KR102473914B1 - Roof type solar power generating apparatus - Google Patents

Abstract

The present invention relates to a roof installation type solar power generation apparatus, comprising: a bar-shaped base frame (10) installed on a roof of a building; a front post (20) installed in front of the base frame (10); a rear post (30) installed at the rear of the base frame (10); a bar-shaped rotation support frame (40) connected to an upper end of the front post (20) by a hinge (h), mounted on an upper end of the rear post (30), and supporting a plurality of solar cell panels (P); a triangle block (50) in which first, second, and third block fastening holes (51, 52, 53) are formed; a wire assembly (60) having a first wire rope (61) connected between the front post (20) and the first block fastening hole (51), a second wire rope (62) connected to the second block fastening hole (52), a third wire rope (63) connected to the rear post (30), and a turnbuckle (64) installed between the second wire rope (62) and the third wire rope (63); and a rotation operation lever (70) hinged to the third block fastening hole (53) and the rotation support frame (40) between the front post (20) and the rear post (30), and interlocked with the triangle block (50) to rotate the rotation support frame (40) with the front post (20) as an axis. The roof installation type solar power generation apparatus enables efficient solar power generation by varying an inclination angle of a solar cell panel when the sun's altitude changes by season.

Description

Solar power generation device for roof installation {Roof type solar power generating apparatus}

The present invention relates to a roof installation solar power generation device installed on the roof of a building, and more particularly, to a roof installation solar power generation device capable of varying the inclination angle of a solar cell panel according to the height of the sun.

Photovoltaic power generation is a power generation method that directly converts sunlight into electrical energy using a plurality of photovoltaic modules. It is free from air pollution, noise, heat, and vibration, and is easy to maintain and has a long lifespan. It is gaining attention as an energy source. Since these solar power generation devices are capable of small-scale power generation, individuals who are not government or local governments are installing solar power generation devices to generate power. It is considered the best place. A photovoltaic device for such a building is manufactured by installing a three-dimensional frame on the roof of the building and installing a plurality of solar cell panels on top of the frame.

However, the roof of a building has various structures such as flat or inclined. For example, in the case of a concrete building, the floor of the building is flat, whereas in the case of a prefabricated building such as a factory, it is often constructed with sandwich panels with numerous hills and valleys. It is not very flat, and at the same time, a slope is formed so that rainwater can flow down. Accordingly, the photovoltaic support frame structure installed is different depending on the shape of the building, which limits the general use of the frame structure according to the shape of the building, resulting in high construction costs when manufacturing a photovoltaic device.

In addition, the altitude of the sun is not constant according to the season in Korea. Looking at the midday altitude of the sun for each season considering the latitude of 38 °, the midday altitude of the sun is approximately 52 ° on the vernal or autumnal equinox and 75.5 ° on the summer solstice, During the winter solstice, there is a great change in altitude, such as 28.5°. This change in altitude caused the amount of solar radiation to change by season, resulting in an inconsistent amount of power generation.

The present invention has been created to solve the above problems, and when the sun altitude changes by season, the inclination angle of the solar cell panel can be varied to enable efficient solar power generation, a roof-mounted solar panel. To provide a photovoltaic device.

Another object of the present invention is to provide a solar power generation device for roof installation, which can be universally applied regardless of the shape or slope of the roof of a building and can reduce the cost and effort required for construction.

In order to achieve the above object, a solar power generation device for roof installation according to the present invention includes a bar-shaped base frame 10 installed on a roof of a building; A front post 20 installed in front of the base frame 10; A rear post 30 installed at the rear of the base frame 10; A hinge (h) is connected to the upper end of the front post 20 and is mounted on the upper end of the upper rear post 30, and a bar-shaped rotation support frame 40 supporting a plurality of solar cell panels P; a triangle block 50 in which the first, second, and third block fastening holes 51, 52, and 53 are formed; A first wire rope 61 connected between the front post 20 and the first block fastening hole 51, a second wire rope 62 connected to the second block fastening hole 52, and the rear post A wire assembly (60) having a third wire rope (63) connected to (30) and a turnbuckle (64) installed between the second wire rope (62) and the third wire rope (63); And the pivoting support frame 40 between the front post 20 and the rear post 30 and the third block fastening hole 53 are hingedly connected to the triangle block 50 to interlock with the pivoting support frame ( 40) is characterized in that it includes; a rotation operation lever 70 for rotating the front post 20 as an axis.

