KR102211309B1 - Photovoltaic system using a cable - Google Patents

Abstract

The present invention relates to a solar system using a cable, comprising: a first support pillar installed on a first mountain positioned at one side of a direction crossing the valley based on the valley crossing in one direction; A second support pillar installed on a second mountain positioned on the other side of the valley and having a set height difference in a direction downward from the first support pillar; A first cable connecting the first support pillar and the second support pillar; A second cable connecting the first support column and the second support column, the second cable spaced apart by a set distance in the upward direction of the first cable; And a plurality of installed on the first cable and spaced apart at a set interval along the length direction of the second cable so as to be connected to the second cable, and the upper surface rotates along the movement path of the sun and It includes solar panel units that collect and generate electricity.

Description

Photovoltaic system using a cable}

The present invention relates to a photovoltaic facility system using a cable, and more particularly, to a photovoltaic facility system using a cable capable of collecting sunlight by installing between a mountain and a mountain with a valley in between.

Fossil fuels, which are mainly used to generate electricity today, are a kind of resource with limited reserves on the planet, and are used indiscriminately according to the rapidly increasing acceptance of electric energy due to industrial development, causing serious environmental pollution, as well as in the near future. As it is expected to be exhausted, the development of so-called clean energy that can replace fossil fuels is being actively promoted around the world, and a representative example is solar power generation.

Solar power generation is attracting great interest because it is pollution-free and can be used infinitely among alternative energy sources along with wind power generation. In particular, in solar power generation, the power generation part is a semiconductor device, and the control part is composed of electronic parts that have a very long lifespan, and there is no mechanical vibration or noise, and the operating life of several decades is guaranteed.

The geometries of the ground on which the solar power module is installed enables various applications when installed, and the control and operation of the corresponding power generation system can be remotely or unmanned through a semi-automated or automated program. Therefore, the active use of the solar power generation system is an alternative power generation system that must be actively developed in an environment like ours where energy resources are absolutely scarce.

Solar cell panels are designed in a variety of sizes from large to small, and in order to produce a large amount of electricity, it is necessary to secure a large space since tens or hundreds of large-sized solar cell panels must be provided.

However, in the case of Korea, most of the land is composed of mountainous areas, and in the relatively small plains, it is not enough for people to live, agricultural, and industrial areas, so the plain area has a large area for the production of large amounts of electricity. It is not easy to secure ground space.

In addition, in order to replace a plain area with a relatively high land price, the facility of a large-capacity solar power generation site is intended to be used as a photovoltaic power generation site by securing a large area of a forest area with a relatively low land price. In order to have economic feasibility, development activities should be minimized as possible, but most of the mountain areas have a disadvantage that additional costs for development are required.

Therefore, there is a need for a technology that can build solar power generation facilities in mountainous areas that have been underutilized in terms of securing a relatively economical site area beyond the method of using it as a solar power generation site in the plain area, which was mainly used in the past. I will.

Korean Patent Registration No. 10-1273292

An object of the present invention is to provide a photovoltaic facility system using a cable capable of collecting sunlight by installing between a mountain and a mountain with a valley therebetween.

The present invention includes: a first support column installed on a first mountain positioned on one side of a direction crossing the valley based on a valley crossing in one direction; A second support pillar installed on a second mountain positioned on the other side of the valley and having a set height difference in a direction downward from the first support pillar; A single first cable connecting the first support pillar and the second support pillar; And a plurality of installed on the first cable, which are spaced apart from each other at a set interval along the length direction of the first cable, and generate electricity by collecting light from the sun while the top surface rotates along the movement path of the sun. It provides a solar installation system comprising photovoltaic panel units.

According to another aspect of the present invention, the present invention relates to a first support pillar installed on a first mountain positioned at one side of a direction crossing the valley based on the valley crossing in one direction; A second support pillar installed on a second mountain positioned on the other side of the valley and having a set height difference in a direction downward from the first support pillar; A first cable connecting the first support pillar and the second support pillar; A second cable connecting the first support column and the second support column, the second cable spaced apart by a set distance in the upward direction of the first cable; And a plurality of installed on the first cable and spaced apart at a set interval along the length direction of the second cable so as to be connected to the second cable, and the upper surface rotates along the movement path of the sun and It provides a solar facility system including solar panel units that collect and generate electricity.

The solar installation system using a cable according to the present invention has the following effects.

