KR20220006258A - Apparatus for supporting solar pannel - Google Patents

Abstract

The present invention relates to a solar panel supporter for installing a solar panel on a railing. The solar panel supporter comprises: a first square steel tube which supports the rear surface of the solar panel and in which an upper end is fastened to an upper side of the railing; a second square steel tube which is located between a lower side of the railing and the rear surface of the first square steel tube and in which one end is fastened to a lower side of the railing; and a connection unit which connects the first square steel tube and another end of the second square steel tube. The first square steel tube and the connection unit are fastened by a first bolt. The second square steel tube and the connection unit are fastened by a second bolt disposed vertical to the first bolt.

Description

Solar panel mount {APPARATUS FOR SUPPORTING SOLAR PANNEL}

The present invention relates to a solar panel holder.

Solar cells convert light energy from the sun into electrical energy. The smallest unit that generates electricity using the photoelectric effect is called a cell, and a solar cell module (solar panel) that generates power of a certain size by connecting a plurality of cells in series or in parallel is called a cell. A plurality of solar cell modules are connected in series or parallel to form a solar power plant.

Since the solar cell module must be used in a large amount to obtain a certain amount of power, the installation site is limited. There is no problem when installing on the roof of a building or outdoor facilities, but it is not easy to install it individually within a household when installing it in a multi-family house that accounts for a significant portion of the house.

Conventionally, a support structure for supporting a solar cell module was used to facilitate individual installation in an apartment house.

However, since the environment of the installation location (for example, the railing of a veranda or terrace) is different for each apartment house, it is difficult to use the same support structure as it is, and the operator has to cut or drill a hole and reassemble the support element according to the installation environment. discomfort ensues.

Even when information about the installation location (size, angle, etc.) is secured in advance, if even a slight error occurs due to the characteristics of the support elements made of a solid material, installation becomes quite difficult. Even if it is installed somehow, it is not easy to guarantee the stability of the fixation considering the use environment that is always exposed to the external environment.

In addition, support elements are often joined to each other by welding, so it is time-consuming and costly to change the arrangement once positioned.

Accordingly, the inventor of the present invention has completed the present invention after long research and trial and error in order to solve the above problems.

An embodiment of the present invention provides a solar panel cradle that can be easily installed on the railing of the veranda or terrace.

On the other hand, other objects not specified in the present invention will be additionally considered within the range that can be easily inferred from the following detailed description and effects thereof.

According to one aspect of the present invention, there is provided a photovoltaic panel holder for installing a photovoltaic panel on a railing, comprising: a first square steel pipe supporting the rear surface of the photovoltaic panel and having an upper end fastened to the upper side of the railing; a second steel tube positioned between the lower side of the handrail and the rear surface of the first steel tube, one end of which is fastened to the lower side of the handrail; and a connecting part connecting the other ends of the first square steel pipe and the second square steel pipe, wherein the first square steel pipe and the connecting part are fastened by a first bolt, and the second square steel pipe and the connecting part are the first A solar panel holder is provided, which is fastened by the first bolt and the second bolt vertically arranged.

The connecting portion may be formed as a plate bent in a U-shape, and the connecting portion may surround the other ends of the first steel tube and the second steel tube.

The connecting portion includes two parallel plates facing each other; and a vertical plate positioned between the two parallel plates, wherein a front surface of the first each steel pipe is in contact with the vertical plate, and both sides of the second each steel pipe are in contact with the two parallel plates. .

The first bolt may collectively fasten the first square steel pipe, the connection part, and the solar panel.

A through hole penetrating the upper and lower surfaces may be formed at one end of the second rectangular steel pipe, and the one end of the second rectangular steel pipe and the lower side of the handrail may be fastened to each other by a tie member passing through the through hole.

An angle between the first square steel pipe and the second square steel pipe may be changeable, and an angle between the connection part and the second square steel tube may be changeable.

According to a position where the connection part is coupled to the first square steel pipe, the angle between the first square steel pipe and the second square steel pipe may be changed.

A plurality of bolt holes arranged vertically are formed in the first square steel pipe, the first bolt is inserted into at least one of the plurality of bolt holes, and the more the first bolt is inserted into the bolt hole located at a high place, the higher the number of bolt holes. The angle between the first square steel tube and the second square steel tube may be reduced.