In the present invention, the pivoting position fixing part 80 for fixing the position of the pivoting support frame 40 rotated at a specific angle in the front post 20; further includes.

In the present invention, the rotation position fixing part 80, the rear post 30, the rear post 30, the rear post 30, the rim 81, which can be inserted into the rotation support frame 40 forward and backward, and the rear post 30 and It includes an angle fixing lever 82 that is hinged to each corner of the base frame 10 and the rim 81 so that the rotation support frame 40 can be maintained at a specific angle rotated.

In the present invention, the rim 81 includes a rim body 81a fitted to the rotation support frame 40 so as to be able to move forward and backward, and a screw hole 81b formed on a side surface of the rim body 81a. And, a pressure bolt 81c screwed into the screw hole 81b to selectively press the surface of the rotation support frame 40, and a relatively large diameter knob installed at an end of the pressure bolt 81c. (81d) and a pair of rim wings 81e extending downward from the rim body 81a to hinge-connect the end of the angle fixing lever 82.

In the present invention, a frame roof fixing part 90 for fixing the base frame 10 to the roof R made of alternating peaks R1 and valleys R2; is further included.

In the present invention, the frame roof fixing part 90 includes a mounting cap bracket 91 having a pair of bracket inclined ends 91a that are in close contact with the outer slope of the opposite mountain R1 at the same time, and the mounting cap bracket A pair of mountain fastening bolts 92 each fastened to the mountain R1 facing each other through 91, and the base frame fitting groove in which the base frame 10 mounted on the mounting cap bracket 91 is inserted 93a) is formed to open downward and extends to both sides of the base frame fitting groove 93a to have a pair of fixed wings 93b superimposed on the upper surface of the mounting cap bracket 91; , It includes a bone fastening bolt nut 94 fastened through the pair of fixed wings 93b and the mounting cap bracket 91 at a position corresponding to the bone R2.

According to the present invention, a plurality of solar cell panels (P) is supported by a bar-type rotation support frame 40 and; a triangle block 50 in which the first, second, and third block fastening holes 51, 52, and 53 are formed; A first wire rope 61 connected between the front post 20 and the first block fastening hole 51, a second wire rope 62 connected to the second block fastening hole 52, and a rear post 30 A wire assembly 60 having a third wire rope 63 connected to and a turnbuckle 64 installed between the second wire rope 62 and the third wire rope 63; A rotation operation lever 70 interlocked with the triangle block 50 to rotate the rotation support frame 40 with the front post 20 as an axis; by including, the inclination angle of the solar cell panel P is easily variable Accordingly, even if the solar altitude changes by season, it is possible to enable efficient photovoltaic power generation by varying the inclination angle of the solar cell panel P.

In addition, by adopting the frame roof fixing part 90, the base frame 10 can be fixed in position on the roof R made of alternating peaks R1 and valleys R2, and thus the shape or inclination angle of the roof of the building. Regardless of the location, universal installation is possible, and as a result, the cost and effort required for construction can be reduced.

