KR20180138376A - Method & system apparatus for installing solar cell panel on mountain slope. - Google Patents

Abstract

The present invention relates to a method and a system device for installing a large amount of solar cell panels on a mountain slope, and more particularly, to a system, which installs a plurality of rails short-circuited at regular intervals depending on topography, on a mountain slope in a stepwise manner, has frames of a plurality of solar cell panels mounted on the rails, and has a length-variable connection means between four corners of each of the frames and rails, such that the slope of the panels is varied by varying the length of the connection means even after construction of the system, and the slope is arbitrarily varied in a 360 degree direction to maintain an optimal solar power generating efficiency. Accordingly, the present invention is to provide a system technology for constructing an eco-friendly solar power generating plant replaced with nuclear power generation or thermal power generation in the future since costs for solar power generation can be remarkably reduced with a step-wise system technology capable of being safe from strong wind by fastening four axes of the solar cell panels, simply maintaining the panels with a frame detached and attached by sliding the panels, semi-permanently improving the lifespan of a solar power generation system due to a panel replacement, and creating a large scale of a solar power panel complex using a mountain.

Description

METHOD AND SYSTEM APPARATUS FOR INSTALLING SOLAR CELLS PANEL ON SLOPPING RIVER.

The present invention relates to a method and system for installing a solar cell panel for solar power generation on a mountain slope and more particularly to a method for installing a solar cell panel on a flat ground, A solar cell panel installation system that can securely install a solar cell panel in four axes regardless of the structure and inclination angle of the panel and can vary the slope of the panel arbitrarily and change the slope of the panel to 360 degrees after installation, To an application system device.

A conventional method of installing a solar cell panel is to install a panel composed of a plurality of solar cell modules on a floor mount and to adjust the tilt of the panel in advance or to remotely control the solar cell panel. , It is vulnerable to typhoons and strong winds. In order to avoid the shade between the panels, a large area is needed because of the separation distance.

In addition, the conventional flat landing method is disadvantageous in that it is difficult to maintain the solar cell panel because it is easily broken due to the strong wind of the mountain slope when it is installed on a sloping mountain slope.

In addition, when a solar cell panel for solar power generation is installed on a flat land, there is a problem that the cost of purchasing land is high, thereby increasing the production cost of the photovoltaic power generation. Therefore, an effective method of installing a large number of photovoltaic power generation panels .

The conventional solar cell panel installation system is composed of a stationary type that fixes the angle of reflection of the panel with a prefabricated stand and a variable type that adjusts the slope of the panel between the stand and the panel arbitrarily.

Korean Patent No. 10-1108713 (a photovoltaic device with easy inclination angle adjustment) connects a holder and a solar cell panel with a hinge axis and configures a device for varying the degree of inclination of the hinge axis. However, There is a problem that the panel is broken due to the strong wind due to the load.

Korean Patent No. 10-1670346 (a photovoltaic power generation device for a flat roof) discloses a structure in which an upper frame for supporting a solar cell panel and a lower frame for supporting a frame are assembled and the inclination of the panel is fixed. However, this method has a problem that the inclination can not be arbitrarily adjusted after installation.

Korean Patent Registration No. 10-0887723 (Fixed Structure for Photovoltaic Panel) is registered as a patent for a waterborne structure that installs a solar collecting panel on a river or a lake. However, There is a problem that the power generation unit price is twice or more.

In 1954, Bell Laboratories recorded a 4% efficiency with silicon (Si) solar cells. However, the purity of the material was improved and the manufacturing process was improved. Now, the efficiency of the mass production cells has improved to around 15%. However, It is possible to improve the mass production efficiency by more than 22% and lower the manufacturing cost by less than 1/3 of the silicon solar cell.

Therefore, it is predicted that the grid parity will reach 2018, when the cost of solar power generation required to produce 1 KW of electricity and the cost of production of generic power produced using fossil fuel become equal.

Nuclear power generation in the world is vulnerable to earthquakes and tsunamis, and when nuclear bombs are bombed by exhibits, it causes damage on the scale of an atomic bomb. Therefore, Israel does not install nuclear power plants originally, and in countries where there is war or terrorism The tendency to avoid nuclear power plants is increasing.

In addition, coal-fired thermal power plants are closing their power plants due to pollution. Therefore, it is necessary to develop an innovative solar power generation technology that can replace nuclear power plants or thermal power generation and a revolutionary system that can reduce power generation costs.