Further comprising a bracket for fastening the upper end of the first steel tube and the upper side of the handrail, the bracket is bent to surround the upper end of the first steel tube and the upper side of the handrail, the bracket and the first steel tube can be bolted together.

This technology can provide a solar panel holder that can install the solar panel very easily and stably on the railing of the veranda or terrace.

This technology can provide a solar panel holder that can adjust the angle of the solar panel when installing the solar panel on the railing of the veranda or terrace.

On the other hand, even if it is an effect not explicitly mentioned herein, it is added that the effects described in the following specification expected by the technical features of the present invention and their potential effects are treated as described in the specification of the present invention.

1 to 3 are views illustrating a state in which a solar panel is installed on a handrail by a solar panel holder according to an embodiment of the present invention.
4 is a view showing a state in which the solar panel is coupled to the solar panel holder according to an embodiment of the present invention.
5 is a view showing a state in which the solar panel is separated from the solar panel holder according to an embodiment of the present invention.
6 is a view showing a first square steel tube and a second square steel tube of a solar panel holder according to an embodiment of the present invention.
7 is a view showing the railing side end of the second each steel pipe of the solar panel holder according to an embodiment of the present invention.
8 is a view showing a state in which the second each steel pipe and the handrail are coupled to the solar panel holder according to an embodiment of the present invention.
9 is a view showing a state in which the first square steel pipe and the second square steel pipe of the solar panel holder according to an embodiment of the present invention are coupled.
10 is an exploded view of FIG. 9(a).
11 is a view showing a bracket according to an embodiment of the present invention.
12 is a view showing a state in which the first square steel pipe, the bracket, and the solar panel are coupled according to an embodiment of the present invention.
13 is a view showing a state in which the first square steel pipe, the bracket, and the solar panel are coupled to the handrail according to an embodiment of the present invention.
14 to 16 are views showing changes in the angle of the solar panel holder according to an embodiment of the present invention.
It is revealed that the accompanying drawings are exemplified by reference for understanding the technical idea of the present invention, and the scope of the present invention is not limited thereby.

In the description of the present invention, if it is determined that related known functions are obvious to those skilled in the art and may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, an embodiment of the solar panel holder according to the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numbers and overlapped therewith. A description will be omitted.

1 to 3 are views showing a state in which the solar panel 20 is installed on the handrail 30 by the solar panel holder 10 according to an embodiment of the present invention.

1 to 3, the photovoltaic panel holder 10 according to the present invention is for installing the photovoltaic panel 20 on the handrail 30 such as a balcony or a veranda. The front surface of the solar panel 20 is a surface on which sunlight is incident. The solar panel 20 is installed on the outside of the handrail 30 so that the front faces outward. In addition, the solar panel 20 may be installed to be inclined so that the front side faces upward. In this case, the solar panel holder 10 according to the present invention may fix the solar panel 20 in an inclined state.

The handrail 30 may include a horizontal bar and a vertical bar 33 . The horizontal bar is disposed parallel to the floor, and the vertical bar 33 is disposed perpendicular to the horizontal bar. The horizontal bar is disposed on the upper side and the lower side, respectively, and the vertical bar 33 may be disposed in plurality to connect between the upper horizontal bar 31 and the lower horizontal bar 32 .

The solar panel holder 10 according to the present invention uses a steel tube. Here, each steel pipe is a steel pipe of a square column, has four surfaces, and has a hollow part therein. The cross section of each steel pipe is rectangular. In addition, the material of each steel pipe is not limited, and may be made of aluminum or stainless steel, which is resistant to corrosion in an external environment.

4 is a view showing a state in which the solar panel 20 is coupled to the solar panel holder 10 according to an embodiment of the present invention. 5 is a view showing a state in which the solar panel 20 is separated from the solar panel holder 10 according to an embodiment of the present invention.

4 and 5 , the solar panel holder 10 according to the present invention supports the solar panel 20 . The solar panel holder 10 may be formed as a pair. A pair of photovoltaic panel mounts 10 may be respectively located on both sides from the center of the photovoltaic panel 20 .

The solar panel 20 may include a solar cell unit 21 and a square frame 22 . The solar cell unit 21 is a part having a configuration such as an electrode and substantially serves as a solar cell, and the rectangular frame 22 is a part for supporting the solar cell unit 21 . The first rectangular steel pipe 100 may be coupled to the rear side of the rectangular frame 22 of the solar panel 20 .

