KR102181834B1 - Photovoltaic Power Generation System - Google Patents

Abstract

The present invention relates to a solar power generation system. The solar power generation system comprises: a solar cell array; a structure in which a vertical bar and a horizontal bar are coupled to each other to support the solar cell array; an inverter connected to a junction box of the solar cell array by a wire; and a wire profile located between the solar cell array and the horizontal bar and formed with an accommodation space which is a space capable of accommodating the wire. The wire profile includes: an accommodation body having an open upper surface and formed with the accommodation space; and a coupling wing vertically protruding from the accommodation body and coupled to a solar cell module frame of the solar cell array. Therefore, the wire connected to the junction box is inserted into the inside of the wire profile to be connected with the inverter, thereby having a beautiful exterior of the solar power generation system.

Description

Photovoltaic Power Generation System {Photovoltaic Power Generation System}

The present invention relates to a solar power system.

Fossil energy sources using oil, coal and natural gas have limited reserves and are predicted to be depleted in the near future, and fossil energy sources are the main cause of serious air pollution.

In addition, nuclear energy sources have risks such as radioactive waste, so the need for changes in energy use is raised. In particular, the Korean government is actively supporting new and renewable energy projects such as solar energy, wind power, hydropower, geothermal energy, marine energy, and bio energy due to its high dependence on oil and low energy independence.

Photovoltaic power generation, one of power generation using renewable energy, is a technology that converts solar energy into electric power using a solar power generation system. Unlike fossil energy sources, sunlight does not emit greenhouse gases or cause environmental damage, and solar radiation has endless advantages. In 1839, a scientific discovery of the photoelectric effect was made in France, and a technology capable of manufacturing ultra-high purity single crystal silicon was developed in the 1940s, and it was first commercialized as a Vanguard satellite in the United States in 1958.

In the solar power generation system, a solar cell module that generates DC electricity by receiving sunlight, an inverter, and a junction box to which a wire for transmitting the produced DC electricity to the storage battery are connected are installed at the rear of the solar cell module.

On the other hand, the smallest unit of a solar cell is a cell, and the cell is assembled to make a module, and a frame frame is placed around the module to be fixed. Then, the modules are connected to form an array.

Such an array is installed in a structure consisting of a column and a horizontal and vertical frame connected to the column. At this time, the wires were still exposed to the outside, resulting in a messy appearance.

In the solar power generation system, since the amount of power generated by the solar cell module is largely influenced by the amount of light incident on the solar cell module, the amount of power generated is greatly reduced when the surface of the solar cell module is contaminated by dust or foreign matter. Therefore, in the solar power generation system, the surface of the solar cell module must be cleaned. Accordingly, it is a situation in which the surface of the solar cell module is cleaned by simply brushing it off with a tool such as a brush, or by spraying water on the surface of the solar cell module to clean it.

In addition, since the solar power generation system is installed outdoors to expose the solar cell module, it may be damaged by rainfall, snowfall, or strong wind.

Korean Patent Registration No. 10-1563924 (2015.10.22.) Korean Patent Registration No. 10-1935476 (2018.12.28.)

The present invention provides a technology for preventing the wires connecting the junction box and the inverter installed at the rear of the solar cell array from being exposed.

The present invention is easy to clean the solar cell module, and provides a technology for protecting the solar cell module from requirements such as rainfall, snowfall, and strong wind.

A solar power generation system according to an embodiment of the present invention includes a solar cell array consisting of solar cell modules, a structure in which vertical bars and horizontal bars are combined to support the solar cell array, and connected to the junction box of the solar cell array by wires. The inverter, located between the solar cell array and the horizontal bar, and a space capable of accommodating the electric wire is connected to one side of the installation unit consisting of a combination of a wire profile having an accommodation space and a horizontal bar of the structure, It includes an opposing cover reflector.
The cover reflector may include a reflective plate facing the solar cell array, and a hinge driving unit rotatably connecting the reflective plate to the installation unit.
The hinge drive unit is a shaft protruding from the reflective plate, a bushing member located on both sides of the reflective plate to support the shaft to rotate and coupled to the installation unit, a sprocket connected to the shaft, and a chain connected to the sprocket It may include a drive motor that has been.
The reflective plate may cover the solar cell array by driving the driving motor or reflect the incident sunlight to the solar cell array at a predetermined angle with the solar cell array.

The electric wire profile includes: a receiving body having an open upper surface and having the receiving space; And a coupling blade protruding vertically from the receiving body and coupled to the frame of the solar cell module. It may include.

