KR101662823B1 - Photovoltaic power generating apparatus - Google Patents

Abstract

The purpose of the present invention is to provide a roof mounted type photovoltaic power generating apparatus capable of preventing the degradation of a waterproof ability. The present invention relates to the roof mounted type photovoltaic power generating apparatus. A plurality of scarves (S) including scarf folding ends (S1) are installed on a scarf folding roof (R). The photovoltaic power generating apparatus comprises: a frame rail (10) to support a plurality of photovoltaic modules (P); a slider bracket (20) slidably combined with the frame rail (10); a lower frame (30) located at a lower side of the frame rail (10); a shaft frame (40) extended from a front side of the lower frame (30) to an upper side and combining an upper end with a first hinge (h) at the front side of the frame rail (10); an assembling frame (50) to combine a lower end with a second hinge (h2) at the rear side of the lower frame (30) and to combine an upper end with a third hinge (h3) at the slider bracket (20); and a scarf fixing unit (60) to fix the lower frame (30) at the scarf (S).

Description

[0001] PHOTOVOLTAIC POWER GENERATING APPARATUS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a roof mounted solar power generation apparatus, and more particularly, to a roof mounted solar power generation apparatus which can be installed directly on a roof of a semi-rigid roof to which sandwich panels are connected.

Solar power generation is a power generation method that converts solar light directly into electric energy by using a plurality of solar modules. Since there is no pollution such as air pollution, noise, heat and vibration, maintenance is easy and life is long, It is attracting attention as an energy source. Because these solar power generation devices are capable of small-scale power generation, non-governmental and non-governmental individuals also install solar power generation devices to generate electricity. However, since the roofs of factory buildings are large, attempts to install solar power generation devices .

On the other hand, the number of columns should be minimized in the factory building because the machines must be arranged in a complicated manner and continuous production activities must be carried out. Therefore, since the roof of the factory building must be constructed with light weight, it is often constructed with a sandwich panel containing urethane or styrofoam.

However, since the photovoltaic device is made up of a plurality of photovoltaic modules and a frame, the weight of the photovoltaic power generation device is considerable. In order to install the photovoltaic device on the roof panel of a prefabricated panel such as a sandwich panel, Respectively. A prior art related to this is disclosed in Utility Model Registration No. 20-0470558 entitled " Prefabricated Roof Mounted Solar Photovoltaic Device ".

However, it was very difficult to fix the solar power generation device while dispersing the weight on the roof panel of the weak durability panel. Therefore, it took much effort and time to construct the solar power generation device on the roof.

In addition, since the method is a method in which a hole is formed in a prefabricated panel, there has been a problem in that rain or corrosion occurred in the portion where the hole was drilled.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a roof-mounted photovoltaic power generation system which can be installed directly on a roof of a folding type roof structure in which sandwich panels are connected to each other.

It is another object of the present invention to provide a roof-mounted solar power generator capable of preventing a waterproofing ability from being lowered without puncturing a roof.

In order to achieve the above-mentioned object, the roof-mounted solar power generation apparatus according to the present invention is installed in a substantially vertical roof R having a large number of hermes S formed with a top end S1, A frame rail (10) for supporting a plurality of solar modules (P); A slider bracket 20 slidably coupled to the frame rail 10; A lower frame (30) located on the lower side of the frame rail (10); An axis frame (40) extending upward from a front side of the lower frame (30) and having an upper end coupled to a first hinge (h) at a front side of the frame rail (10); A rotating frame 50 whose lower end is engaged with the second hinge h2 at the rear side of the lower frame 30 and whose upper end is engaged with the third hinge h3 at the slider bracket 20; And a remote part (60) for fixing the lower frame (30) to the conical (S);
The remoter 60 includes a first bracket 61 which is in contact with one side of the conical S at the lower side of the rigid connecting end S1 and a second bracket 61 which is in close contact with the other side of the conical S A second bracket 62 and a fastening portion 63 for fastening the first bracket 61 and the second bracket 62 to each other through the conical portion S;
The first bracket 61 includes a first bracket block 61a which is brought into close contact with one side of the conical S at a lower side of the rigid connecting end S1 and a second bracket block 61b having a smaller width than the first bracket block 61a A first bracket blade 61b extending from an upper end of the first bracket block 61a and a first bracket folding end 61c bent at an upper end of the first bracket blade 61b, A block nut hole 61d formed in the bracket block 61a and a first bending monolithic hole 61e formed in the first bracket bent end 61c;
The second bracket 62 includes a second bracket block 62a which is in close contact with the other side of the conical S and a second bracket block 62a which is smaller in width than the second bracket block 62a. A second bracket folding step 62c bent at the upper end of the second bracket blade 62b and a second bracket folding step 62c extending to the upper end of the second bracket block 62a, Hole 62d and a second bent single-ended through-hole 62e formed in the second bracket bent end 62c.