In the present invention, the term "solar cell panel" refers to a solar power generation array that combines modules, which are minimum units of a solar cell or a photovoltaic module, to produce actual electricity, A power generation panel or a solar cell panel.

Conventional solar cell panels have a problem of increasing power generation cost due to high land price when installed on flat ground, and it has been difficult to construct a large scale photovoltaic power generation facility in the city due to the rejection of panel reflection waves.

Due to the above problems, some countries have been experimenting with building solar power facilities on floors and roads.

It is an object of the present invention to provide an effective and economical method and system for constructing a large scale solar cell panel complex for photovoltaic generation in an abandoned mountain slope to solve the above problems and reduce the solar power generation cost, The goal is to provide a large-scale solar power generation facility that can replace the system technology.

In order to achieve the above object, according to the present invention, a plurality of rails are installed stepwise between the upper part and the lower part of a mountain in accordance with the topography of a mountainous area in order to construct a large number of solar power generation panels without obstructing the topography structure of the mountainous slopes, A solar cell panel for a plurality of solar power generation is installed in the longitudinal direction between the rails and a connecting means capable of adjusting the length between the quadrangular corners of each panel and the rails is constituted so that the inclination degree of each panel can be varied And a slope of the slope is arbitrarily changed in a 360 degree direction, and a system device thereof.

Thus, it is possible to increase the power generation efficiency, to secure the panel to withstand the strong wind by joining the panel at the corner, to establish a path between the upper rail and the lower rail installed in the mountain vent, In a detachable manner to slide on the frame of the panel, thereby providing a solution for semi-permanently improving the lifetime of the photovoltaic generation system by replacing the panel.

In addition, the application system using the above system technology provides an economical and effective way to construct a photovoltaic power generation system on the rooftops, roofs, electric poles, street lamps and wind power generation facilities of building exterior walls and buildings.

The step-by-step solar cell system construction technology of the present invention provides an economical and effective solution for mounting a large number of solar cell panels regardless of the inclination of the mountain slope, thereby enabling the formation of a large scale solar cell panel complex in a cheap mountain region .

Since the four-axis of the solar cell panel is coupled to the rail at the slope, the slope of the panel after the installation can be changed in a 360-degree direction while being safe to strong winds as compared with the conventional rotary- It has an effect of maintaining the optimum power generation efficiency

The present invention provides a system technology for constructing a large number of photovoltaic power generating panels in a stepwise manner at an inexpensive mountain slope and thus has the effect of enabling the construction of a solar power generation plant that replaces a nuclear power plant or a thermal power plant by constructing a large- .

The present invention has the effect of remarkably reducing the power generation cost by constructing the system of the present invention in an inexpensive mountainous wallpaper that does not cause civil complaints due to urban beauty or reflection waves compared with the urban lower plain.

The present invention provides an economical and effective solution for constructing an additional solar power generation facility on the outer wall of a building, a roof of a building, a roof of a house, a pole, a street lamp or a tower of a wind power generation facility, It has the effect of reducing the burden of relying on power generation.

Particularly, the present invention has an effect of installing solar cell panels on a wind power tower and providing effective system technology for varying the degree of inclination and tilt, thereby increasing the efficiency of wind power generation facilities by adding solar power to wind power generation

1 is a system configuration diagram of the present invention.
2 is a frame configuration diagram of a solar cell module panel of the present invention.
FIG. 3 is a block diagram of the connecting means of the present invention.
4 is a configuration diagram of a bolt-nut fastening frame according to the present invention.
5 is a diagram illustrating an example of the system installation of the present invention.
6 is a system side view of the present invention.
Figure 6a is a system coupled perspective view of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a system configuration diagram of the present invention, and FIG.

As shown in the above drawing, the system of the present invention short-circuits the rail at regular intervals according to the topography of the sloping slope along the sloping slope, fixes the short-circuited bottom to the ground, and forms an anchor bolt between the sloped rocks or the structure. A plurality of stepped rails 11 bound by a rock bolt or a soil nailing and a plurality of frames 10 mounted on a solar cell panel longitudinally installed along the plurality of rails Connecting means (12) for binding the upper side and lower side quadrangular corners of the frame and the rails and varying the length between the frame and the rail to vary the inclination of the frame or varying the inclination of the inclined face in the 360 degree direction, .