The coupling blades may be vertically protruded from both sides of the upper surface of the receiving body in a length of 10 mm to 20 mm in an outward direction, respectively, and may be formed along the length direction of the receiving body.

The coupling blades may be vertically formed in the inner and outer directions on both sides of the upper surface of the receiving body, respectively, and may be formed along the longitudinal direction of the receiving body.

The coupling blade may protrude in a length of 10 mm to 20 mm in an outward direction and a length of 5 mm to 10 mm in an inward direction based on a side surface of the receiving body.

The wire profile includes: a plurality of friction protrusions formed along an inner circumference of the receiving body along a longitudinal direction of the receiving body and arranged in a vertical direction around the inner circumference of the receiving body; It may further include.

The friction protrusion protrudes from the inner circumference of the receiving body in the form of a right triangle, and the range arranged in the vertical direction may be 5 mm to 15 mm based on the coupling blade.

The height of the receiving body may be 30mm to 40mm, the width may be 40mm to 60mm, and the thickness between the inner circumference and the outer circumference may be 0.5mm to 1.5mm.

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The reflective plate may include a plate body connected to the shaft and having one surface facing the solar cell array; A reflective layer formed on one surface of the plate body and reflecting incident sunlight to the solar cell array; And an advertisement layer formed on the other surface of the plate body. It may include.

While the reflective plate covers the solar cell array, the advertisement layer may be exposed and emit light.

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A locking hole may be formed in the coupling blade overlapping the frame of the solar cell module.

The photovoltaic power generation system may further include a profile fixing part positioned between the adjacent solar cell modules and coupled to the locking hole.

The profile fixing part, a support member in contact with the lower surface of the coupling wing; A locking protrusion protruding from the support member and inserted into the locking hole; A connecting member protruding vertically from the support member and passing between adjacent solar cell modules; And a mounting member protruding vertically from an upper end of the connecting member to both sides and contacting an upper surface of the solar cell module. It may include.

According to an embodiment of the present invention, the wires connecting the inverter of the junction box are arranged by the wire profile, so that they are not exposed to the outside of the solar power generation system. Therefore, the appearance of the solar power system is beautiful.

According to an embodiment of the present invention, the profile fixing portion is fixed between adjacent solar cell modules, and the locking hole of the coupling blade is caught by the locking projection and fixed. Accordingly, the solar cell array is fixed to the wire profile. It is possible to shorten the installation time of the wire profile than to fix it using a screw, and it is easy to remove.

According to an embodiment of the present invention, when the cover reflector is erected, the incident sunlight is reflected by the solar cell array to increase the solar light incident rate to the solar cell array, thereby increasing solar power generation efficiency. In addition, when the cover reflector is laid down, the solar cell array can be protected from external requirements, and the solar power generation system can be used for advertisements by exposure of the advertisement layer, thereby increasing use efficiency.

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1 is a bottom perspective view showing a solar power generation system according to an embodiment of the present invention.
2 is an enlarged view of part A of FIG. 1.
Figure 3 is a cross-sectional view showing the wire profile of Figure 2;
Figure 4 is a cross-sectional view showing another embodiment of the wire profile of Figure 3;
Figure 5 is a cross-sectional view showing another embodiment of the wire profile of Figure 3;
6 is an exploded view showing the wire profile of FIG. 2 and a profile fixing part for coupling a solar cell array.
Figure 7 is a schematic view showing a coupling state of the profile fixing portion of Figure 4;
Figure 8 is a schematic diagram showing a solar power generation system according to another embodiment of the present invention.
9 is a schematic view showing a portion of the cover reflector of FIG. 8;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. However, the present invention may be implemented in a number of different forms and is not limited to the embodiments described herein. The same reference numerals are assigned to similar parts throughout the specification.

Then, a solar power generation system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

1 is a bottom perspective view showing a photovoltaic power generation system according to an embodiment of the present invention, FIG. 2 is an enlarged view of part A of FIG. 1, and FIG. 3 is a cross-sectional view showing the wire profile of FIG. 2.

1 to 3, the solar power generation system 1 according to the present embodiment includes a solar cell array 10, a structure 30, an inverter 20, and a wire profile 40a, and includes a junction box ( The electric wire 113 connecting the 112 and the inverter 20 is not exposed so that the appearance of the solar power generation system 1 can be beautiful.

The solar cell array 10 is composed of a combination of a solar module 11 composed of a solar cell, tempered glass, EVA sheet, back sheet, frame 111, and junction box 112, and direct current by incident sunlight. Produces electricity.