1 is a perspective view of a solar power generation device for roof installation according to the present invention;
Figure 2 is a cross-sectional view taken along line II-II of Figure 1; A cross-sectional view for explaining that the rotational support frame supporting the solar cell panel is inclined obliquely with respect to the base frame,
Figure 3 is a cross-sectional view for explaining that the rotation support frame of Figure 2 is disposed in the horizontal direction on the base frame,
Figure 4 is a view for explaining the configuration by extracting the base frame, the rotation support frame, the triangle block and the wire assembly of Figure 3;
5 is a view for explaining the configuration by extracting the wire assembly of FIG. 4;
6 is a view for explaining the configuration by extracting the rotation position fixing part of FIGS. 2 and 3;
7 is a view for explaining the configuration of a frame roof fixing part for fixing the position of the base frame of FIG. 1 to a roof made of hills and valleys;
8 is a cross-sectional view taken along line VII-VII of FIG. 7, an exploded view for explaining a specific configuration of a rim.

Hereinafter, a photovoltaic device for roof installation according to the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, what is described as "above" or "above" may include not only what is directly on top of contact but also what is on top of non-contact. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. Terms are only used to distinguish one component from another. Singular expressions include plural expressions unless the context clearly dictates otherwise. In addition, when a certain component is said to "include", this means that it may further include other components without excluding other components unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation.

1 is a perspective view of a solar power generation device for roof installation according to the present invention, and FIG. 2 is a cross-sectional view taken along line II-II of FIG. A cross-sectional view for explanation, and FIG. 3 is a cross-sectional view for explaining that the rotational support frame of FIG. 2 is disposed in the horizontal direction on the base frame. In addition, FIG. 4 is a view for explaining the configuration by extracting the base frame, the pivoting support frame, the triangle block, and the wire assembly of FIG. 3, and FIG. 5 is a view for explaining the configuration by extracting the wire assembly of FIG.

As shown, the solar power generation device for roof installation according to the present invention is installed in a building such as a factory or building to generate solar power, and includes a bar-shaped base frame 10 installed on the roof of the building; A front post 20 installed in front of the base frame 10; A rear post 30 installed at the rear of the base frame 10; A hinge (h) is connected to the upper end of the front post 20 and is mounted on the upper end of the rear post 30, and a bar-shaped rotation support frame 40 in which a plurality of solar cell panels P are supported; a triangle block 50 in which the first, second, and third block fastening holes 51, 52, and 53 are formed; A first wire rope 61 connected between the front post 20 and the first block fastening hole 51, a second wire rope 62 connected to the second block fastening hole 52, and a rear post 30 A wire assembly 60 having a third wire rope 63 connected to and a turnbuckle 64 installed between the second wire rope 62 and the third wire rope 63; It is hinged to the rotation support frame 40 between the front post 20 and the rear post 30 and the third block fastening hole 53, and is interlocked with the triangle block 50 to move the rotation support frame 40 to the front post ( 20) and a rotation operation lever 70 for rotating the axis; A rotation position fixing part 80 for fixing the position of the rotation support frame 40 rotated at a specific angle in the front post 20; It is characterized in that it includes; a frame roof fixing part 90 for fixing the base frame 10 to the position of the roof R made of alternating peaks R1 and valleys R2.

The base frame 10 is made of a square pipe having a long bar shape as being fixed to the roof of the building. A plurality of C-beams 45 are installed on the upper surface of the base frame 10, and a plurality of solar cell panels P are installed on the C-beams 45.

The front post 20 and the rear post 30 are vertically fixed to the front and rear sides of the base frame 10 by welding or the like. At the facing corners of the front post 20 and the rear post 30, between the front and rear posts 20 and 30, when force is applied in the opposite direction by the wire assembly 60 to be described later, so as to support it Reinforcing ends 21 and 31 are installed.

At the upper end of the rear post 30, as shown in FIG. 4, in the process of manufacturing the photovoltaic device of the present invention, the pivoting support frame 40 hingedly connected to the front post 20 is temporarily mounted Post cap (32) is installed. The post cap 32 provides a cushion to prevent peeling off of the painted surface at the portion where the metal rotation support frame 40 is mounted on the rear post 30 made of metal. The cap is preferably made of a rubber material.