The square frame 22 may have coupling holes 23 and 24 formed therein. The coupling holes 23 and 24 are holes into which bolts for coupling the solar panel 20 and the first square steel pipe 100 are inserted. A lower coupling hole 23 for coupling with the lower side of the first rectangular steel pipe 100 and an upper coupling hole 24 for coupling with the upper side of the first rectangular steel pipe 100 may be formed in the square frame 22 . . These coupling holes 23 or 24 are formed in plurality, and accordingly, a position at which the first angle steel pipe 100 is coupled can be variously selected.

The solar panel holder 10 according to the present invention may include a first square steel pipe 100 , a second square steel pipe 200 , and a connection part 300 .

6 is a view showing the first steel tube 100 and the second steel tube 200 of the solar panel holder 10 according to an embodiment of the present invention. Figure 6 (a) shows the first square steel pipe 100, Figure 6 (b) shows the second square steel pipe (200).

Referring to FIG. 6( a ), the first rectangular steel pipe 100 is a rectangular steel pipe extending long in one direction and may support the rear surface of the solar panel 20 . The upper end of the first each steel pipe 100 may be fastened to the upper side of the handrail 30 . The upper end of the first each steel pipe 100 may be fastened to the upper horizontal bar 31 . The lower end of the first each steel pipe 100 is not directly fastened to the handrail 30 .

The first square steel pipe 100 is installed at an angle with respect to the handrail 30 . The first rectangular steel pipe 100 is installed to be inclined downward, and is installed to form an acute angle with the vertical bar 33 of the handrail 30 . The lower end of the first each steel pipe 100 is spaced apart from the lower horizontal bar 32 of the handrail 30 .

A bolt hole is formed in the first each steel pipe 100 . A bolt is inserted into the bolt hole, and thus, a configuration different from that of the first steel pipe 100 may be bolted together. The bolt hole may be formed to penetrate the two opposite surfaces of the first steel pipe 100 . The bolt hole may be formed to pass through the front and rear surfaces of the first each steel pipe 100 .

As shown in FIG. 6( a ), the bolt hole may include a group 101a-c for coupling with the second square steel pipe 200 and a group 102a-b for coupling with the bracket 400 . have.

For example, the bolt holes 101a to c for coupling with the second square steel pipe 200 may be formed in three pieces. The bolt holes 102a-b for coupling with the bracket 400 may be formed in two pieces. They may each be arranged vertically. However, the number of bolt holes in the present invention is not limited.

On the other hand, at least one of the bolt holes 101a to c for coupling with the second square steel pipe 200 (eg, 101a located at the lowermost side) is also coupled to the solar panel 20 . That is, at least one 101a of the bolt holes 101a to c for coupling with the second square steel pipe 200 corresponds to the lower coupling hole 23 of the solar panel 20 and is coupled.

In addition, at least one of the bolt holes 102a to b for coupling with the bracket 400 (eg, 102a located at the uppermost side) is also coupled to the solar panel 20 . That is, at least one (102a) of the bolt holes (102a ~ b) for coupling with the bracket 400 is coupled to correspond to the upper coupling hole (24) of the solar panel (20).

The solar panel 20 is coupled to the front surface of the first each steel pipe 100 . Since the first square steel pipe 100 is installed at an angle to the handrail 30 , the solar panel 20 coupled thereto may also be installed at an angle.

As described above, the first square steel pipe 100 and the solar panel 20 may be bolted. At least one of the bolt holes of the first square steel pipe 100 and at least one of the coupling holes of the solar panel 20 may correspond to each other and may be fastened with a bolt. A nut may be coupled to the bolt to fix the bolt.

Referring to FIG. 6( b ), the second each steel pipe 200 and the first each steel pipe 100 are rectangular steel pipes that are elongated in one direction, and the angle of the first rectangular steel pipe 100 can be adjusted. The second steel tube 200 is located between the lower side of the handrail 30 and the rear surface of the first steel tube 100 .