The inclination degree of each frame can be arbitrarily adjusted by the connecting means by connecting the bolts and nuts between the left and right sides of the frame of the solar cell panel and the rail and by connecting means capable of adjusting the length between the right and left sides of the frame and the rail.

In addition, the connecting means for controlling the length of the rails by electric or hydraulic type is provided on the left and right side of the frame and the lower side of the frame, and the inclination and inclination of the frame can be changed to 360 degrees by adjusting the length of each connecting means by remote control can do.

2 and 4 are frame diagrams for a solar cell panel mount of the present invention.

As shown in the drawing, the frame device for mounting the solar cell panel in the present invention comprises a panel mount portion 22 for fixing and fixing a solar cell panel for solar power generation, a frame connection portion 15, 15a), and connecting means (12) varying in length so as to vary the interval between the frame connecting portion and the panel mounting stand, wherein the length of each connecting means is variable to vary the inclination of the panel, Direction.

When the panel mounting portion 22 is shaped like a frame and the frame fixing portion 23 is formed on one side of the frame, maintenance of the solar cell panel 10 can be easily performed by installing or replacing the solar cell panel 10, The life span of the solar power generation system of the present invention is semi-permanently extended.

As described above, by configuring the connecting means 12 capable of adjusting the length at the quadrangular corner portion of the frame, the height of the quadrangular corner can be selectively changed to vary the inclination of the solar cell panel, or the inclination of the inclined surface can be varied In particular, there is an effect of providing a solar power generation system that is safe to strong winds by joining quadrangular corners of the frame to a rail or a frame rest.

In the above configuration, when the frame is large, a separate reinforcement or support can be additionally provided between the lower connection portions of the frame to support the load of the solar cell panel, and a separate connection portion Or the frame for mounting the panel according to the size or load of the solar cell panel can be configured as a prefabricated structure.

In the present invention, the rails may be selected from T-shaped, L-shaped, H-shaped, □ -shaped or shaped steel, and the lower end of the rail is fixed to the ground. Anchor bolts or rock bolts Soil Nailing provides a safe system for high loads and harsh stormy winds of panels and power generation aids by bonding them to a volcanic rock or installation aids.

In particular, the existing system installed on the ground is vulnerable to earthquake and strong wind by supporting the load of the heavy solar cell panel only by the strut, but the system of the present invention is advantageous in that the load of the solar cell panel is lower than the load axis of the lower side of the rail and the anchor bolt It is dispersed by the side bolts connected with rock bolts or soilless nails, and is safe for strong winds and earthquakes. It is easy to replace the solar cell panels and can be a semi-permanent solar power generation system.

When a number of longitudinal rails are joined to a plurality of longitudinal rails in a lattice-like structure to fix the bottom of a number of rails to the ground, and the ground rail is joined to an inclined rock bed or ancillary equipment with an anchor bolt, rock bolt or soil nailing A plurality of rails are arranged in a lattice structure to distribute loads, thereby providing a more secure panel mounting system.

In addition, since the rail is installed on the slope of the mountain slope, the solar cell panel mounted on the rail is stepped so that it does not obstruct the field of view, so that the solar light collecting efficiency is excellent and a plurality of panels can be efficiently installed in a narrow area.

When the system of the present invention is installed on an outer wall, a roof, or a roof of a building, a plurality of rails for mounting a plurality of solar cell panel frames with detachable bolt nuts are installed on a wall, roof, or roof, A plurality of solar cell panel frames are provided between the four corners of the frame and the rails, and variable length connecting means is formed between the four corners of the frames, thereby changing the inclination of the frame by varying the length of each connecting means, 360 degrees.

In the above system, a bolt nut is used between the left and right sides of the panel of the solar cell panel and the rail, and a connecting means capable of adjusting the length between the right and left sides of the lower side of the frame and the rail is constituted so that the inclination degree of each frame can be arbitrarily adjusted have.

Further, when the connecting means is configured to adjust the length with the rail by electric or hydraulic type, remote control can be used to vary the length of each connecting means of the quadrangular corner portion to vary the inclination of the frame or to change the inclination to 360 degrees can do.

As described above, since the system of the present invention is in close contact with the roof or the roof of the building, the height of the solar cell panel is low and the aesthetic effect is not hurt.