The structure 30 is composed of a combination of a vertical bar 31 and a horizontal bar 321. The vertical bar 31 is erected and the lower end is fixed to the ground. The vertical bars 31 are arranged in the front and rear, left and right directions, and the vertical bars 31 have different vertical lengths.

The horizontal bar 321 is composed of a horizontal bar and a vertical bar to form an installation part 32 to which the solar cell array 10 is fixed. The installation part 32 is inclined from one side to the other side by vertical bars 31 having different lengths. At this time, the height of the other side is higher than the height of one side based on the ground. Such a structure 30 is continuously arranged in front and rear, left and right directions at the installation site of the solar power generation system 1.

The inverter 20 is disposed on one side of the structure 30 and is connected to the junction box 112 by an electric wire 113.

The detailed configuration of the solar cell array 10, the structure 30, and the inverter 20 is the same as the solar cell array, structure, and inverter of a known solar power generation system, and thus a detailed description thereof will be omitted.

The wire profile 40a includes a receiving body 41, and a coupling blade 42a, and is located between the solar cell array 10 and the installation part 32 to accommodate the wire 113. The electric wire 113 is arranged by the electric wire profile 40a and is not exposed to the outside of the solar power system 1. The wire profiles 40a are installed along the width direction 10W of the solar cell array 10 and are arranged in the length direction 10L.

The receiving body 41 has an open upper surface facing the solar cell array 10, and a receiving space 411 in which the electric wire 113 is located is formed along the length direction. The accommodation space 411 is open to the upper surface of the receiving body 41 and both sides in the longitudinal direction. Caps 44 for blocking foreign matters from entering into the receiving space 411 are coupled to the open sides. The cap 44 may be made of rubber or the like.

The height 41H of the receiving body 41 may be 30mm to 40mm. However, the height 41H of the receiving body 41 may be 35mm. The width 41W of the receiving body 41 may be 40mm to 60mm. However, the width 41W of the receiving body 41 may be 50mm. In addition, the thickness 41T between the outer circumference and the inner circumference of the receiving body 41 may be 0.5mm to 1.5mm. However, the thickness 41T may be 1 mm. When the height 41H of the receiving body 41 is less than 30mm and the width 41W is less than 40mm, the receiving space 411 accommodating the electric wire 113 becomes narrow, so that electric wires can be accommodated. When the height 41H of the receiving body 41 exceeds 40mm and the width 41W exceeds 60mm, there is difficulty in transportation and installation due to an increase in the volume of the receiving body 41. And if the thickness (41T) is formed to be less than 0.5mm, it is easily damaged by external force, and if it exceeds 1.5mm, the strength is improved but there is difficulty in transportation and installation due to an increase in weight.

The coupling blades 42a are vertically protruded outwardly from both sides of the open upper surface of the receiving body 41 and formed along the longitudinal direction of the receiving body 41.

The coupling blades 42a are in contact with the frame 111 of the solar cell module 11 and face the back sheet of the solar cell module 11 at an interval. The frame 111 and the coupling blade 42a are in contact with each other by screwing the wire profile 40a to which the solar cell array 10 is fixed. By fixing the coupling blades (42a), the lower surface of the receiving body 41 faces the installation part 32 at an interval. In addition, a gap is formed between the back sheet and the coupling blade 42a, and the wire 113 connected to the junction box 112 is inserted into the accommodation space 411 through the gap. Accordingly, a hole for inserting the electric wire 113 into the receiving space 411 can be inserted into the receiving space 411 without forming a hole in the receiving body 41.

And the coupling blade (42a) is protruding from 10mm to 20mm length (42L). However, the protruding length 42L of the coupling blade 42a may be 15mm. And the thickness of the coupling wing (42a) is the same as the thickness (41T) of the receiving body (41). If the length (42L) of the coupling blade (42a) is less than 10mm, the contact area with the frame 111 is narrow, making it inconvenient to connect the screw, and furthermore, the coupling blade (42a) may be damaged during the process of tightening the screw with a thickness less than 0.5mm I can. And if the length (42L) exceeds 20mm, the screw can be fastened easily due to the increase in the contact area, and the weight of the wire profile (40a) can be increased, and if the thickness exceeds 1.5mm, the screw can tighten the coupling blade (42a). As the passing time increases, the fixing time of the wire profile 40a increases, thereby hindering the installation work.

Such a wire profile 40a may be made of metal or the like. The material of the wire profile 40a is not limited to metal.