First, by connecting cables between mountains and mountains with valleys in between, and installing solar panel units on the cables, there is no need for construction work such as ground work to prepare a separate flat slope space. There is an advantage of being able to install a solar facility system including four solar panel units.

Second, since a cable connection part is formed on the lower surface of the solar panel, the solar panel can be supported with only one cable, so installation is easy and a compact solar installation system can be implemented.

Third, since the photovoltaic panel is rotated along the movement path of the sun by the rotating member, it is possible to efficiently collect sunlight and generate power.

Fourth, since the solar panel unit has a foldable structure, damage caused by rainfall, snowfall, hail and other falling objects can be prevented.

1 is a perspective view showing a solar system using a cable according to an embodiment of the present invention.
FIG. 2 is a side view of the photovoltaic system of FIG. 1 as viewed from the side.
3 is a perspective view illustrating a solar panel unit of the solar installation system according to FIG. 1.
4 is a cross-sectional view taken along AA′ of FIG. 3.
5 is a perspective view illustrating a solar panel unit of a solar system according to another embodiment of the present invention.
6 and 7 are front views illustrating a rotated state of the solar panel unit according to FIG. 5.
8 is a front view illustrating an operation in which the solar panel unit according to FIG. 5 is folded.

1 to 8 are shown for the solar installation system using a cable according to the present invention.

First, a photovoltaic facility system (hereinafter, a photovoltaic facility system) using a cable according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4.

The solar installation system includes a first support column 111, a second support column 113, a single first cable 115, and a solar panel unit 200. The first support pillar 111 is installed on the first mountain 10 located at the north side of the valley 1 with respect to the valley 1 crossing the east side and the west side.

The second support pillar 113 is installed on the second mountain 30 located on the south side of the valley 1. The second support pillar 113 has a set height difference in a downward direction than the first support pillar 111.

The height of the portion where the first support pillar 111 is installed in the first mountain 10 is higher than the height of the portion in the second mountain 30 where the second support pillar 113 is installed. However, this is only limited to this embodiment, and the first support pillar 111 and the second support pillar 113 have the same height, but the height of the first mountain 10 is the same as that of the second mountain 30. It may be higher than the height.

The first support pillar 111 and the second support pillar 113 may be electrically connected. As the first support pillar 111 and the second support pillar 113 are electrically connected, electricity may be supplied to the solar panel unit 200 to be described later.

The single first cable 115 connects the first support pillar 111 and the second support pillar 113. The solar panel unit 200 is installed on the first cable 115. A plurality of solar panel units 200 are installed with an upper surface facing the south side and spaced apart at a predetermined interval along the length direction of the first cable 115.

The solar panel 210 is installed on the first cable 115 so that the upper surface faces the sun and faces the south, and absorbs the sunlight from the upper surface to generate electricity. The solar panel 210 includes a cable connection part 211 provided on a lower surface.

The cable connection part 211 is provided on the lower surface of the solar panel 210 in the center of either a horizontal direction or a vertical direction. One or a plurality of cable connection portions 211 are provided, and are provided at a predetermined interval along the other of the horizontal direction or the vertical direction. The cable connection part 211 includes a connection body (not shown) in which a hollow is formed, and the first cable 115 is inserted through the cable connection part 211.

On the other hand, the solar installation system further includes a second cable 117 and a connection cable 118. The second cable 117 connects the first support pillar 111 and the second support pillar 113, and is spaced apart from the first cable 115 by a set distance in a downward direction.

One side of the connection cable 118 is connected to the first cable 115 and the other side is connected to the second cable 117. A plurality of connection cables 118 are provided at predetermined intervals along the length direction of the first cable 115 and the second cable 117. The connection cables 118 connect the first cable 115 and the second cable 117 to reduce vibration generated in the first cable 115.

The solar installation system further includes a mesh module. The mesh module is separated by a set distance in the east direction and the west direction based on the solar panel units 200 to prevent the solar panel units from being shaken by the wind.

The mesh module includes third support pillars 311, the fourth support pillars 313 and a mesh 330. The third support pillars 311 are installed on the first mountain 10 at a set distance apart from the first support pillar 111 to the east side and the west side. The fourth support pillars 313 are installed on the second mountain 30 at a set distance apart from the second support pillar 113 to the east side and the west side.

The net 330 is installed to surround the solar panel unit 200 by connecting the third support pillars 311 on one side and connecting the fourth support pillars 313 on the other side. The net 330 blocks wind blowing between the first mountain 10 and the second mountain 30 to prevent the solar panel unit 200 from being shaken by the wind.