When the system of the present invention is installed on a flat surface, a plurality of rails are installed longitudinally or horizontally on a flat ground surface or a separate stand, and a rail is provided on upper and lower quadrangular corners of a plurality of frames, A connecting means for adjusting the length between the frame and the rail may be connected to each other so that the inclination of each frame can be varied by adjusting the length of the connecting means at each corner or the slope of the slope can be varied 360 degrees for each frame.

It is possible to construct a connecting means which can be adjusted by a bolt nut between the left and right side of the frame of the solar cell panel and the frame cradle and to adjust the length between the left and right side of the frame and the frame cradle. It is possible.

Specifically, in the present invention, a frame device for mounting a solar cell panel includes a panel mounting portion 22 for fixing and fixing a solar cell panel for solar power generation, frame connecting portions 15, 15a and a connecting unit 12 that varies in length so as to vary the interval between the frame connecting unit and the panel mount. Thus, the length of each connecting unit can be varied to vary the inclination of the panel, So that the inclination of the frame is arbitrarily adjusted.

 Particularly, it is possible to provide a photovoltaic power generation system that is safe for strong winds by joining quadrangular corners of the frame to a rail or a frame rest.

According to the present invention, if a universal joint is added to the joining portion of the connecting means of the frame, the inclination of the frame can be changed by a bolt nut of a long axis, a hydraulic type or an electric type.

According to the present invention, when the connecting means is constituted by a hydraulic type or an electric type and an electric rotating device is additionally provided in the cradle, a computer program can provide a useful technique for remotely controlling the direction and inclination angle of the solar cell panel.

When the solar cell panel system of the present invention is used, a photovoltaic power generation facility can be constructed by using a pole, a streetlight, a security lamp, or a tower of a wind power generation facility.

The conventional column-type solar cell panel device has a problem that the size of the panel is limited due to the installation of the panel on the upper part of the support, and the number of the panels that can be installed is limited due to its vulnerability to strong winds.

In the system of the present invention, first, four connecting portions are connected to the rails at the left, right, bottom, and bottom portions of the rear of the frame for mounting the solar cell panel. The light rail, which is connected to a pole, a streetlight, And a plurality of connection portions are formed from the top to the bottom by a punch connected to the connection portion of the frame.

In order to reduce the burden on the support by the rail and the solar cell panel, the rail bottom is connected to the ground and the upper part of the rail is connected to the steel bend or anchor The same effect can be obtained even if the rail is constituted by an aluminum chassis in which two L-shaped connecting shafts are integrally formed.

The upper left and right connection parts on the back of the solar cell frame, the connection part and the bolt nut fastened to the two light rail are fastened to each other, and the connecting parts formed on the lower left and right sides of the frame back are connected to the lower connecting part of the upper two light rail and bolt nut The inclination degree of the solar cell panel can be arbitrarily varied by varying the length of the connecting means, thereby making it possible to constitute a photovoltaic power generation system that achieves an optimum light collecting effect.

In order to increase the generation capacity of the wind power generation plant in the above system, a trapezoidal connection of at least three light rail is required in the southeast direction of the support, and a frame for installing a plurality of solar cell panels is installed between the rails In this case, when the lengthwise connecting means is formed on the upper left and right connecting means of each frame back, variable length connecting means are formed at the four corners of the frame, so that the lengths of the four connecting means can be varied to vary the inclination of the frame, 360 degrees, and it has the effect of greatly increasing the power generation capacity by adding solar power to the existing wind power generation.

Because the tower of the wind turbine is composed of a large cylindrical steel plate, it is possible to construct a cradle that mounts a solar cell panel with welding or bolt nuts on an iron plate instead of a rail and connects the cog corner of the frame with the connecting means. Can be obtained.

If the charging means and the light sensor means are added to the street lamp or the security lamp where the above system device is built, it becomes a street light or a security light that is automatically blinked by the self-charged battery without supplying the external power. Provide security measures.

As described above, the present invention can be applied not only to various applications, but also to provide an effective method of constructing a large number of solar cell panel complexes on an abandoned sloped slope, and it is possible to secure the panel slope It is possible to provide a system in which the slope of the slope is variable and the slope of the slope can be arbitrarily changed in the direction of 360 degrees and the solar cell panel can be optionally replaced by the sliding method, To provide a system technology capable of constructing a large-scale photovoltaic power generation system that can replace the conventional solar power generation system.

Therefore, the present invention can be utilized in various other forms without departing from the technical idea and the main features of the present invention, and thus all modifications and changes belonging to the equivalent scope of the claims of the present invention belong to the scope of the present invention.

