KR102009941B1 - 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 panels on a hill slope, and more particularly, a plurality of rails which are connected to a hill slope on a slope and short-circuited at regular intervals according to the terrain, are cascaded. By connecting the frame of a number of solar panels, and forming a variable length connecting means between the four corners of each frame and the rail, even after the system construction, the angle of the panel is changed by the variable length of the connecting means, and the tilt is randomly set in the 360 degree direction. It provides a system that maintains the optimal photovoltaic efficiency by varying.
As a result, the four axes of the solar cell panels are bound together, which is safe for strong winds, and the maintenance of the panels is simple due to the structure of the frame that slides on and off the panel, and the life of the solar power generation system can be semi-permanently improved by replacing the panels. In addition, it is possible to significantly reduce the cost of photovoltaic power generation with a stepped system technology that can create large-scale photovoltaic panel complexes using mountain areas, thus providing eco-friendly photovoltaic power plant construction system technology that replaces nuclear power plants or thermal power generation in the future.

Description

Method & system apparatus for installing solar cell panel on mountain slope.

The present invention relates to a method and a system device for installing a solar panel for photovoltaic power generation on a hill slope, and more particularly, as a conventional method for installing a solar cell panel on a flat slope cannot be installed on a steep slope. Regardless of the structure and angle of inclination, the solar panel is secured in strong winds by binding the solar panels on 4 axes, and after installation, the panel's inclination can be arbitrarily changed and the panel's inclination can be changed in the 360 degree direction. Application system device.

Conventional solar panel installation method is to install a panel consisting of a plurality of solar cell module on the ground cradle and to install the solar panel by adjusting the inclination of the panel in advance or remote control. Due to its weight and height, it is vulnerable to typhoons and strong winds, and a large area of land is required because of the separation distance to avoid shade between panels.

In addition, the existing flat installation method has a problem that the solar panel is easily collapsed and collapsed due to the strong winds of the mountain slope when installed on a steep mountain slope, and the maintenance is difficult because of the mountain slope.

In addition, there is a problem of increasing solar power production cost due to the high land purchasing cost when installing solar panels for solar power generation on flat lands. Therefore, an effective method of installing a large amount of solar panels in a low land price is required. .

The existing solar panel installation system is composed of a fixed type that is installed by fixing the reflection angle of the panel with a prefabricated holder and a variable type that arbitrarily adjusts the inclination of the panel between the holder and the panel.

In Korea Patent No. 10-1108713 (solar power generation device with easy tilt angle adjustment), a device is used to connect the cradle and the solar panel with the hinge axis and to change the inclination on the hinge axis. Due to the load, there is a problem in that the panel falls due to strong wind and the panel is broken.

Korean Patent Registration No. 10-1670346 (solar folding photovoltaic device for installing roofs) discloses a configuration in which an upper frame for supporting a solar panel and a lower frame for supporting a frame are prefabricated and installed by fixing the inclination of the panel. However, this method has a problem that can not be adjusted arbitrarily after installation.

Korean Patent Registration No. 10-0887723 (Patent for Water Structure of Solar Collecting Panel) has been registered for a water-based structure for installing a solar collector panel in a river or lake, but the existing thermal power generation is still high due to the high cost of the facility. Compared with the power generation cost, there is a problem that is more than twice.

In 1954, Bell Labs recorded 4% efficiency with silicon (Si) solar cells, but the efficiency of mass production cells has now improved to around 15% by increasing the purity of materials and improving manufacturing process technology. Called metal oxide improves mass production efficiency by more than 22% and reduces manufacturing costs to less than one third of silicon solar cells.

Hence, we expect 2018 to reach Grid Parity, where the cost of photovoltaic power needed to produce 1 kW of electricity will be the same as the cost of electricity generated from fossil fuels.

In many countries around the world, nuclear fission nuclear power is vulnerable to earthquakes and tsunamis, and bombs in wartime cause nuclear bomb damage. The tendency to evade nuclear power plants is increasing.

In addition, coal-fired thermal power plants are shutting down power generation facilities due to pollution, so it is necessary to develop industrial photovoltaic technologies and power generation systems that can replace nuclear power plants or thermal power plants in the future.

In the present invention, the term "solar-cell panel" refers to a photovoltaic array that combines modules that are the smallest units of solar cells (Solar-Cell or Photovoltaic) to produce actual electricity. It is called power generation panel or solar panel.

