KR20200114262A - Floating Solar Power Generating System - Google Patents

Abstract

According to the present invention, provided is a floating solar power generation device (10) which is configured by connecting a plurality of floating solar power generation modules (100). The floating solar power generation device (10) comprises: a floating solar power generation module (100); a frame unit (200) on which the floating solar power generation module (100) is supported; a cylindrical drum-type floating body (300) installed on a water surface on a lower portion of the frame unit (200) to float the frame unit (200); a fixing unit (400) fixing and coupling the drum-type floating body (300) to the frame unit (200) and connecting the drum-type floating body (300) to be disposed adjacent to each other; a spud unit (500) provided to extend from the frame unit (200) to maintain a balance of the floating solar power generation device (10); and a control module (C) acquiring status and surrounding environment data of the floating solar power generation device (10) and controlling operation of the spud unit (500).

Description

Floating Solar Power Generating System {Floating Solar Power Generating System}

The present invention relates to an aquatic photovoltaic device, and more particularly, to a floating photovoltaic device that is easy to maintain a balance according to the surrounding environment.

In order to solve various problems of fossil fuels such as environmental problems and depletion problems, research and interest in pollution-free energy using natural power without requiring raw materials is becoming active, and a representative example is solar power generation.

Such photovoltaic power generation facilities are installed on land, and since solar panels must be installed in a large area to use solar energy, many sites are required, and permission from relevant government offices and authorities is required to build solar power generation facilities. Also, in recent years, there is a problem of having difficulty in installation due to complaints from neighboring residents.

In addition to the essential meaning of generating power through solar energy, interest in floating solar power has been increasing in recent years due to various advantages such as high power production efficiency and no need for a site compared to onshore solar power facilities. Research is also being actively conducted.

As a prior art related to photovoltaic power generation installed on the water surface, it is a surface floating solar power generation device including a power generation means and a power generation support installed to have buoyancy on the water surface in Korean Patent Application Publication No. 10-2012-0026924. , Gap maintenance is installed vertically on the upper surface of the power generation support, and two or more buoyancy bodies are installed in the longitudinal direction at the bottom to have buoyancy, and are installed on the water surface of rivers, lakes, reservoir dams, etc. to produce solar energy. A surface floating solar power generation device is disclosed.

However, the conventional water-floating solar power generation device including the above-described prior art has a problem of touching the bottom of the reservoir when a drought occurs in the reservoir and the uneven bottom of the reservoir is exposed, and there is a risk of being damaged due to the local load.

Unexamined Patent Publication No. 10-2012-0026924 (published on March 20, 2012)

The present invention has been devised in view of the above points, and an object thereof is to provide an aquatic solar power generation device capable of stably supporting upper structures.

In addition, another object of the present invention is to provide an aquatic solar power generation device capable of stably generating power by monitoring and controlling from the outside.

As to the floating solar power generation device 10 is configured by connecting a plurality of water solar power module 100, the water solar power generation module 100; A frame part 200 on which the water solar power module 100 is supported; A cylindrical drum-type floating body 300 installed on the water surface under the frame part 200 to float the frame part 200; A fixing part 400 for fixing and coupling the drum-type floating body 300 to the frame part 200 and for connecting the drum-type floating body 300 to be disposed adjacent to each other; A spud portion 500 extending from the frame portion 200 to maintain the balance of the floating photovoltaic device 10; And a control module (C) for acquiring state and surrounding environment data of the floating photovoltaic device 10 and controlling the operation of the spud unit 500.

The spud part 500 may include a connection frame 510 extending from the frame part 200; A leg 520 that is vertically connected to the connection frame 510 and is adjustable in height; And a spud 530 installed at the lower end of the leg 520 to support the leg 520.

The drum-type floating body 300 includes an inner skin 310 made of a plastic material having an inner space; A metallic outer shell 320 formed to surround the inner skin 310 and coated with a paint coating for preventing corrosion on the surface thereof; And, it is formed to penetrate the outer skin 320 and the inner skin 310 of either the upper or lower surface of the drum-type floating body 300, injecting and discharging compressed air for buoyancy control into the inner space of the inner skin 310 It characterized in that it comprises a; outlet for inlet 330.