The present invention can economically construct a large-scale photovoltaic power generation facility in a low-cost mountain volcanic wallpap, which can be used in a solar power plant construction industry that can replace nuclear power plants or thermal power plants in the future.

According to the present invention, it is possible to provide an economical solution for constructing a photovoltaic power generation facility on the outer wall of a building, a roof, or a roof, so that it can be used in the photovoltaic industry for companies and households.

The present invention provides a technique for constructing a photovoltaic power generation facility in a wind power generation pillar, so that it can be used in the wind power generation industry by dramatically improving power generation capacity by adding solar power to wind power generation.

According to the present invention, since sufficient electric power is stored in the own cell device without supplying external power to the street light or security light, it can be used for the industry that constructs the street light or the security light in the mountainous wallpaper road network without the electricity supply facility.

10; A solar cell panel 11; rail
12; Connecting means 13 / 13a; Frame connection ball
14; Rail stair connection 15 / 15a; Frame connection portion
16; Bolt nut coupling hole 17; Rail and Frame Combination Ball
18; Anchor bolt for rail mounting bolt hole 19; Connecting means
20; A solar cell module 22; The solar cell panel mounting part
23; A solar cell panel fixing section 24; Frame connection of rail
25; Anchor bolt joint of rail

Claims (24)

A method of constructing a solar cell panel for solar power generation on a sloping slope,
(1) a step of forming a connection part with a solar cell panel mounting frame on a plurality of rails short-circuited by a specific length according to a mountain slope inclined topography and installing rails in a stepwise manner between the upper and lower parts of the mountain,
(2) constituting a connecting portion with the rail at the quadrangular corner portion of the frame that mounts the solar cell panel,
(3) A plurality of solar cell panel frames are installed along the plurality of stepwise rails, and variable length connecting means is formed between the connecting portions of the frames and the rails, so that the lengths of the connecting means are variable, The slope of the slope of the solar cell panel and the slope of the slope of the slope of the slope of the solar cell panel are arbitrarily varied on a frame-by-frame basis, How to build The method according to claim 1,
A connecting means for adjusting the length between the left and right sides of the frame and the rails is constituted so that the length of the connecting means is variable and the inclination of each frame is divided by frame A method for constructing a solar power generation panel system of a mountain slope inclined by arbitrary adjustment The method according to claim 1 or 2,
Wherein the connecting means of the frame is selectively constructed of an electric type or a hydraulic type so that the length of each connecting means is remotely controlled to change the inclination of each frame. The method according to claim 1 or 2,
It is characterized by a structure in which a plurality of transverse rails are joined to a plurality of longitudinal rails in a lattice-like structure, the floor is fixed to the ground, and the ground rail is joined by an inclined rock mass or an installation auxiliary device with an anchor bolt, rock bolt or soil nailing How to build solar power generation panel system on sloping slope A method of constructing a solar cell panel for photovoltaic power generation on a building exterior wall, roof, or roof,
A method of manufacturing a solar cell panel, comprising: attaching a plurality of rails constituting a connecting portion for mounting a solar cell panel to a building outer wall, a roof, or a roof of a roof; constructing a rail connection portion at a quadrangular corner portion of a frame that mounts the solar cell panel; A frame of a solar cell panel is installed between a connecting portion of the plurality of rails and a frame connecting portion, and variable length connecting means is provided between the quadrangular corners of each frame and the rails so that the inclination degree of each frame is varied Or a method of varying the inclination of the inclined plane in the direction of 360 degrees The method of claim 5,
A connecting means for adjusting the length between the rails and the frame is formed on the left and right sides of the remaining one side of the frame with bolt nuts so as to arbitrarily adjust the inclination of each frame by adjusting the length of the connecting means A method for constructing a solar power generation panel system A system for installing a solar cell panel for solar power generation,
(1) a plurality of rails constituting a plurality of connection portions for connection of a solar cell panel mounting frame,
(2) a frame constituting a connecting portion with a rail at a quadrangular corner portion of the frame which mounts the panel of the solar cell module,
(3) a variable length connecting means for connecting the connecting portion of the rail and the connecting portion of the frame, and varying the distance between the rail and the frame,
Wherein a plurality of solar cell panel frames are installed along the rails so that the length of the frame between the quadrilateral connection portion and the rail connection portion is variable to vary the inclination of the frame or the inclination angle of the inclined surface to 360 degrees. Photovoltaic panel system equipment The method of claim 7,