As shown in FIG. 3 , the pivoting support frame 40 may be temporarily mounted on the rear post 30 during the manufacturing process of the photovoltaic device to maintain a horizontal state as a whole. Accordingly, a plurality of C-beams 45 for supporting the solar cell panel P can be easily installed on the upper side of the pivoting support frame 40. That is, the pivoting support frame 40 is rotatably connected to the front post 20 and can be temporarily mounted on the rear post 30 in a horizontal direction as a whole, so that a plurality of C-beams 45 or solar cell panels (P ) can be easily installed.

The triangle block 50 has an equilateral triangle shape forming an angle of 60° at each corner side, and first, second, and third block fastening holes 51, 52, and 53 are formed at the corner side. The size of the triangle block 50 may vary according to the rotation angle of the rotation support frame 40, and in this embodiment, one side is 60 cm.

The wire assembly 60 is for rotating the rotation support frame 40 supporting the solar cell panel P with the front post 20 as an axis, as shown in FIG. 4, the front post 20 and the first The first wire rope 61 connected between the first block fastening holes 51, the second wire rope 62 connected to the second block fastening hole 52, and the third wire rope connected to the rear post 30 (63) and a turnbuckle (64) installed between the second wire rope (62) and the third wire rope (63).

As shown in FIG. 5, the turnbuckle 64 includes a first ring bolt 64a connected to the second wire rope 62 and a second ring bolt 64b connected to the third wire rope 63. And, it includes a turnbuckle body (64c) that is screwed together with the first and second ring bolts (64a) (64b).

As shown in FIG. 4, the rotation operation lever 70 is a rotation support frame 40 between the third block fastening hole 53 of the triangle block 50 and the front post 20 and the rear post 30 hinged to

Due to the organic coupling structure of the triangle block 50, the wire assembly 60, and the turning lever 70, as shown in FIG. 5, by forward or reverse rotation of the turnbuckle body 64c, the first The distance between the second and third wire ropes 61 and 62 connected to the two ring bolts 64a and 64b is narrowed or widened, and accordingly, as shown in FIG. 2, the third block fastening hole ( 53) and the pivoting operation lever 70 hingedly rotate the pivoting support frame 40 around the front post 20 at a predetermined angle. Accordingly, the inclination angle of the solar cell panel P supported by the C-beam 45 on the pivot support frame 40 can be varied.

That is, the rotation support frame 40 can be rotated with the front post 20 as an axis, and the inclination angle of the solar cell panel P supported on the rotation support frame 40 can be varied. Even if the sun altitude is different, it is possible to enable efficient solar power generation by varying the inclination angle of the solar cell panel (P).

6 is a view for explaining the configuration by extracting the rotation position fixing part of FIGS. 2 and 3 .

The rotation position fixing part 80 is for fixing the position of the rotation support frame 40 moved from the front post 20 at a specific angle, and can move forward and backward to the rotation support frame 40 from the rear side of the rear post 30 The hinged rim 81 and the edge between the rear post 30 and the base frame 10 and the rim 81 are hinged to each of the pivot support frame 40 to be rotated at a specific angle. It includes an angle fixing lever 82.

The rim 81 includes a rim body 81a fitted to the rotation support frame 40 so as to be able to move forward and backward, a screw hole 81b formed on a side surface of the rim body 81a, and a screw hole 81b. A pressure bolt 81c which is screwed together to selectively press the surface of the rotation support frame 40, a relatively large diameter knob 81d installed at an end of the pressure bolt 81c, and a rim body 81a It extends downward and includes a pair of rim wings 81e hingedly connecting the end of the angle fixing lever 82.

One end of the angle fixing lever 82 is hinged to a pair of rim wings 81e, and the other end is hinged to a corner between the rear post 30 and the base frame 10.

By this rotation position fixing part 80, it is possible to fix the position of the rotation support frame 40 rotated at a specific angle with respect to the front post 20, and accordingly, even if strong wind blows or vibration occurs, a number of The position of the solar cell panel P can be safely fixed.