The present invention further includes a module rail 70 installed between the plurality of solar modules P and the frame rail 10.

In the present invention, a plurality of rail through holes 11 are formed at a predetermined interval on the lower surface of the frame rail 10; A nut end 21 is formed at a lower side of the slider bracket 20 to receive a position fixing bolt B selectively engaged with the rail through hole 11. As shown in FIG.

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In the present invention, the fastening portion 63 further includes a pointed drill end 63a at an end thereof.

According to the present invention, since the solar power generator is directly installed on the hermetic S formed by attaching the assembled panels such as the sandwich panel to each other, it is possible to omit the process of perforating the holes in the assembled panel, Construction period is shortened and easy installation is possible.

In addition, since holes are formed in the non-water-resistant horns (S), it is possible to prevent rain or corrosion through the holes and further reduce the cost of waterproofing.

When the sun altitude changes according to the season, the inclination angle of the frame rail supporting the photovoltaic module can be varied by moving the slider brackets on the frame rails, thereby enhancing the photovoltaic power generation efficiency.

1 is a perspective view of a roof mounted solar power generator according to the present invention,
Fig. 2 is a side view of the roof mounted solar power generation device of Fig. 1,
3 is a sectional view taken along the line III-III 'of FIG. 2,
FIG. 4 is a cross-sectional view of FIG. 3,
Fig. 5 is an exploded perspective view of the first and second brackets of Fig. 4,
6 is a view for explaining that the inclination angle of the solar module is increased as the slider bracket of FIG. 1 moves forward in the frame rail,
FIG. 7 is a view for explaining that the inclination angle of the solar module is reduced as the slider bracket of FIG. 6 moves rearward along the frame rail; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a roof mounted solar power generation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a roof mounted solar power generator according to the present invention, FIG. 2 is a side view of the roof mounted solar power generator of FIG. 1, and FIG. 3 is a sectional view taken along line III - III 'of FIG.

As shown in the figure, the roof-mounted solar power generation apparatus according to the present invention is installed in a substantially vertical roof R having a plurality of hermit S formed with a top end S1, A frame rail (10) for supporting the module (P); A slider bracket (20) slidably coupled to the frame rail (10); A lower frame (30) positioned on the lower side of the frame rail (10); An axis frame 40 extending upward from the front side of the lower frame 30 and having an upper end coupled to the first hinge h at the front side of the frame rail 10; A rotating frame 50 whose lower end is engaged with the second hinge h2 at the rear side of the lower frame 30 and whose upper end is engaged with the third hinge h3 at the slider bracket 20; And a remote part (60) for fixing the lower frame (30) to the conical (S).

At this time, a module rail 70 is provided between the plurality of solar modules P and the frame rails 10 to support the lower side of the plurality of solar modules P separated from each other. The plurality of solar panels P having various sizes can be supported on the plurality of frame rails 10 by the module rails 70.

The frame rail 10 has an angular pipe shape, and a plurality of rail through holes 11 are formed at a predetermined interval on the lower surface.