A connecting means for connecting the left and right sides of the frame with the bolt nuts between the left and right sides of one side of the frame of the solar cell panel and the inside of the rail so as to adjust the length between the left and right sides of the frame and the rails, Photovoltaic panel system equipment The method according to claim 7 or 8,
Wherein the connecting means is of an electric type or a hydraulic type and the length of the connecting means is remotely controlled to vary the inclination of the frame. The method according to claim 7 or 8,
And the solar cell panel is integrally formed in the frame. 1. A frame apparatus for mounting a solar cell panel for solar power generation,
A frame attaching / detaching means for attaching and fixing the solar cell panel to the frame, a frame connecting portion formed at the corner portion of the frame, and a length variable connecting means for changing the distance between the frame connecting portion and the panel placing table. And the slope of the inclined surface is varied in the direction of 360 degrees. 2. The solar cell panel frame system according to claim 1, The method of claim 11,
A connecting means is provided between the left and right sides of the frame of the solar cell panel and the frame rest with a rotation rod or a bolt nut to adjust the length between the left and right sides of the frame and the frame rest so that the inclination of each frame can be arbitrarily adjusted And the frame system unit of the solar cell panel 12. The method according to claim 11 or 12,
Wherein the connecting means is configured to be electromechanical or hydraulic so that the degree of inclination of the frame can be varied by controlling the length of the connecting means by remote control. 12. The method according to claim 11 or 12,
Wherein the cell-cell panel mounting portion and the panel connecting portion of the frame are detachably mounted, and a frame reinforcing agent, a subsidiary connecting portion, or a frame supporting portion is additionally provided between the four panel connecting portions of the frame lower portion. 12. The method according to claim 11 or 12,
Wherein a frame for mounting the solar cell panel is constructed as a prefabricated structure and a separate frame connection portion is additionally formed between each connection portion of the quadrangular corner portion. 12. The method according to claim 11 or 12,
Wherein a panel mount portion of a frame that mounts the solar cell panel is formed in a U-shape and is detachably attached to the panel by sliding the panel. CLAIMS 1. A device for varying the inclination of a solar cell panel for solar power generation,
A connecting means capable of varying the length between the corner portions of the frame of the solar cell panel and the frame cradle is constituted so that the inclination degree of each frame can be arbitrarily changed or the inclination of the frame can be varied in the 360 degree direction by varying the length of the connecting means Solar cell panel tilt adjustment 18. The method of claim 17,
A connecting means is provided between the left and right sides of the frame of the solar cell panel and the frame rest with a rotation rod or a bolt nut so that the length between the left and right sides of the frame and the frame rest can be adjusted. Wherein the solar cell panel tilt adjusting device 18. The method of claim 17 or 18,
And a universal joint is attached to a joining portion of the connecting means of the frame. 18. The method of claim 17 or 18,
And a rotatable device is additionally provided on the frame rest so that the inclination and the direction of the frame can be selectively changed. 18. The method of claim 17 or 18,
Wherein the connecting means is configured to be electromechanical or hydraulic so as to remotely control the length of the connecting means. A system for installing a solar cell panel for photovoltaic power generation using a pole, a streetlight, a security lamp, or a tower of a wind power generation facility,
(1) Two or more lightweight rails joined together in a trapezoidal fashion along the south side or the southeast and west side of a strut selected from a pole, a streetlight or a pillar of a wind power generation plant and constituting a frame connection part for mounting a solar cell panel,
(2) a frame constituting a connecting portion with the rail on the left, right and lower right and left sides of the rear surface of the frame for mounting the solar cell panel,
(3) A plurality of frames are successively installed in the longitudinal direction with respect to the light rail, and bolts are fastened between the upper left and right connection portions and the rail connection portions of the rear sides of the frames, And the slope of each frame is arbitrarily varied by varying the length of the connecting means. 23. The method of claim 22,
Wherein a variable length connecting means is additionally provided on the upper left and right sides of the rear face of the frame so as to vary the inclination of each frame by four connecting means and vary the inclination of the inclined face in the 360 degree direction. 23. The method according to claim 22 or 23,
Characterized in that a charging means and an optical sensor means are additionally provided in a column of a streetlight or a security lamp in which the system device is installed, and the self-charging battery is automatically turned on and off without external power supply.

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