Existing solar panels have a problem of increasing power generation costs due to high land prices when installed on flat land, and there is a difficulty in building a large-scale solar power generation facilities in the city due to the rejection of panel reflection waves.

Due to the above problems, some countries continue to experiment with building photovoltaic facilities on salt floors or road surfaces.

The present invention provides an effective and economical method and system device for constructing a large-scale solar panel complex for photovoltaic power generation on abandoned mountain slopes to solve the above problems and reduce the cost of photovoltaic power generation. It is an object to provide system technology for building large-scale photovoltaic facilities that can be replaced.

In order to achieve the above object, the present invention provides a stepless installation of a plurality of rails between the top and bottom of the mountain in accordance with the topography of the mountain slope in order to construct a large amount of solar power panels without obstacles to the topographical structure of the mountain slope. Solar panels for multiple solar power generations are installed in the longitudinal direction between the rails, and the connecting means which can be adjusted in length between the four corners of each panel and the rails are configured to vary the inclination of each panel by varying the length of each connecting means. And it provides a photovoltaic panel installation method and a system device that arbitrarily variable inclination of the inclined surface in a 360 degree direction.

This increases the power generation efficiency and is strong enough to endure strong winds by joining panels at the four corners, and by establishing a passage between the upper rail and the lower rail installed on the mountain slope, it is easy to access and maintain the solar panels. It is easy to replace the panel by constructing in a removable way sliding to the frame of the panel provides a solution that semi-permanently improve the life of the photovoltaic power generation system by replacing the panel.

In addition, as an application system using the above system technology, it provides an economical and effective way to build a photovoltaic power generation system on the exterior wall of a building, on the roof of a building, on a roof, a pole, a street lamp, or a pillar of a wind power plant.

The stepped solar cell system construction technology of the present invention provides an economical and effective solution for mounting a large number of solar panels on a mountain slope regardless of the slope of the mountain, thereby enabling the construction of a large scale solar panel complex in an inexpensive mountain area. .

The present invention is a structure that binds the four axes of the solar cell panel to the rail in the slope, and compared to the rotating shaft method for adjusting the inclination, safer to strong winds, the angle of the panel can be changed after installation and the inclination can be changed in a 360 degree direction. It is effective to maintain optimal power generation efficiency

The present invention provides a system technology for constructing a large amount of solar power panels in a stepped manner on an inexpensive mountain slope, thereby creating a large-scale photovoltaic panel complex, enabling the construction of a solar power plant that replaces a nuclear power plant or a thermal power plant. .

The present invention has the effect of significantly reducing the power generation cost by constructing the system of the present invention on an inexpensive mountain wall where civil complaints due to urban aesthetics or reflected waves do not occur as compared to the suburban plains.

The present invention provides an economical and effective solution for additionally constructing photovoltaic facilities on the exterior walls of buildings, rooftops, roofs of houses, poles, street lights, or props of wind power generation facilities, and expands photovoltaic power generation and thermal power plants. This reduces the burden on development.

In particular, the present invention has the effect of greatly improving the efficiency of the wind power plant by adding solar power to the wind power generation by providing an effective system technology for installing the solar panel on the wind turbine and variable inclination and inclination.

1 is a system configuration diagram of the present invention.
2 is a frame diagram illustrating a solar cell panel of the present invention.
Figure 3 is a block diagram of the connection means of the present invention.
Figure 4 is a block diagram of a bolt nut fastening frame of the present invention.
5 is an exemplary diagram of a system installation of the present invention.
Figure 6 is a system top view of the present invention.
Figure 6a is a perspective view of the system combination of the present invention.

It will be described in detail by the accompanying drawings of the present invention.

Figure 1 is a system configuration of the present invention, Figure 5 is an example of a mountain slope installation.

As shown in the above drawings, the system of the present invention is connected to the slope of the mountain slope and short-circuits the rail at regular intervals according to the terrain of the slope of the hill slope to fix the shorted lower portion to the ground, and anchor bolts between the rock slopes or the structures. Or a plurality of frames (10) for mounting a plurality of stepped rails (11) fastened by rock bolts or oil nailing and a solar cell panel installed in the longitudinal direction in connection with the plurality of rails (10). And connecting means 12 for binding the upper and lower four corners of the frame and the rail and varying the length between the frame and the rail to change the inclination of the frame or the inclination of the inclined surface in a 360 degree direction. It consists of.

When the connecting means which is fastened by bolt nuts between the upper and lower left and right sides of the frame of the solar panel and the rail and the length is adjustable between the lower left and right of the frame and the rail, the inclination of each frame can be arbitrarily adjusted by the connecting means.