2, the slider bracket 20 is moved along the frame rail 10, and the lower end of the slider bracket 20 is coupled to the lower end of the nut 11, An end 21 is formed. When the position fixing bolt B passes through the nut end 21 and is inserted into the corresponding rail through hole 11 in a state where the slider bracket 20 is positioned in the small section of the frame rail 10, The slider bracket 20 is fixed to the frame rail 10.

The lower frame 30 uses a C-shaped steel frame having a "C" shape in cross section so that a space for fastening the frame fixing bolt B and the nut N to each other can be formed in the upper portion 60, do.

The side frame 40 is fixed to the front side of the lower frame 30, and the front side of the frame rail 10 is axially coupled by the first hinge h1.

The rotating frame 50 is coupled to the rear side of the lower frame 30 and the second and third hinges h2 and h3 of the slider bracket 20 so that the slider bracket 20 moves along the frame rail 10 The inclination angle of the frame rail 10 supporting the photovoltaic module P is changed with reference to the shaft frame 40. [ That is, when the rotation frame 50 moves to the shaft frame 40 side, the inclination angle of the solar module P supported by the frame rail 10 is increased. On the contrary, when the rotation module 50 is moved to the opposite side of the axis frame, The inclination angle of the solar module P supported by the rail 10 is reduced.

FIG. 4 is a cross-sectional view of the bracket of FIG. 3, and FIG. 5 is an exploded perspective view of the first and second brackets of FIG.

The remotely located portion 60 is for fixing the lower frame 30 to the roof slab S by fixing. The disengaged portion 60 is engaged with the lower frame 30 and includes a first bracket 61 which is brought into close contact with one side of the conical S at the lower side of the rigid connecting end S1; A second bracket (62) which is in close contact with the other side surface of the conical (S); And a fastening part 63 for fastening the first bracket 61 and the second bracket 62 to each other through the conical S,

The first bracket 61 has a first bracket block 61a which is in close contact with one side of the conical S at the lower side of the rigid connecting end S1 and a second bracket block 61b having a smaller width than the first bracket block 61a, A first bracket blade 61b extending from the upper end of the first bracket block 61a and a first bracket folding step 61c bent from the upper end of the first bracket blade 61b, And a first bent single-ended through hole 61e formed in the first bracket bent end 61c.

The second bracket 62 includes a second bracket block 62a which is in close contact with the other side of the conical S and a second bracket block 62b which is smaller in width than the second bracket block 62a, A second bracket bent portion 62c bent at the upper end of the second bracket blade 62b and a block through hole 62d formed in the second bracket block 62a, And a second bent single-ended through hole 62e formed in the second bracket bent end 62c.

The fastening portion 63 is formed with a pointed drill end 63a at its end portion, and is used to flow under the name of a direct bolt. The fastening portion 63 is inserted into the block through hole 62d and then passes through the conical portion S and is fastened to the block nut hole 61d.

The first bracket block 61a is positioned at one side of the conical S at the lower side of the convexly protruding S1 and the second bracket block 62a is positioned at the side of the second bracket block 62a, The drill bit 63a penetrates through the conical portion S and then moves forward so as to advance the first bracket block 62a. So that the first and second brackets 61 and 62 are fixed to the hanger S, respectively. When the second bracket folding end 62c is positioned on the lower side of the first bracket folding end 61c, the first and second folding end passage holes 61e and 62e coincide with each other. In this state, B are fastened to the nut (N) through the holes of the first and second bending-only through holes (61e) and (62e) and the lower frame (30), the lower frame (30) is fixed to the hanger (S).

6 is a view for explaining an increase in the inclination angle of the solar module as the slider bracket of FIG. 1 moves forward in the frame rail. FIG. 7 is a cross- The inclination angle of the module is reduced.

6, when the altitude of the sun is changed in accordance with the change of the season, the slider bracket 20 is moved forward along the frame rail 10, The rotary frame 50 connected to the third hinge h3 is rotated forward so that the frame rail 10 axially coupled to the first hinge h1 is raised and the solar module P is arranged at a large inclination angle do.