One end of the second each steel pipe 200 is fastened to the lower side of the handrail 30 . One end of the second each steel pipe 200 may be fastened to the lower horizontal bar 32 of the handrail 30 . The other end of the second square steel pipe 200 may be coupled to the first square steel pipe 100 . However, the position at which the other end of the second steel tube 200 is coupled to the first steel tube 100 is not fixed, and may vary depending on the inclination of the solar panel 20 .

A through hole 201 penetrating the upper and lower surfaces may be formed at one end of the second rectangular steel pipe 200 . The through hole 201 may be formed in a slit shape extending from side to side. The slit-shaped through-holes 201 are formed in both the upper and lower surfaces of the second rectangular steel pipe 200 . A tie member T, which will be described later, may be inserted into the slit-shaped through-hole 201 .

A side hole 202 penetrating both sides may be formed at the other end of the second each steel pipe 200 . The side hole 202 is a hole into which a bolt for fastening the second square steel pipe 200 and the connection part 300 is inserted.

7 is a view showing an end of the handrail 30 side of the second steel pipe 200 of the solar panel holder 10 according to an embodiment of the present invention. 8 is a view showing a state in which the second steel pipe 200 and the handrail 30 of the solar panel holder 10 are coupled according to an embodiment of the present invention.

7 (a) and 7 (b), one end of the second each steel pipe 200 is located close to the lower horizontal bar 32 of the handrail 30. 7(a) is a view from above, and FIG. 7(b) is a view from below.

As described above, a slit-shaped through hole 201 penetrating the upper and lower surfaces may be formed at one end of the second rectangular steel pipe 200 . As shown in FIG. 7 , the slit-shaped through-holes 201 are formed in both the upper and lower surfaces of the second rectangular steel pipe 200 .

Referring to FIG. 8 , a tie member T may be used so that one end of the second steel pipe 200 is fastened to the lower side of the handrail 30 . The tie member T may bind the second square steel pipe 200 and the handrail 30 together.

Figure 8 (a) shows the state in which the tie member (T) is coupled to Figure 7 (a), Figure 8 (b) shows a view from the inside of the handrail 30.

The tie member T may pass through the through hole 201 of the second square steel pipe 200 . When the through hole 201 is formed in a slit shape, it may correspond to the shape of the flat tie member T. The tie member T passes through the through hole 201 of the second square steel pipe 200 and wraps the lower side (lower horizontal bar 32) of the handrail 30 to close the second square steel pipe 200. It can be fixed to the handrail 30 .

Here, since the second square steel pipe 200 has four surfaces, in order to fix the second square steel pipe 200 to the handrail 30 with a tie member (T), a through hole 201 is provided in the second square steel pipe 200. ) need to be formed.

9 is a view showing a state in which the first square steel pipe 100 and the second square steel pipe 200 of the solar panel holder 10 according to an embodiment of the present invention are coupled. 9 (a) shows in detail the state in which the first each steel pipe 100 and the second each steel pipe 200 are coupled by the connection part 300, and FIG. 9 (b) shows the connection part 300 in detail. . 10 is an exploded view of FIG. 9(a).

9 and 10 , the connection part 300 connects the first square steel pipe 100 and the second square steel pipe 200 . In particular, the other end of the second square steel pipe 200 is connected to the first square steel pipe 100 . The connection part 300 is fastened to the first square steel pipe 100 by a first bolt B1, and is fastened to the second square steel pipe 200 by a second bolt B2. The first bolt B1 and the second bolt B2 are disposed perpendicular to each other. By the first bolt B1 and the second bolt B2 disposed vertically, the first square steel pipe 100 , the second square steel pipe 200 , and the connecting part 300 may have a strong fastening force to each other.

The connection part 300 may be formed of a bent plate. The connection part 300 may be formed of a plate bent in a U-shape. The connection part 300 may be disposed to surround the other ends of the first square steel pipe 100 and the second square steel pipe 200 .

When bent in a U-shape, since a space is provided therein, the first square steel pipe 100 and the second square steel pipe 200 may be located in the inner space. In addition, each of the first square steel pipe 100 and the second square steel pipe 200 may be in contact with each side of the connection part 300 (plate), and the first bolt B1 and the second bolt B2 described above. can be concluded by

The U-shaped connector 300 may include two parallel plates 310 and 320 and one vertical plate 330 facing each other. The vertical plate 330 is positioned between the two parallel plates 310 and 320 . The parallel plates 310 and 320 and the vertical plates 330 form a U-shape.