In addition, by configuring the connecting means for adjusting the length of the rail by electric or hydraulic on the left and right sides of the frame and the left and right sides of the frame, the tilt and tilt of the frame can be changed in the 360 degree direction by adjusting the length of each connecting means by remote control. can do.

2 and 4 is a frame configuration for mounting the solar panel of the present invention.

As shown in the drawings, the frame device for mounting the solar cell panel according to the present invention includes a panel mounting portion 22 for fixing the solar cell panel for photovoltaic power generation, and a frame connection part configured at each corner of the frame ( 15, 15a) and a connecting means 12 for varying the length to arbitrarily vary the distance between the frame connecting portion and the panel holder, the variable inclination of the panel by the variable length of each connecting means or the inclination of the inclined surface 360 degrees It is configured to vary in the direction.

When the panel mounting portion 22 is configured in a shape and the frame fixing portion 23 is configured on one side of the frame, maintenance is easy by sliding installation or replacement of the solar panel 10 and the panel is replaced with the present invention. It has the effect of semi-permanently extending the life of the solar power system.

As described above, by configuring the connecting means 12, the length of the four corners of the frame is adjustable by selectively varying the height of the four corners to change the inclination of the solar panel or the inclination of the inclined surface in the 360 degree direction In particular, by bonding the four corners of the frame with the rail or frame holder is effective to provide a solar power system that is safe against strong winds.

In the above configuration, when the frame is large, a separate reinforcement or support may be added between each connection between the lower parts of the frame in order to support the load of the solar panel, and additional connection is optionally configured between the four connection parts. In addition, according to the size or load of the solar panel, the frame for mounting the panel can be configured as a prefabricated structure.

In the present invention, the rail is selected from T-shaped steel, L-shaped steel, H-shaped steel or □ -shaped steel or ∪-shaped steel to fix the lower end of the rail to the ground and between the anchor bolt (Rock Bolt) or the upper end and the lower end of the rail or Bonding to hillside rock or installation aids with Soil Nailing provides a safe system for high loads or hillside winds on panels and power generation aids themselves.

In particular, the conventional method of installing on the ground is susceptible to earthquakes and strong winds by supporting the load of the heavy solar panel only with the support, but the system of the present invention is that the load of the solar cell panel is not limited to the ground shaft of the rail and the anchor bolt. It is distributed on the side slopes of rock slopes or soil nailing, which is secured against strong winds and earthquakes, and can be easily replaced by solar panels, making it a semi-permanent photovoltaic system.

By joining a plurality of transverse rails in a lattice structure to a plurality of longitudinal rails to fix the bottom of the multiple rails to the ground, and joining the ground rails to an inclined rock or installation aid with anchor bolts, rock bolts or soil nailing. Multiple rails are grid-structured to distribute the load, providing a safer panel mounting system.

In addition, since the rail is installed on the slope of the slope, the solar panels mounted on the rail are cascaded to cover the field of vision so that the solar light collecting efficiency is excellent and multiple panels can be efficiently installed in a small area.

When the system of the present invention is installed on the outer wall or roof or roof of the building, a plurality of rails for mounting the frame of the plurality of solar panel panels with a removable bolt nut are installed on the wall or roof or the face of the roof, and between the plurality of rails. Frames of a plurality of solar panels are installed between the frame, and the variable length connecting means is configured between the four corners of the frame and the rail to change the inclination of the frame or the inclination of the inclined surface for each frame. It is configured to be variable in the 360 degree direction.

In the above system, the bolts can be fastened between the upper and lower left and right sides of the frame of the solar panel and the rails, and the connecting means can be configured to adjust the inclination of each frame by the connecting means. have.

In addition, if the connecting means is configured to adjust the length with the rail by electric or hydraulic by constructing a system to change the inclination of the frame or change the inclination in the 360 degree direction by varying the length of each connecting means of the four corners by remote control can do.

As described above, the system of the present invention has a structure in close contact with the roof of the building or the surface of the roof, so that the height of the solar cell panel is low, thereby not damaging the aesthetics.

When the system of the present invention is installed on a flat surface, a plurality of rails are installed in a longitudinal direction or a transverse direction on a flat surface or a separate mount, and the rails are formed in four corners of the upper and lower left and right sides of the plurality of frames on which the solar panels are mounted. By connecting the frame and the rail to adjust the length of the connection means can be configured to vary the inclination of each frame by adjusting the length of the connecting means of each corner or to configure the inclination of the inclined surface in the 360 degree direction for each frame.