Next, another embodiment of the wire profile will be described with reference to FIG. 4.

4 is a cross-sectional view showing another embodiment of the wire profile of FIG. 3.

Referring to FIG. 4, the wire profile 40b according to this embodiment has most of the components of the embodiment described with reference to FIG. 3. However, the coupling blades 42b of the wire profile 40a according to the present embodiment are vertically protruded from both sides of the open upper surface of the receiving body 41 in the inward and outward directions, respectively, and are formed along the longitudinal direction of the receiving body 41 have. The coupling blade 42b has a length 42OUT_L protruding outward from the side 412 of the receiving body 41 is 10mm to 20mm, and a length 42IN_L protruding in the inward direction is 5mm to 10mm. Accordingly, the total length of the coupling blade (42b) according to this embodiment is 15mm to 20mm. The portion of the coupling blade 42b protruding outward is coupled with the frame 111 of the solar cell module 11 through a screw, and the portion of the coupling blade 42b protruding inwardly is a wire accommodated in the receiving space 411 ( 113) do not deviate.

For other configurations, the configuration of the embodiment of FIG. 3 may be applied as it is.

Next, another embodiment of the wire profile will be described with reference to FIG. 5.

5 is a cross-sectional view showing another embodiment of the wire profile of FIG. 3.

Referring to FIG. 5, the wire profile 40c according to the present exemplary embodiment has most of the constituent elements of the exemplary embodiment described with reference to FIGS. 3 or 4. However, the wire profile 40c according to the present embodiment further includes a friction protrusion 43. In Figure 5, the coupling blade (42c) is shown to protrude in the outer direction of the receiving body 41, but the coupling blade (42c) may also protrude in the inner direction of the receiving body (41).

The friction protrusion 43 is formed along the length direction of the receiving body 41 by protruding 1mm from the inner circumference of the receiving body 41 to the inner center. The friction protrusion 43 is composed of a horizontal surface perpendicular to the inner circumference of the receiving body 41 and an inclined surface inclined toward the inner circumference of the receiving body 41 in the horizontal plane. Accordingly, the friction protrusion 43 forms a right triangle shape.

The friction protrusions 43 are arranged in the vertical direction around the inner circumference of the receiving body 41. The friction protrusions 43 are arranged in a range of 5mm to 15mm (43L) based on the coupling blades 42a. However, the friction protrusion 43 may be arranged in a range of 10 mm. The friction protrusion 43 increases the coefficient of friction to prevent separation of the electric wire 113 inserted into the receiving space 411 from the open upper portion of the receiving body 41.

For other configurations, the configurations of the embodiments of FIGS. 3 and 4 may be applied as they are.

Next, another embodiment of the solar power generation system will be described with reference to FIGS. 6 and 7.

FIG. 6 is an exploded view showing the wire profile of FIG. 2 and a profile fixing part for coupling a solar cell array, and FIG. 7 is a schematic diagram showing a combined state of the profile fixing part of FIG. 4.

Referring to FIGS. 6 and 7, the solar power generation system 2 according to the present embodiment may further include a profile fixing part 50 while including the embodiments of FIGS. 1 to 5 as it is.

The profile fixing part 50 includes a support member 51, a locking protrusion 52, a connection member 53, and a seating member 54, and the wire profile 40a is attached to the solar cell array 10 without using screws. To fix.

Engagement holes 421 are formed in the coupling wing 42a at intervals along the length direction. The portion where the locking hole 421 is formed is in contact with the frame 111 of the solar cell module 11.

The support member 51 has a predetermined length and is in contact with the lower surface 422 of the coupling blade 42a. The support member 51 is located in the portion where the locking hole 421 is formed. On the other hand, a part of the support member 51 is out of the coupling wing (42a).

The locking protrusion 52 protrudes vertically from one surface in contact with the coupling blade 42a and is inserted into the locking hole 421.

Although it is assumed that the locking protrusion 52 is caught in the locking hole 421, the locking protrusion 52 and the locking hole 421 may be omitted. In this case, an unevenness is formed between the support member 51 and the frame 111 of the solar cell module 11 to be engaged.

The connection member 53 protrudes vertically upward from the support member 51 that is away from the coupling wing 42a. The connecting member 53 is exposed to the upper portion of the solar cell module 11 through the frames 111 of the adjacent solar cell module 11.