Conversely, when the slider bracket 20 is moved backward along the frame rail 10, the rotating frame 500 connected to the slider bracket 20 and the third hinge h3 is rotated backward as shown in Fig. 7 So that the frame rail 10 axially coupled to the first hinge h1 is lowered while the solar module P is arranged at a small inclination angle.

As described above, according to the present invention, since the solar power generator is directly installed on the hermetic S formed by attaching the assembled panels such as the sandwich panel to each other, the process of drilling holes in the assembled panel can be omitted , Thus shortening the construction period and facilitating installation.

In addition, since holes are formed in the non-water-resistant horns (S), it is possible to prevent rain or corrosion through the holes and further reduce the cost of waterproofing.

The inclination angle of the frame rail 10 supporting the solar module P can be varied by moving the slider bracket 20 on the frame rail 10 when the sun altitude changes according to the season, The photovoltaic power generation efficiency can be increased.

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.

10 ... frame rail 11 ... rail through hole
20 ... Slider bracket 21 ... Nut stage
30 ... lower frame 40 ... axis frame
50 ... Convoy frame 60 ... Far distant government
61 ... first bracket 61a ... first bracket block
61b ... first bracket blade 61c ... first bracket bent edge
61d ... Block nut ball 61e ... First bending monolithic aperture
62 ... second bracket 62a ... second bracket block
62b ... second bracket blade 62c ... second bracket bent edge
62d ... block through hole 62e ... second bending monolithic hole
62 ... second bracket 63 ... fastening portion
70 ... module frame

Claims (6)

Folded roof R having a plurality of ridges S1 formed at the upper end thereof,
A frame rail (10) for supporting a plurality of solar modules (P);
A slider bracket 20 slidably coupled to the frame rail 10;
A lower frame (30) located on the lower side of the frame rail (10);
An axis frame (40) extending upward from a front side of the lower frame (30) and having an upper end coupled to a first hinge (h) at a front side of the frame rail (10);
A rotating frame 50 whose lower end is engaged with the second hinge h2 at the rear side of the lower frame 30 and whose upper end is engaged with the third hinge h3 at the slider bracket 20; And
And a remote part (60) for fixing the lower frame (30) to the conical (S);
The remoter 60 includes a first bracket 61 which is in contact with one side of the conical S at the lower side of the rigid connecting end S1 and a second bracket 61 which is in close contact with the other side of the conical S A second bracket 62 and a fastening portion 63 for fastening the first bracket 61 and the second bracket 62 to each other through the conical portion S;
The first bracket 61 includes a first bracket block 61a which is brought into close contact with one side of the conical S at a lower side of the rigid connecting end S1 and a second bracket block 61b having a smaller width than the first bracket block 61a A first bracket blade 61b extending from an upper end of the first bracket block 61a and a first bracket folding end 61c bent at an upper end of the first bracket blade 61b, A block nut hole 61d formed in the bracket block 61a and a first bending monolithic hole 61e formed in the first bracket bent end 61c;
The second bracket 62 includes a second bracket block 62a which is in close contact with the other side of the conical S and a second bracket block 62a which is smaller in width than the second bracket block 62a. A second bracket folding step 62c bent at an upper end of the second bracket blade 62b and a second bracket folding step 62b extending from the upper end of the second bracket block 62a, And a second bent single-ended through-hole (62e) formed in the second bracket bent end (62c). The method according to claim 1,
Further comprising a module rail (70) installed between the plurality of solar modules (P) and the frame rail (10). The method according to claim 1,
A plurality of rail through holes 11 are formed at a predetermined interval on the lower surface of the frame rail 10;
And a nut end 21 coupled to a position fixing bolt B which is selectively coupled to the rail through hole 11 is formed on a lower side of the slider bracket 20, . delete delete The method according to claim 1,
The roof mounted photovoltaic device according to claim 1, wherein the coupling part (63) further comprises a pointed drill (63a) at an end thereof.

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