Tighten bolt bolts between the upper and lower left and right frames and the frame holder of the solar panel and configure the adjustable means between the left and right sides of the frame and the frame holder to adjust the inclination of each frame by adjusting the length of the connecting means. It may be.

Specifically, in the present invention, the frame device for mounting the solar cell panel includes a panel mounting part 22 for fixing the solar cell panel for photovoltaic power generation and a frame connecting part 15 configured at each corner of the frame. 15a) and the connecting means 12 varying in length to arbitrarily vary the distance between the frame connecting portion and the panel holder, so that the inclination of the panel can be varied or the inclination of the inclined surface in the 360 degree direction by varying the length of each connecting means. By varying the configuration, the inclination of the frame is arbitrarily adjusted.

 In particular, by bonding the four corners of the frame with the rail or frame holder is effective to provide a solar power system that is safe against strong winds.

In the present invention, if the universal joint (Universal Joint) is additionally configured to the joint connecting means of the frame can be converted to the tilt of the frame by the bolt nut of the long axis or hydraulic or electric, and if necessary, a rotating device can be added to the lower part of the frame.

In the present invention, when the connecting means is configured hydraulically or electrically and the electric rotating device is additionally configured to the cradle, the computer program provides a useful technique for remotely controlling the direction and the inclination angle of the solar cell panel.

Using the solar cell panel system of the present invention, it is possible to build a solar power generation facility using poles, street lights, security lamps, or props of wind power generation facilities.

The existing column-mounted solar panel device has a problem in that the number of panels that can be installed due to the limited size of the panel and vulnerable to strong winds by installing the panel on the upper end of the column.

According to the system of the present invention, first, four connection parts are connected to the rails on the upper left and right and lower left and right sides of the frame mounting the solar panel. Perforations to connect with the connection of the frame constitutes a plurality of connections from the top to the bottom.

The two light rails configured as above are connected to the south side of the support and are long-bound in a trapezoidal shape.To reduce the burden on the support of the rail and the solar panel, connect the bottom of the rail to the ground and the steel bend or anchor on the upper rail. The bolt can be used to bind with the prop, and the same effect can be obtained even if the rail is composed of an aluminum chassis in which two L-shaped connecting shafts are integrally formed.

Fasten the bolts and the bolts on the left and right sides of the solar cell frame and the light rails on the two lightweight rails. By connecting, the inclination of the solar cell panel can be arbitrarily changed by varying the length of the connecting means, thereby making it possible to construct a photovoltaic system that achieves an optimal condensing effect.

In the above system, if you want to increase the power generation capacity by constructing on the prop of wind power plant, at least 3 lightweight rails should be trapezoidally bound in the southwest direction of the prop and install the frame for mounting multiple solar panels between rails. In this case, if the variable length connecting means is formed in the upper left and right connecting means on the back of each frame, the variable length connecting means is configured at all four corners of the frame, so the inclination of the frame can be varied or the slope of the inclined surface can be changed by the variable length of the four connecting means. It can be configured to vary in the 360-degree direction, and there is an effect to increase the power generation capacity by adding solar power to the existing wind power generation.

Since the pillar of the wind power plant consists of a large cylindrical steel plate, it is possible to construct a cradle for mounting the solar panel by welding or bolt nut on the steel plate instead of the rail, and to connect it by the four corners of the frame and the connecting means. You can get it.

When the charging means and the light sensor means are additionally configured on the street lamp or the pillar of the security lamp where the above system device is constructed, it is a street lamp or a security lamp that automatically flashes with a self-charged battery without an external power supply, which is useful for a mountain wall road network without electric equipment. Provide security measures.

As described above, the present invention is not only applicable to a variety of applications, but also provides an effective method for constructing a large number of solar panel complexes on an abandoned hill slope, and binds the solar panels in four axes to secure the slope of the panel while being strong in strong winds. In addition to providing a variable and randomly inclined surface in a 360-degree direction, the solar panel can be replaced by a sliding method, which can semi-permanently improve the life of the photovoltaic power generation system. To provide a system technology to build a large-scale photovoltaic power generation system that can replace the.

Therefore, the present invention may be used in various other forms without departing from the technical spirit and main features of the present invention, and all modifications and changes belonging to the equivalent scope of the claims of the present invention are within the scope of the present invention.