The front surface of the first square steel pipe 100 is in contact with the vertical plate 330 , and both sides of the second square steel pipe 200 are in contact with the two parallel plates 310 and 320 .

Holes 301 , 302 , 303 are formed in the parallel plates 310 and 320 and the vertical plates 330 , respectively.

The hole 301 formed in the vertical plate 330 may correspond to the bolt hole of the first square steel pipe 100 . The first bolt B1 is inserted into the hole 301 formed in the vertical plate 330 and the bolt hole of the first square steel pipe 100 to fasten the vertical plate 330 and the first square steel pipe 100 . have.

The holes 302 and 303 formed in the parallel plate may correspond to the side holes 202 formed at the other end of the second rectangular steel pipe 200 described above. The second square steel pipe 200 may be positioned between two parallel plates. The second bolt B2 is inserted into the holes 302 and 303 formed in the parallel plate and the side hole 202 of the second square steel pipe 200 to fasten the parallel plate and the second square steel pipe 200 . have.

Since both the first square steel pipe 100 and the second square steel pipe 200 are "cornered pipes", it may be difficult for the other end of the second square steel pipe 200 to be directly coupled to the rear surface of the first square steel pipe 100 . Accordingly, the first square steel pipe 100 and the second square steel pipe 200 may be coupled to each other via the connecting part 300 .

11 is a view showing a bracket 400 according to an embodiment of the present invention. 12 is a view showing a state in which the first square steel pipe 100, the bracket 400, and the solar panel 20 are coupled according to an embodiment of the present invention. 13 is a view showing a state in which the first steel pipe 100, the bracket 400, and the solar panel 20 are coupled to the handrail 30 according to an embodiment of the present invention.

The upper end of the first rectangular steel pipe 100 and the upper side of the handrail 30 may be fastened by a bracket 400 . The bracket 400 may be bent to surround the upper end of the first each steel pipe 100 and the upper side of the handrail 30 .

Referring to FIG. 11 , the bracket 400 has three bending points and may be formed of a plate composed of four surfaces. This bracket 400 may be composed of four surfaces (410 to 440) to be described below.

The first surface 410 is in contact with the front surface of the upper end of the first each steel pipe 100 . The first surface 410 may be directly fastened to the front surface of the upper end of the first square steel pipe 100 by a bolt.

The second surface 420 is connected to the first surface 410 and is bent to be perpendicular to the first surface 410 (90 degrees). The second surface 420 is connected to the upper side of the handrail 30 beyond the upper upper side of the first each steel pipe 100 .

The third surface 430 is connected to the second surface 420 and is bent to form an obtuse angle greater than 90 degrees with the second surface 420 . The third surface 430 may be in contact with one surface of the upper horizontal bar 31 of the handrail 30 .

When the solar panel 20 is installed on the handrail 30 , it is necessary to tilt the solar panel 20 to increase power generation efficiency. The southern and middle altitude of the sun for each season considering latitude (38°) is approximately 52° in the spring or autumn equinox, 75.5° in the summer solstice, and 28.5° in the winter solstice, so the solar panel 20 is 30-70° It needs to be tilted somewhat. In consideration of this point, the angle between the second surface 420 and the third surface 430 may be between 120° and 160°. When the angle has a value between 120 and 160°, photovoltaic efficiency can be maximized.

The fourth surface 440 is connected to the third surface 430 and is bent to form an obtuse angle greater than 90 degrees with the third surface 430 . The fourth surface 440 may be parallel to the first surface 410 .

Two fastening holes 401 and 402 may be formed on the first surface 410 , and one fastening hole 404 may be formed on the fourth surface 440 . The two fastening holes 401 and 402 formed on the first surface 410 are vertically disposed.

The fastening hole 401 at the top of the first surface 410 may correspond to the bolt hole of the first square steel pipe 100 . The bolt B3 is collectively inserted into the fastening hole 401 at the top and the bolt hole of the first square steel pipe 100 , and may also be fastened to the solar panel 20 .

Referring to FIG. 12 , the fastening hole 402 under the first surface 410 corresponds to the fastening hole 403 of the fourth surface 440 , and the rod 500 is the first surface 410 . The fastening hole 402 and the fastening hole 403 of the fourth surface 440 collectively pass through, and nuts are coupled to both sides (or one side) of the rod 500, so that the rod 500 can be fixed. . This rod 500 may have a thread.

