40 by bolts.

As shown in Figures 11 to 13, the present invention is applied to the scaffold 80 for the maintenance of the photovoltaic structure.

The scaffold 80 is installed in one or more steps along the solar module 50, and the scaffold fixing bracket 81 and the scaffold fixing bracket 81 for installing the two-stage scaffold 80 having different heights are pillars. The footrest side saddle 82 and the inclined brace 83 which are fixed to 20 are included.

The scaffold fixing bracket 81 is formed in the form of a step and includes two horizontal portions 81-1 and 81-2, that is, the first horizontal portion 81-1 and the first horizontal portion 81-1. It consists of a vertical portion (81-3) extending to the upper portion of, a second horizontal portion (81-2) extending horizontally from the vertical portion (81-3). In addition, scaffolding fasteners 81-4 are formed on the first and second horizontal portions 81-1 and 81-2 to fix the scaffolds 80, respectively.

The footrest fastening portion 81-4 may include a space into which the footrest 80 is inserted and may be configured as a tightening bolt for fixing the footrest 80 inserted into the space.

The footrest side saddle 82 has a structure surrounding three sides of the pillar 20 and a flange is formed on both sides, and the flange is fixed through the foothold fixing bracket 81 and a bolt, thereby securing the foothold fixing bracket 81 to the pillar 20. Fix it.

In addition, a bolt passing through the footrest side saddle 82 and the pillar 20 and the foothold fixing bracket 81 may be included to secure the foothold fixing bracket 81.

The inclined brace 83 is disposed to be inclined at the bottom of the scaffold fixing bracket 81, and the bottom and the top are fixed to the first and second horizontal portions 81-1 and 81-2 through bolts, respectively, to secure the scaffold 80. I support it.

Alternatively, it is also possible to fix the inclined brace 83 to the pillar 20.

For example, the inclined brace 83 has a first inclination fixed to the column fixing part 83-1, the column fixing part 83-1, and the first horizontal part 81-1 fixed to the pillar 20. It consists of a part 83-2, the column fixing part 83-1, and the 2nd inclination part 83-3 fixed to the 2nd horizontal part 81-2.

The pillar fixing part 83-1 is assembled through the flanges and bolts of the birds on the three sides of the pillar 20 and the other side of the pillar 20 and the first and second inclined portions 83-2 and 83. -3) consists of brackets each assembled through bolts.

The construction method of the photovoltaic power generation structure for a roof according to the present invention is as follows.

1. Support installation.

A plurality of supports 10 are installed on the roof 1. The plurality of supports 10 are arranged at a predetermined interval from each other for stable support of the photovoltaic module 50, and are installed through bolts fastened to the fixing plate and the roof 1 of the bottom.

2. Pillar assembly.

Assembling and standing the pillar 20 on the support 10, specifically described, raise the fixing plate 21 of the pillar 20 on the flange 11 of the support 10 to fasten the fixing bolt 24. However, in order to adjust the angle of the pillar 20, the fixing bolt 24 and the nut are loosely fastened so that the pillar 20 moves.

Adjusting the angle of the pillar 20 while turning a total of eight angle adjusting bolts 25 installed in four places of the pillar 20 in both directions, and after completing the angle adjustment, tighten the fixing bolt 24 to secure the pillar 20. Fix it.

3. Girder installation.

For example, the pillar support 61 of the girder assembly bracket 60 is padded on the pillar 20 and fixed with bolts, and then the girder 30 is formed on the girder support 62 and the girder support jaw 64 of the girder assembly bracket 60. ) To assemble the girder 30 to the pillar 20 by fastening the bolts.

4. Perlin assembly.

For example, put the perlin 40 on the girder 30 and cover the perlin side saddle 70 from the bottom of the girder 30 to fasten the bolts in the perlin side saddle 70 and the bolt holes of the perlin 40. Perlin 40 is assembled.

5. Install solar power module.

Raise the photovoltaic module 50 on the Perlin 60 installed through the above process and assemble by fastening bolts.

10: support, 20: pillar
30: girder, 40: furlin
50: solar module, 60: girder assembly bracket
70: Perlin saddle, 80: scaffold
81: footrest fixing bracket, 82: footrest side saddle

Claims (9)

A support (10) built on the roof;
A pillar 20 which is assembled to adjust the angle on the support;
A girder 30 assembled on the pillar;
Covering the pillar and the girder on both sides of the pillar and the girder and being assembled to each other through bolts, the pillar supporting portion 61 assembled through the pillar and the bolt covering the pillar and extending from the pillar supporting portion and above the pillar. A girder support part 62 assembled through the girder and the bolt while covering the raised girder, a pillar support jaw 63 protruding from both sides of the pillar support part to support the pillar, and one side of the upper and lower parts of the girder support part A girder assembly bracket 60 formed of a girder support jaw 64 protruding from the girder to support the girder;
Perlin 40 is assembled on the girder in a direction orthogonal to the girder;
It includes a solar module 50 is assembled on the perlin,
A flange 11 formed at an upper portion of the support and provided with a plurality of bolt holes 12, a bolt hole 22 formed at a bottom of the pillar and communicating with the bolt hole 12, and the bolt hole 22. Fixing plate 21 is provided with an angle adjusting hole 23 formed on both sides of the center, the angle adjusting bolt 25 is fastened to the angle adjusting hole and the end is supported by the flange to adjust the angle of the pillar And a fixing bolt 24 fastened to the bolt holes 12 and 22 to assemble the support and the pillar. According to claim 1, The plate is provided with a bolt hole communicating with the bolt through-hole formed on the surface facing the girder of the perlin, a fixed plate 41 fixed to the bottom surface of the perlin, the girder wraps the bolt holes on both sides And a perlin-side birds provided, wherein the perlin-side birds surround the girder at the bottom and assemble the girder and perlin through bolts fastened to the bolt holes of the fixing plate. The solar cell of claim 1, further comprising a spacer filled in an empty space between the pillar and the girder. delete The photovoltaic power generation structure for a roof according to claim 1, comprising an elastic spacer (26) interposed between the flange (11) and the fixed plate (21). The solar cell structure of claim 1, further comprising a scaffold (80) fixed to the pillar through the scaffold fixing bracket. As a construction method of a photovoltaic power generation structure for roof according to claim 1,
Assembling a plurality of supports on a roof;
A second step of assembling and standing a pillar on the support;
A third step of assembling a girder on the pillar through a girder assembly bracket;
A fourth step of assembling perlins on the girder;
Comprising a fifth step of assembling the photovoltaic module on the perlin,
The second step is to raise the fixing plate 21 of the pillar on the flange 11 of the support and loosely fasten the fixing bolt 24 to move the pillar, and the angle adjusting bolt 25 coupled to the fixing plate in both directions Fastening the fixing bolt 24 to adjust the angle of the pillar while turning to fix the pillar 20,
The third step includes a pillar support portion 61 assembled through the pillar and the bolt while covering the pillar, and a girder support portion extending from the pillar support and assembled through the girder and the bolt while covering the girder mounted on the pillar ( 62), protruding on both sides of the pillar support portion to support the pillar, and support pillars 63 and girder support projections 64 formed to protrude on at least one side of the upper and lower portions of the girder support portion to support the girder. Method of constructing a solar photovoltaic power generation structure for the roof, characterized in that the girder assembly bracket is put on the left and right sides of the pillar and the girder and fastened bolts to assemble the pillar and the girder. The method according to claim 7, wherein the fourth step, the perlin on the girder, the perlin-side birds under the girder, and then the perlin-side birds and the perlins are fastened with bolts to assemble the girder and perlins. Construction method of photovoltaic power generation structure for roof


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