In accordance with the present invention, it is possible to economically construct a large-scale photovoltaic power generation facility on a hillside wallpaper with low land prices, and thus may be used in the construction of a photovoltaic power plant that can replace nuclear power plants or thermal power plants in the future.

The present invention provides an economical solution for building photovoltaic facilities on the exterior walls, rooftops or roofs of buildings, and thus can be used in the enterprise and home photovoltaic industry.

The present invention provides a technology for building a photovoltaic power generation facility on a wind power prop, so it can be used in the wind power industry because it significantly improves the power generation capacity by adding photovoltaic power generation to wind power.

The present invention can be used in the industry to build a street lamp or security light on the mountain wall road network without electricity supply equipment because it automatically flashes by storing enough power in its own solar cell device without supplying external power to the street lamp or security light.

10; Cell panel 11; rail
12; Connecting means 13 / 13a; Frame connector
14; Rail stair connection 15 / 15a; Frame connection
16; Bolt nut coupling hole 17; Rail and Frame Joiner
18; Anchor bolt coupling hole for rail mounting 19; Connector
20; Cell module 22; Cell Panel Mount
23; Cell panel fixing 24; Frame connector on the rail
25; Anchor Bolt Coupling on Rail

Claims (24)

In a method of building a solar panel for photovoltaic power generation on a hill slope,
(1) forming a connection with a solar panel mounting frame on a plurality of rails shorted to a specific length according to the slope of the mountain slope and installing rails stepwise between the upper and lower parts of the mountain;
(2) constructing a connection portion with the rail at the four corners of the frame on which the solar panel is mounted;
(3) Install the frames of the plurality of solar panels connected to the plurality of stepped rails, but the variable length connecting means between the connecting portion of each frame and the connecting portion of the rail to form a variable slope of each frame by varying the length of each connecting means Mounting the frame which is variable or configured to vary the inclination of the inclined plane in a 360 degree direction, the solar panel panel system of the hill slope slope characterized in that the inclination of the solar panel and the inclination of the inclined plane arbitrarily vary by frame How to build The method according to claim 1,
In the frame mounting step, by connecting the bolt nut between one side of the left and right sides of the frame and the rail connecting portion and the length adjustment between the remaining one side of the frame and the rails of the frame by varying the length of the connecting means to change the inclination of each frame by frame Method for constructing photovoltaic panel system on mountain slope The method according to claim 1 or 2,
The method of constructing a photovoltaic panel system of a hill slope in which the frame connecting means is configured to be electrically or hydraulically configured to convert the inclination of each frame by remotely controlling the length adjustment of each connecting means. The method according to claim 1 or 2,
A plurality of transverse rails are joined to a plurality of longitudinal rails in a lattice structure to fix the floor to the ground, and the ground rails are joined to an inclined rock or installation aid with anchor bolts, rock bolts or soil nailing. Construction method of photovoltaic panel system on mountain slope In the method of building solar panels for photovoltaic power generation on the outer wall, roof or roof of a building,
Attaching a plurality of rails that constitute the frame mounting connection of the solar panel to an outer wall of the building or a face of a roof or a roof; forming a rail connection at each corner of the frame for mounting the solar panel; The frame of the solar panel is installed between the connecting portion and the frame connecting portion of the plurality of rails, the variable length of the connecting means by varying the length of each connecting means by configuring the variable length connecting means between the four corners of the frame and the rail Method for constructing a photovoltaic panel system comprising a method of changing the slope of an inclined surface The method according to claim 5,
It is configured to fasten the inclination of each frame by adjusting the length of the connecting means by configuring the connecting means which can adjust the length between the rail and the frame on the left and right sides of the frame with the bolt nut between the left and right sides of the frame and the rail connection part. Photovoltaic panel system building method characterized in that In the system device for installing the solar panel for solar power generation,
(1) a plurality of rails comprising a plurality of connections for connection of a frame mounted on a solar panel;
(2) a frame having a connection portion with a rail at a corner of a frame that mounts a panel of a solar cell module,
(3) a configuration including a variable length connecting means for connecting the connecting portion of the rail and the connecting portion of the frame and configured to vary the distance between the rail and the frame,
The frame of the plurality of solar cell panels connected to the rail is installed, and the inclination of the frame or the inclination of the inclined surface is varied in a 360 degree direction by varying the length between the quadrangular connecting portion and the rail connecting portion of each frame. Photovoltaic Panel System The method according to claim 7,
The connecting means which is fastened by bolt nuts between the left and right sides of the frame of the solar panel and the inside of the rail and the length adjustable between the left and right sides of the frame and the rail is configured to vary the inclination of each frame as the connecting means. Photovoltaic Panel System The method according to claim 7 or 8,