In addition, it protects the worker who installs the solar facility system from fall, and prevents the fall of the solar panel 210 to prevent damage to the solar panel 210 and due to the solar panel 210 Prevent human injury accidents.

5 to 8 illustrate a solar system according to another embodiment of the present invention.

The photovoltaic system according to the present embodiment also includes a first support column 111 and a second support column 113, which is the same configuration as the above-described embodiment, and thus a detailed description thereof will be omitted.

In this embodiment, a first cable 115a, a second cable 117a, and a solar panel unit 200a are included. However, in the present embodiment, as shown in FIG. 5, the second cable 117a is spaced apart from the first cable 115a by a set distance.

The solar panel unit 200a is installed on the first cable 115a and is also connected to the second cable 117a. In the above-described embodiment, the solar panel unit was fixedly installed on the first cable 115, but in this embodiment, the solar panel unit 200a is installed to rotate along the movement path of the sun. . This will be described in more detail through a description of the configuration of the solar panel unit 200a.

The solar panel unit 200a also has a top surface facing south, and as described above, while rotating along the moving path of the sun, it collects the sun's light to generate electricity.

The solar panel unit 200a includes a support shaft 230a, solar panels 210a, and a control module. The support shaft 230a is coupled to the first cable 115a, and the first cable 115a passes through the support shaft 230a.

The solar panels 210a are rotatably coupled to both sides of the support shaft 230a with their upper surface facing the south side. Electricity is generated by absorbing the sunlight on the upper surface of the solar panel 210a.

In this embodiment, a pair of solar panels 210a are rotatably coupled to one support shaft 230a on both sides with respect to the support shaft 230a, and a pair of the solar panels 210a ) Are separated by a set distance along the longitudinal direction of the support shaft 230a, and are combined in plurality.

The size of the inner diameter of the support shaft 230a may be slightly larger than the size of the outer diameter of the first cable 115a. Accordingly, the support shaft 230a may be rotated by a difference between the size of the inner diameter of the support shaft 230a and the outer diameter of the first cable 115a. Alternatively, a bearing (not shown) may be provided between the support shaft 230a and the first cable 115a. Specifically, while a bearing (not shown) is inserted into the support shaft 230a, the first cable 115a may be coupled to the support shaft 230a while passing through the bearing (not shown). That is, the support shaft 230a may be rotated by the bearing (not shown).

The control module is provided on the second cable 117a, and is connected to the solar panels 210a to rotate the solar panels 210a along the movement path of the sun or the solar panel in case of rain. The solar panels 210a are rotated based on the support shaft 230a so that the lower surfaces of 210a are close to each other.

The control module includes a controller 220, a winding member 240a, and wires 251a and 251b. The controller 220 is provided on the second cable 117a. The controller 2200 transmits a command to rotate the solar panels 210a from the east side to the west side along the movement path of the sun, or when it rains, the support so that the bottom surfaces of the solar panels 210a become close to each other. A command to rotate the solar panel 210a is transmitted based on the axis 230a.

The winding member 240a receives a command transmitted from the controller 220. The winding member 240a is provided on the second cable 117a. More specifically, the second cable 117a passes through the winding member 240a, and the winding member 240a is coupled to the second cable 117a. However, the winding member 24a is rotatably coupled to the second cable 117a.

The winding member 240a is electrically connected to the controller 220 and thus rotates clockwise or counterclockwise according to a command transmitted from the controller 220. A plurality of winding members 240a are provided along the length direction of the second cable 117a. In this embodiment, the winding member 240a is provided in a front-rear direction with respect to the controller 220, and two winding members 240a are also provided in front of the controller 220, and the controller 220 The two winding members 240a are also provided at the rear.

One side of the wires 251a and 251b is wound around the winding member 240a, and the other side is connected to the front end of the solar panel 210a. Therefore, as described above, two winding members 240a are provided based on the controller 220.

That is, one side of the one wire 251a is wound on the one winding member 240a, and the other side of the wire 251a is the solar panel coupled to the left side with respect to the support shaft 230a. It is connected to the tip of (210a). One side of the other wire 251b is wound on the other winding member 240a, and the other side of the wire 251b is the solar panel coupled to the right side with respect to the support shaft 230a It is connected to the tip of (210a).

Meanwhile, as described above, connecting one winding member 240a and one solar panel 210a with a single wire corresponds to the present embodiment, and is not limited thereto. One wire is wound on one winding member, and both sides of the wire may be connected to two solar panels respectively.