The seating member 54 protrudes vertically from the end of the connecting member 53 and covers the frame 111 of the solar cell module 11. And although not shown in the drawing, irregularities are formed between the seating member 54 and the frame 111 of the solar cell module 11 so that the seating member 54 does not slide on the frame 111 of the solar cell module 11. .

Accordingly, the frame 111 of the solar cell module 11 passes between the seating member 54 and the support member 51.

The profile fixing part 50 is fixed between the adjacent solar cell modules 11 and the locking hole 421 of the coupling wing 42a is caught and fixed by the locking protrusion 52, while the wire profile 40a is The battery array 10 is fixed. Accordingly, it is possible to shorten the installation time of the wire profile 40a than to fix using a screw, and it is easy to separate.

For other configurations, the configurations of the embodiments of FIGS. 1 to 7 may be applied as they are.

Next, another embodiment of the solar power generation system will be described with reference to FIGS. 8 and 9.

8 is a schematic diagram showing a photovoltaic power generation system according to another embodiment of the present invention, and FIG. 9 is a schematic diagram showing a part of the cover reflector of FIG. 8.

Referring to FIGS. 8 and 9, the photovoltaic power generation system 3 according to the present embodiment further includes a cover reflector 60 while still including the embodiments of FIGS. 1 to 7.

The cover reflective unit 60 further includes a reflective plate 61 and a hinge driving unit 62, and reflects incident sunlight to the solar cell array 10 and reflects the solar cell array 10 with strong winds, snow, rainfall, etc. To protect against external requirements.

The reflective plate 61 includes a plate body 611, a reflective layer 612 and an advertisement layer 613, and reflects incident sunlight to the solar cell array 10 or protects the solar cell array 10 from external requirements. do.

The plate body 611 has a width that can cover the solar cell array 10. One side of the plate body 611 is connected to one side of the installation part 32 and can move based on one side. Accordingly, the plate body 611 may be erected or laid on one side.

The reflective layer 612 is disposed on one surface of the plate body 611 facing the solar cell array 10. When the plate body 611 is erected, the reflective layer 612 is inclined to the solar cell array 10 at a predetermined angle, and the incident sunlight is specularly reflected to the solar cell array 10. Accordingly, the reflective layer 612 may be formed of a film or a mirror that can reflect light. Meanwhile, the reflective layer 612 may diffusely reflect incident light.

Solar light reflected to the solar cell array 10 through the reflective layer 612, and sunlight irradiated to the solar cell array 10 by sunlight directly incident on the solar cell array 10 is further improved to generate solar power. The efficiency is improved.

The advertisement layer 613 is disposed on the other surface of the plate body 611. When the plate body 611 is erected, the advertisement layer 613 is covered by neighboring structures. However, when the plate body 611 is laid down, the advertisement layer 613 is exposed.

Characters, figures, and the like are formed on the advertisement layer 613 to represent advertisements. Characters and figures may be formed of LEDs capable of emitting light. However, characters and figures may be formed by printing with a phosphorescent pigment. That is, it can be applied in various ways if it can increase visibility at night.

Accordingly, when the solar power generation system 3 is installed in a place that is exposed to people, such as a place close to a road or a hillside, the advertisement layer 613 of the cover reflector 60 is exposed. It can be used for advertising other than production. In particular, since the advertisement layer 613 is exposed at night due to light emission, the advertisement efficiency is further improved.

The hinge driving unit 62 includes a shaft 621, a bushing member 622, a sprocket 623, and a driving motor 624, and rotates the reflective plate 61 to stand or lay it down.

The shaft 621 protrudes outward from both sides of one side of the plate body 611. The shaft 621 is integrally formed with the plate body 611.

The bushing member 622 is located on both sides of the plate body 611 and is coupled to the shaft 621. The bushing member 622 supports the shaft 621 so that it can rotate. The bushing member 622 is coupled to one side of the installation part 32.

The sprocket 623 is coupled to the shaft 621. At this time, when the sprocket 623 rotates, the sprocket 623 and the shaft 621 are key-coupled so that the shaft 621 can rotate along with it.

The drive motor 624 is disposed on one side of the installation part 32 and is powered by a sprocket 623 and a chain 624a. The power of the driving motor 624 is transmitted to the sprocket 623 through the chain 624a so that the shaft 621 rotates. At this time, the reflective plate 61 is erected or laid down according to the rotation direction of the shaft 621.

The cover reflector 60 reflects the incident sunlight when it is erected to the solar cell array 10 to increase the solar light incident rate to the solar cell array 10 to increase solar power generation efficiency. In addition, when the cover reflector 60 is laid, the solar cell array 10 can be protected from external requirements, and the solar power generation system 3 can be used for advertisements by exposure of the advertisement layer 613 to increase use efficiency. .