Photovoltaic panel system device, characterized in that configured to change the inclination of the frame by remotely controlling the length of each connecting means by configuring the connecting means by electric or hydraulic The method according to claim 7 or 8,
Photovoltaic panel system device, characterized in that the solar panel is integrally formed in the frame. In the frame device for mounting a solar panel for solar power generation,
Each connecting means comprises a frame detachable means for mounting and fixing the solar cell panel to the frame, a frame connecting part configured at the four corners of the frame, and a variable length connecting means for varying the distance between the frame connecting part and the panel holder. Frame system device of a solar panel, characterized in that the inclination of the panel to vary the length of the variable or the inclination of the inclined surface in a 360 degree direction The method according to claim 11,
Arrangement is possible by varying the inclination of each frame by adjusting the length of the connecting means by configuring the connecting means which can be fastened between the left and right sides of the solar panel frame and the frame holder with the rotating rod or bolt nut, and the length can be adjusted between the left and right sides of the frame and the frame holder. Frame system device of the solar panel, characterized in that The method according to claim 11 or 12,
The solar cell panel frame system device, characterized in that configured to change the inclination of the frame by adjusting the length of the connection means by the remote control by selectively configuring the connection means in the electric or hydraulic type The method according to claim 11 or 12,
The solar panel frame system device of claim 1, wherein the solar panel panel mounting portion or the panel connection portion of the frame is detachably configured, and a frame reinforcement, an auxiliary connection portion or a frame support is additionally configured between the four panel connection portions of the lower frame. The method according to claim 11 or 12,
The frame system device of the solar cell, characterized in that the frame for mounting the solar panel in a prefabricated structure, and additional frame connection is selectively configured between each connection between the four corners. The method according to claim 11 or 12,
Cell frame system device, characterized in that the panel mounting portion of the frame on which the solar panel is mounted in a U-shape to detachable by sliding the panel In the inclination variable device of the solar panel for solar power generation,
It is characterized by the configuration of the variable length of the connecting means by varying the length of the connection means by varying the length of the connection means by varying the length of the connection means between the four corners of the frame of the solar panel and the frame holder Cell Panel Tilt Adjuster The method according to claim 17,
One side left and right sides of the frame of the solar cell panel and the frame holder are fastened with a rotating rod or bolt nut, and a length adjustable between the left and right sides of the frame and the frame holder is configured. Cell panel tilt control device, characterized in that variable The method according to claim 17 or 18,
Cell panel inclination control device, characterized in that the universal joint (Additional Joint) is added to the connecting means joining of the frame The method according to claim 17 or 18,
Cell panel inclination adjustment device, characterized in that configured to selectively change the inclination and direction of the frame by additionally configured a rotating device to the frame holder The method according to claim 17 or 18,
Cell panel inclination control device, characterized in that it is configured to remotely control the length conversion of the connecting means by selectively configuring the connecting means in the electric or hydraulic In the system device that installs the solar panel for solar power generation using poles, street lights, security lamps or props of wind power generation facilities,
(1) two or more lightweight rails connected in a trapezoidal shape connected to the south or south-west side of a selected pole in poles, street lamps, or pillars of wind power generation facilities, and comprising a frame connection for mounting a solar panel;
(2) the frame which constitutes the connection part with the rail in the upper left, right, bottom, left and right of the frame which mounts a solar cell panel,
(3) Connecting to the lightweight rail in order to install a plurality of frames in the longitudinal direction, fastening the bolt nut between the upper left and right connecting portion and the rail connecting portion of each frame back, the variable length connecting means between the lower left and right connecting portion and the rail connecting portion of the frame back The solar cell panel system for holding the column, characterized in that configured to vary the inclination of each frame by varying the length of the connecting means The method according to claim 22,
The solar panel panel system for strut mounting, characterized in that the variable length connecting means is additionally configured at the upper left and right sides of the frame, and the four connecting means vary the inclination of each frame and the inclination of the inclined surface in the 360 degree direction. The method according to claim 22 or 23,
The solar cell panel system device for strut mounting, characterized in that the charging means and the light sensor means are additionally configured to the struts such as a street lamp or a security lamp on which the system device is constructed, and to automatically flash with a self-charged battery without an external power supply.

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