When the controller 220 commands the solar panels 210a to rotate toward the east side toward the sun, the winding members 240a receiving this command rotate respectively. The winding member 240a on which the wire 251b connecting the solar panel 210a located at the east side with respect to the support shaft 230a is wound is rotated so that the length of the wire 251b becomes longer. .

And the winding member (240a) on which the wire (251a) connecting the solar panel (210a) located on the west side with respect to the support shaft (230a) is wound is rotated so that the length of the wire (251a) is shortened. do.

On the other hand, when the sun moves to the west, the controller 220 issues a command to rotate the solar panels 210a toward the west, and rotates the solar panel 210a in an operation opposite to the above. .

Meanwhile, in the case of rain, the solar panels 210a may be folded with respect to the support shaft 230a to prevent damage or damage to the solar panels 210a. Folding here means rotating the solar panels 210a based on the support shafts 230a so that the lower surfaces of the solar panels 210a are close to each other.

8, when a command to fold the solar panels 210a through the controller 220, the winding member 240a rotates so that the lengths of the wires 251a and 251b are lengthened. . As the wires 251a and 251b rotate, the solar panels 210a are rotated and folded so that the rear surfaces of the solar panels 210a become close to each other.

The controller 220 may be connected to an operator's control terminal (not shown) through wireless communication. Accordingly, the operator may directly adjust the controller 220 through the adjustment terminal (not shown) according to the movement of the sun. Examples of the wireless communication include Internet of Things (IoT), RF communication, and Bluetooth.

Meanwhile, in another embodiment, the controller 220 may transmit a command according to a preset input value. For example, since the sun's movement path can be predicted in advance, the angle of the sun's movement path over time can be stored. Accordingly, the controller 220 may transmit a command to the winding member 240a every set time to rotate the support shaft 230a and the solar panels 210a.

In addition, a sensor (not shown) capable of detecting a rainy weather condition is provided, and when snow, rain or hail is detected through the sensor (not shown), the controller 220 causes the solar panels 210a to be folded. You can also have a command sent so that you can lose.

In this embodiment, as in the above-described embodiment, the mesh module is included. Since the mesh module is configured in the same manner as in the above-described embodiment, a detailed description thereof will be omitted.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

111: first support pillar 113: second support pillar
115: first cable 117: second cable
118: connection cable 200, 200a: solar panel unit
210, 210a: solar panel 211: cable connection
213: fixing plate 220: controller
230a: support shaft 240a: winding member
251a, 251b: wire 260a: connecting cable

Claims (14)

A first support column;
A second support pillar disposed to be spaced apart from the first support pillar;
A single first cable fixed to the first support pillar and the second support pillar, respectively, and connecting the first support pillar and the second support pillar;
A plurality of solar panels disposed to be spaced apart from each other along the first cable;
A plurality of cable connection portions fixed to the solar panels and through which the first cable is inserted so that the first cable extends across the center of the solar panels; And
A solar installation system comprising bearings disposed between the first cable and each of the cable connection portions to enable the solar panels to be rotatably coupled to the first cable. The method according to claim 1,
The first support pillar is installed on a first mountain located at one side of the direction crossing the valley based on the valley crossing in one direction,
The second support pillar is installed on a second mountain located on the other side in a direction crossing the valley, and has a set height difference in a downward direction than the first support pillar. The method according to claim 2,
The valley crosses from east to west,
The first mountain is located at the north side of the valley, the second mountain is located at the south side of the valley, and the upper surface of the solar panel faces south. The method according to claim 2,
A photovoltaic system using a cable in which a height of a portion in which the first support pillar is installed in the first mountain is higher than a height of a portion in which the second support pillar is installed in the second mountain. The method of claim 3,
The solar facility system,
A solar system using a cable to install a mesh module to prevent the solar panels from being shaken by the wind by being spaced apart from the solar panel by a set distance to the east side and the west side. The method of claim 5,
The mesh module,
Third support pillars installed on the first mountain and spaced apart from the first support pillar by a set distance to the east side and the west side;
Fourth support pillars installed on the second mountain and spaced apart by a set distance from the second support pillar to the east side and the west side; And
A photovoltaic facility system using a cable including a net connecting the third support pillars on one side and connecting the fourth support pillars on the other side in a form surrounding the solar panels. delete delete delete delete delete delete delete delete

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