The rod 500 has a head, and the head may be seated on the fourth surface 440 , and a nut may be coupled to an end of the rod 500 opposite to the head. Alternatively, the rod 500 may not have a head, and nuts may be coupled to both sides of the rod 500 .

Referring to FIG. 13 , the bracket 400 and the rod 500 may form a closed ring surrounding the first each steel pipe 100 and the handrail 30 . Accordingly, the first square steel pipe 100 may be fixed to the handrail 30 .

The above-described connection part 300 and the bracket 400 may be made of a steel material. It may be made of aluminum or stainless steel, which is resistant to corrosion in the external environment.

With reference to the above-mentioned bar, the combined structure of the solar panel holder 10 , the solar panel 20 and the handrail 30 will be summarized.

The upper side of the first each steel pipe 100 is fastened to the upper horizontal bar 31 of the handrail 30 . The first surface 410 of the bracket 400 is positioned between the first square steel pipe 100 and the solar panel 20 . In a state in which the first surface 410 of the bracket 400 is in contact with the front surface of the first square steel pipe 100 , the bolt B3 is the uppermost bolt hole 102a of the first square steel tube 100 , the first surface It is inserted into the coupling hole 401 of 410 and the upper coupling hole 24 of the solar panel 20 (square frame 22) and is fixed with a nut. Accordingly, the bracket 400 , the first square steel pipe 100 , and the solar panel 20 may be fixed.

The third surface 430 of the bracket 400 may be fixed to contact the rear surface of the upper horizontal bar 31 of the handrail 30 . The rod 500 is inserted into the fastening hole 403 of the fourth surface 440 of the bracket 400 , and the rod 500 is the bolt hole 102b of the first square steel pipe 100 and the bracket 400 . It is inserted into the fastening hole 402 of the first surface 410 . Nuts are fitted to both sides (or one side) of the rod 500 , and the rod 500 is fixed. As a result, the upper side of the first rectangular steel pipe 100 is fixed to the upper horizontal bar 31 of the handrail 30 by the bracket 400 .

The first square steel pipe 100 is obliquely fixed to the handrail 30 (in a direction in which the other end advances outward). However, the inclination of the first steel tube 100 may vary depending on the position of the second steel tube 200 .

First, a case in which the inclination (angle between the first angle steel tube 100 and the second angle steel tube 200) of the first steel tube 100 is the largest will be looked at. This is referred to as FIGS. 1 to 13 .

The second each steel pipe 200 (the other end), and the connection part 300 are coupled to correspond to the lowermost one 101a among the bolt holes of the first each steel pipe 100 .

The vertical plate 330 of the connection part 300 is positioned between the front side of the first square steel pipe 100 and the solar panel 20 (square frame 22). In particular, the bolt hole 101a of the first square steel pipe 100, the hole 303 of the vertical plate 330, and the lower coupling hole 23 of the solar panel 20 correspond to each other, and the first bolt B1 ) passes through the bolt hole 101a of the first square steel pipe 100 , the hole 303 of the vertical plate 330 , and the lower coupling hole 23 of the solar panel 20 . When the nut N is coupled to the end of the first bolt B1, the first bolt B1 is fixed. Accordingly, the first square steel pipe 100 , the connection part 300 , and the solar panel 20 may be fixed to each other.

A second angle steel pipe 200 is positioned between the two horizontal plates of the connection part 300 . In particular, the side hole 202 of the second square steel pipe 200 and the holes 301 and 302 of the horizontal plate correspond to each other, and the second bolt B2 is the side hole 202 of the second square steel pipe 200 . and through holes 301 and 302 of the horizontal plate. When the nut N is coupled to the end of the second bolt B2, the second bolt B2 is fixed. Accordingly, the second square steel pipe 200 and the connecting portion 300 may be fixed to each other. As a result, the first square steel pipe 100 , the second square steel pipe 200 , and the connection part 300 may be fixed to each other. Since the second bolt B2 and the first bolt B1 are disposed perpendicular to each other, the first square steel pipe 100 , the second square steel pipe 200 , and the connection part 300 can be stably and strongly fixed. .