7 is a view for explaining the configuration of a frame roof fixing part for fixing the position of the base frame of FIG. 1 to a roof made of hills and valleys, and FIG. 8 is a cross-sectional view along line VII-VII of FIG. 7, showing a specific configuration of a rim. It is an exploded view to explain.

The frame roof fixing part 90 is for fixing the position to the roof R, in which the peaks R1 and valleys R2 are alternately formed, and is mounted on a pair of facing mountains R1, and the facing mountain R1 ) A mounting cap bracket 91 having a pair of bracket inclined ends 91a that are in close contact with the outer inclined surface of the mounting cap bracket 91 and a pair of mounting bolts each fastened to the facing mountain R1 through the mounting cap bracket 91 (92) and the base frame fitting groove (93a) in which the base frame (10) mounted on the mounting cap bracket (91) is inserted are formed to open downward, and extend to both sides of the base frame fitting groove (93a) for mounting. A fixed bracket 93 having a pair of fixed blades 93b superimposed on the upper surface of the cap bracket 91, and a pair of fixed blades 93b and a mounting cap bracket 91 at a position corresponding to the valley R2 A bone fastening bolt nut 94 fastened through and a waterproof cap 95 in close contact with the upper surface of the mounting cap bracket 91 while covering the mountain fastening bolt 92, and a pair of fixed wings 93a It includes a waterproof cap pressing wing 96 that is bent and extended at the end of the waterproof cap 95 to press the top of the waterproof cap 95.

The mounting cap bracket 91 is simultaneously mounted on a pair of mountains R1 facing each other and has a width of about 10 cm. Such a mounting cap bracket 91 is used after bending the steel plate to form a bracket inclined end 91a, and then cutting to about 10 cm.

The band cap bracket 93 is overlapped on top of the mounting cap bracket 91 and has a width of about 7 to 8 cm.

The fixing bracket 93 is fixed to the mounting cap bracket 91 mounted on the mountain R1 facing the base frame 10. Accordingly, it is possible to install the base frame 10 on the roof R made of the peak R1 and the valley R2.

The waterproof cap 95 covers the acid fastening bolt 92 so that rainwater does not flow into the acid fastening bolt 92, thereby preventing the fastening part of the acid fastening bolt 92 from being corroded.

The waterproof cap pressure wing 96 is bent and extended from the end of the pair of fixed wing 93a to press the upper end of the waterproof cap 95, thereby firmly sealing the gap between the water repellent cap 95 and the mountain R1. , Accordingly, it further prevents moisture or rainwater from entering the acid fastening bolt 92 side.

Thus, according to the present invention, a plurality of solar cell panels (P) is supported by a bar-type rotation support frame 40 and; a triangle block 50 in which the first, second, and third block fastening holes 51, 52, and 53 are formed; A first wire rope 61 connected between the front post 20 and the first block fastening hole 51, a second wire rope 62 connected to the second block fastening hole 52, and a rear post 30 A wire assembly 60 having a third wire rope 63 connected to and a turnbuckle 64 installed between the second wire rope 62 and the third wire rope 63; A rotation operation lever 70 interlocked with the triangle block 50 to rotate the rotation support frame 40 with the front post 20 as an axis; by including, the inclination angle of the solar cell panel P is easily variable Accordingly, even if the solar altitude changes by season, it is possible to enable efficient photovoltaic power generation by varying the inclination angle of the solar cell panel P.

In addition, by adopting the frame roof fixing part 90, the base frame 10 can be fixed in position on the roof R made of alternating peaks R1 and valleys R2, and thus the shape or inclination angle of the roof of the building. Regardless of the location, universal installation is possible, and as a result, the cost and effort required for construction can be reduced.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