For other configurations, the configurations of the embodiments of FIGS. 1 to 7 may be applied as they are.

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Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1, 2, 3, 4, 5, 6: solar power system
10: solar cell array 10W: width direction
10L: longitudinal direction 11: solar module
111: frame 112: junction box
113: wire 20: inverter
30: structure 31: vertical bar
32: installation part 321: horizontal bar
40a, 40b, 40c: wire profile 41: receiving body
411: accommodation space 41H: height
41W: width 41T: thickness
42a, 42b, 42c: coupling blade 42L, 42I_L, 42OUT_L: length
421: locking hole 422: lower surface
43: friction projection 44: cap
50: profile fixing portion 51: support member
52: stopping protrusion 53: connecting member
54: seating member 60: cover reflector
61: reflective plate 611: plate body
612: reflective layer 613: advertisement layer
62: hinge drive unit 621: shaft
622: bushing member 623: sprocket
624: drive motor

Claims (23)

Solar cell array consisting of solar cell modules,
A structure in which vertical bars and horizontal bars are coupled to each other to support the solar cell array,
An inverter connected to the junction box of the solar cell array by an electric wire,
A wire profile in which an accommodation space is formed between the solar cell array and the horizontal bar and a space capable of accommodating the wire
A cover reflector connected to one side of the installation part made of a combination of horizontal bars of the structure and facing the solar cell array
Including,
The cover reflector includes a reflective plate facing the solar cell array, and a hinge driving unit rotatably connecting the reflective plate to the installation unit,
The hinge drive unit is a shaft protruding from the reflective plate, a bushing member located on both sides of the reflective plate to support the shaft to rotate and coupled to the installation unit, a sprocket connected to the shaft, and a chain connected to the sprocket It includes a drive motor that has been
The reflective plate covers the solar cell array by driving the driving motor or reflects the incident sunlight to the solar cell array at a predetermined angle with the solar cell array.
Solar power system. In claim 1,
The wire profile is
A receiving body with an open upper surface and formed with the receiving space, and
A coupling blade protruding vertically from the receiving body and coupled to the frame of the solar cell module
Including,
The coupling blades are vertically protruding from both sides of the upper surface of the receiving body in a length of 10 mm to 20 mm in an outer direction, respectively, and formed along the length direction of the receiving body. In paragraph 2,
The coupling blades are vertically formed in the inner and outer directions on both sides of the upper surface of the receiving body, respectively, and formed along the length direction of the receiving body. In paragraph 3,
The coupling blade is a solar power generation system that protrudes in a length of 10 mm to 20 mm in an outward direction and a length of 5 mm to 10 mm in an inward direction based on a side surface of the receiving body. In claim 2 or 3,
The wire profile,
A photovoltaic power generation system further comprising: a plurality of friction protrusions formed along the longitudinal direction of the receiving body around the inner circumference of the receiving body and arranged in a vertical direction around the inner circumference of the receiving body. In clause 5,
The friction protrusion protrudes in the form of a right triangle from the inner circumference of the receiving body, and the range arranged in the vertical direction is 5 mm to 15 mm based on the coupling blade. In paragraph 2,
The height of the receiving body is 30mm to 40mm, the width is 40mm to 60mm, and the thickness between the inner circumference and the outer circumference is 0.5mm to 1.5mm. delete delete delete In claim 1,
The reflective plate
A plate body connected to the shaft and having one side facing the solar cell array,
A reflective layer formed on one surface of the plate body and reflecting incident sunlight to the solar cell array; and
It is formed on the other side of the plate body and the advertisement layer
Including,
When the reflective plate covers the solar cell array, the advertisement layer is exposed and emits light.
Solar power system. delete delete delete delete delete delete delete delete delete delete In paragraph 2,
A locking hole is formed in the coupling blade overlapping the frame of the solar cell module,
A photovoltaic system further comprising a profile fixing part positioned between the adjacent solar cell modules and coupled to the locking hole. In claim 22,
The profile fixing part,
A support member in contact with the lower surface of the coupling wing;
A locking protrusion protruding from the support member and inserted into the locking hole;
A connecting member protruding vertically from the support member and passing between adjacent solar cell modules; And
A mounting member protruding vertically from an upper end of the connecting member to both sides and contacting an upper surface of the solar cell module;
Including
Solar power system.

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