On the other hand, one end of the second square steel pipe 200 is positioned toward the handrail 30 . One end of the second square steel pipe 200 may be fixed to the lower horizontal bar 32 of the handrail 30 by a tie member (T). The tie member T is inserted into the slit-shaped through-hole 201 formed at one end of the second rectangular steel pipe 200 , and can bind the handrail 30 . Accordingly, the second square steel pipe 200 is fixed to the lower horizontal bar 32 of the handrail 30 . As a result, the solar panel holder 10 is fixed to the handrail 30 , and the solar panel 20 may also be fixed to the handrail 30 .

The angle between the first square steel pipe 100 and the second square steel pipe 200 may be changed, and the angle between the connection part 300 and the second square steel pipe 200 may be changeable. This angle may vary depending on the coupling position of the first steel tube 100 and the second steel tube 200 . In addition, according to a position where the connection part 300 is coupled to the first square steel pipe 100 , the angle between the first square steel pipe 100 and the second square steel pipe 200 may be changed.

A plurality of bolt holes 101a-c arranged vertically are formed in the first square steel pipe 100, and the first bolt B1 is inserted into at least one of the plurality of bolt holes 101a-c, and , as the first bolt (B1) is inserted into the bolt hole located at a high place, the angle between the first square steel pipe 100 and the second square steel pipe 200 may be reduced. In addition, as the connection part 300 is inserted into the bolt hole positioned at a higher position among the plurality of bolt holes, the solar panel 20 may be installed closer to the handrail 30 and closer to the vertical.

Meanwhile, the angle between the connection part 300 and the second square steel pipe 200 may also vary according to the bolt hole to which the first bolt B1 is coupled.

Hereinafter, a case in which the inclination of the first square steel pipe 100 (the angle between the first square steel pipe 100 and the second square steel pipe 200) decreases will be described. This is referred to as FIGS. 14 to 16 .

14 to 16 are views showing the angle change of the solar panel holder 10 according to an embodiment of the present invention. In the case of FIGS. 14 to 16 , compared to the previous case, the solar panel 20 is installed closer to the handrail 30 and closer to the vertical.

The other end of the second steel pipe 200, and the connection part 300 correspond to the other (101b or 101c) other than the lowermost one (101a) among the multiple bolt holes of the first steel pipe 100. are combined 14 to 16 show that the connection part 300 is coupled to the second bolt hole 101b.

The vertical plate 330 of the connection part 300 is in contact with the front surface of the first square steel pipe 100, the bolt hole 101b of the first square steel pipe 100, the hole 303 of the vertical plate 330 corresponds to each other, and the first bolt B1 collectively penetrates the bolt hole 101b of the first square steel pipe 100 and the hole 303 of the vertical plate 330 . When the nut N is coupled to the end of the first bolt B1, the first bolt B1 is fixed. Accordingly, the first square steel pipe 100 and the connecting portion 300 may be fixed to each other.

On the other hand, the lowermost one 101a of the bolt holes corresponds to the lower coupling hole 23 of the solar panel 20, and the additional bolt B4 is the bolt hole ( 101a), the lower coupling hole 23 of the solar panel 20 is collectively penetrated. When the nut (N) is coupled to the end of the additional bolt (B4), the additional bolt (B4) is fixed. Accordingly, the first square steel pipe 100 and the solar panel 20 may be fixed to each other.

When the angle of the first square steel pipe 100 and the second square steel pipe 200 is the maximum, there is no need for an additional bolt (B4), and the first bolt (B1) is the first square steel pipe 100, the connection part 300 ), the solar panel 20 is collectively fastened. However, when reducing the angle of the first square steel pipe 100 and the second square steel pipe 200, additional bolts (B4) are further required.

A second angle steel pipe 200 is positioned between the two horizontal plates of the connection part 300 . In particular, the side hole 202 of the second square steel pipe 200 and the holes 301 and 302 of the horizontal plate correspond to each other, and the second bolt B2 is the side hole 202 of the second square steel pipe 200 . and through holes 301 and 302 of the horizontal plate. When the nut N is coupled to the end of the second bolt B2, the second bolt B2 is fixed. Accordingly, the second square steel pipe 200 and the connecting portion 300 may be fixed to each other. As a result, the first square steel pipe 100 , the second square steel pipe 200 , and the connection part 300 may be fixed to each other. Since the second bolt B2 and the first bolt B1 are disposed perpendicular to each other, the first square steel pipe 100 , the second square steel pipe 200 , and the connection part 300 can be stably and strongly fixed. .