10 ... base frame 20 ... front post
30 ... rear post 32 ... post cap
40 ... rotation support frame 45 ... C-shaped steel
50 ... Triangle block 51, 52, 53 ... 1st, 2nd, 3rd block fastening hole
60 ... wire assembly 61, 62, 63 ... first, second, third wire rope
64 ... turnbuckle 64a ... first hook bolt
64b ... 2nd ring bolt 64c ... turnbuckle body
70 ... rotation operation lever 80 ... rotation position fixing part
81 ... rim 81a ... rim body
81b ... threaded hole 81c ... pressure bolt
81d ... knob 81e ... rim wing
82 ... angle fixing lever 90 ... frame roof fixing part
91 ... mounting cap bracket 91a ... bracket incline
92 ... acid fastening bolt 93 ... fixing bracket
93a ... base frame fitting groove 93b ... fixed wing
94 ... bolt nut 95 ... waterproof cap
96 ... waterproof cap pressure wing

Claims (6)

Base frame 10 in the form of a bar installed on the roof of the building;
A front post 20 installed in front of the base frame 10;
A rear post 30 installed at the rear of the base frame 10;
One end is hinged (h) connected to the upper end of the front post 20 and the other end is mounted on the upper end of the rear post 30, a plurality of solar cell panels (P) A bar-shaped pivoting support frame ( 40);
a triangle block 50 in which the first, second, and third block fastening holes 51, 52, and 53 are formed;
A first wire rope 61 connected between the front post 20 and the first block fastening hole 51, a second wire rope 62 connected to the second block fastening hole 52, and the rear post A wire assembly 60 having a third wire rope 63 connected to (30) and a turnbuckle 64 installed between the second wire rope 62 and the third wire rope 63; and
The rotation support frame 40 between the front post 20 and the rear post 30 is hinged to the third block fastening hole 53, and is interlocked with the triangle block 50 to rotate the support frame 40 characterized in that it comprises a; rotation operation lever (70) for rotating the other end of the rotation support frame (40) in the upward direction of the rear post (30) with one end of the front post (20) as an axis. , Solar power generation device for roof installation. According to claim 1,
The rotation position fixing part 80 for fixing the position of the rotation support frame 40 rotated at a specific angle in the front post 20; Characterized in that it further comprises, the solar power generation device for roof installation. The method of claim 2, wherein the rotation position fixing part 80,
A rim 81 fitted to the rotational support frame 40 at the rear side of the rear post 30 so as to be able to move forward and backward;
Includes an angle fixing lever 82 that is hinged to each of the corners and rims 81 between the rear post 30 and the base frame 10 so that the rotation support frame 40 can be maintained at a specific angle rotated Characterized in that, a solar power generation device for roof installation. The method of claim 3, wherein the rim 81,
A rim body 81a fitted to the rotation support frame 40 so as to be able to move forward and backward;
A screw hole 81b formed on a side surface of the rim body 81a;
A pressing bolt 81c screwed into the screw hole 81b to selectively press the surface of the rotation support frame 40;
A relatively large diameter knob 81d installed at an end of the pressure bolt 81c;
A solar power generation device for roof installation, characterized in that it includes a pair of rim wings (81e) extending downward from the rim body (81a) and hinge-connecting the end of the angle fixing lever (82). According to claim 1,
Characterized in that it further comprises a; frame roof fixing part 90 for fixing the base frame 10 to the roof R made of alternating peaks R1 and valleys R2; power plant. The method of claim 5, wherein the frame roof fixing part 90,
A mounting cap bracket 91 having a pair of bracket inclined ends 91a that are in close contact with the outer slope of the opposite mountain R1 at the same time;
A pair of mountain fastening bolts 92 respectively fastened to the mountains R1 facing each other through the mounting cap bracket 91;
The base frame fitting groove 93a, into which the base frame 10 mounted on the mounting cap bracket 91 is inserted, is formed to open downward and extends to both sides of the base frame fitting groove 93a to form the mounting cap bracket. A fixing bracket (93) having a pair of fixed blades (93b) superimposed on the upper surface of (91);
Solar power generation for roof installation, characterized in that it includes a bone fastening bolt nut 94 fastened through the pair of fixed wings 93b and the mounting cap bracket 91 at a position corresponding to the bone R2. Device.

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