The connection part 300 and the second square steel pipe 200 may always maintain the same angle regardless of the angle of the first square steel pipe 100 and the second square steel pipe 200 . For example, the connection part 300 and the second square steel pipe 200 may always be horizontal.

Meanwhile, the inclination of the solar panel 20 may be finely adjusted by changing the angle of the connection part 300 and the second angle steel pipe 200 . The connection part 300 and the second square steel pipe 200 may be hinged to each other using the second bolt B2 as a hinge axis.

In addition, the angle of the connection part 300 and the second square steel pipe 200 may be changed according to the angle of the first square steel pipe 100 and the second square steel pipe 200 .

For example, when the angle of the first square steel pipe 100 and the second square steel pipe 200 is maximum, the connection part 300 and the second square steel pipe 200 may be substantially horizontal. When the angle of the first square steel pipe 100 and the second square steel pipe 200 is reduced, the second square steel pipe 200 and the connecting part 300 do not form a horizontal but may be disposed to form an obtuse or acute angle. However, the angle of the second square steel pipe 200 and the connection part 300 may vary depending on the size of the handrail 30 and the size of the solar panel 20 .

On the other hand, also in the case of Figures 14 to 16, the coupling structure of one end of the second square steel pipe 200 and the handrail 30 is the same as in the previous case.

On the other hand, when the connection part 300 is coupled to correspond to the 101c bolt hole, the angle of the first square steel pipe 100 and the second square steel pipe 200 is further reduced than in the case of FIGS. 14 to 16 , and the solar panel (20) may be installed closer to the handrail (30).

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the protection scope of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention pertains.

10: Solar panel cradle
20: solar panel
21: square frame
30: handrail
100: first square steel pipe
200: second square steel pipe
300: connection
400: bracket
500: load

Claims (9)

A solar panel holder for installing a solar panel on a railing,
a first each steel pipe supporting the rear surface of the solar panel and having an upper end fastened to the upper side of the handrail;
a second steel tube positioned between the lower side of the handrail and the rear surface of the first steel tube, one end of which is fastened to the lower side of the handrail; and
and a connecting part connecting the other ends of the first each steel pipe and the second each steel pipe,
The first square steel pipe and the connection part are fastened by a first bolt,
The second each steel pipe and the connecting portion are fastened by a second bolt disposed perpendicular to the first bolt,
Solar panel stand. The method of claim 1,
The connection part is formed of a plate bent in a U-shape,
The connecting portion surrounds the other ends of the first and second each steel pipe,
Solar panel stand. 3. The method of claim 2,
The connecting portion includes two parallel plates facing each other; and a vertical plate positioned between the two parallel plates,
The front surface of the first each steel pipe is in contact with the vertical plate,
Both sides of the second each steel pipe are in contact with the two parallel plates,
Solar panel stand. According to claim 1,
The first bolt is to collectively fasten the first square steel pipe, the connection part, and the solar panel,
Solar panel stand. According to claim 1,
A through hole passing through the upper and lower surfaces is formed at the one end of the second each steel pipe,
The one end of the second square steel pipe and the lower side of the handrail are fastened by a tie member passing through the through hole,
Solar panel stand. According to claim 1,
The angle between the first square steel pipe and the second square steel pipe is changeable,
The angle between the connection part and the second angle steel pipe is changeable,
Solar panel stand. The method of claim 1,
According to the position where the connection part is coupled to the first each steel pipe,
The angle between the first each steel pipe and the second each steel pipe is changed,
Solar panel stand. 8. The method of claim 7,
A plurality of bolt holes arranged vertically are formed in the first each steel pipe,
The first bolt is inserted into at least one of the plurality of bolt holes,
As the first bolt is inserted into the bolt hole located at a high place, the angle between the first steel pipe and the second steel pipe becomes smaller,
Solar panel stand. According to claim 1,
Further comprising a bracket for fastening the upper end of the first each steel pipe and the upper side of the handrail,
The bracket is bent to surround the upper end of the first each steel pipe and the upper side of the handrail,
The bracket and the first each steel pipe are bolted together,
Solar panel stand.

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