The fixing part 400 is characterized in that it has a unit structure in which a plurality of clamp parts 410 are disposed so that a plurality of drum-type floating bodies 300 are inserted into one coupling frame 420.

The control module (C) includes a sensor module 600 for acquiring state and surrounding environment data of the floating photovoltaic device 10; A spud height adjustment unit 710 for adjusting the height of the leg 520 according to the information acquired by the sensor module 600; And a communication interface 800 for transmitting the information acquired by the sensor module 600 to an external server 810.

According to the present invention, there is an advantage of stably supporting upper structures and maintaining a balance by applying a spud device capable of adjusting the height under the floating photovoltaic device. In addition, by applying the drum-type floating body as a double shell and forming a paint layer on the metallic shell, there is an advantage in that resistance to corrosion is strong and the appearance is beautiful.

In addition, by controlling the operation by acquiring the state and surrounding environment data of the floating solar power module, it is possible to implement a floating solar power generation device capable of stable power generation.

In addition, it is possible to easily check and control the device and power generation status by transmitting data to the outside.

1 is a perspective view of a water solar power generation device according to an embodiment of the present invention,
FIG. 2 is a side view of the floating photovoltaic device of FIG. 1,
3 is a partial side view of an aquatic photovoltaic module constituting the floating photovoltaic device of FIG.
4 is a partial plan view of the floating solar power module of FIG. 1;
5 is a cross-sectional view and a partially cut-away perspective view of a drum-type floating body,
6 is a perspective view and a cross-sectional view of a state in which a floating body is installed in a fixed part,
7 is a cross-sectional view of a state in which a plurality of floating bodies are installed in a fixed part;
8 is a configuration diagram of a control module of the floating photovoltaic device of FIG. 1

The above objects, features and other advantages of the present invention will become more apparent by describing in detail a preferred embodiment of the present invention with reference to the accompanying drawings. Hereinafter, with reference to the accompanying drawings will be described in detail for the water solar power generation apparatus according to an embodiment of the present invention.

1 and 2 are views showing that the floating photovoltaic device 10 according to the present invention is configured by connecting a plurality of floating photovoltaic modules 100, and the floating photovoltaic module 100 is not shown. It is connected to each other by a non-joint structure, and thus several to hundreds of the water solar power modules 100 are connected to constitute the water solar power generation device 10.

The floating photovoltaic device 10 according to the embodiment of the present invention includes a floating photovoltaic module 100, a frame part 200 supporting the floating photovoltaic module 100, and a floating photovoltaic module 100 The drum-type floating body 300, which provides buoyancy to the upper structure such as the frame part 200, and the drum-type floating body 300 are coupled to the frame part 200 and also connects the drum-type floating body 300. Status and surrounding environment data of the spud unit 500 and the floating photovoltaic device 10 that are provided extending from the fixing part 400 and the frame part 200 to maintain the balance of the floating photovoltaic device 10 It acquires and includes a control module (C) for controlling the operation of the spud unit 500.

3 and 4 will be described in detail the configuration of the water photovoltaic device 10 of the present invention.

The floating photovoltaic module 100 is a general configuration including a solar light collecting plate 110 and a detailed description thereof will be omitted. The number of installations of the floating photovoltaic module 100 may be appropriately adjusted according to the design. The solar light collecting plate 110 is fixed to the inclined support 120 installed at an inclined angle to effectively concentrate sunlight, and the inclined support 120 is coupled to the vertical support 130 coupled to the frame part 200, and eventually The solar light collecting plate 110 is installed to be supported by the frame part 200.

The frame unit 200 is installed to support the floating photovoltaic module 100, and includes a first frame 210 that is installed in plurality in the X-axis direction in the drawing. The number of installations of the first frame 210 may be appropriately adjusted according to design. Meanwhile, a safety footrest 230 for inspecting the solar light collecting plate 110 and the like may be installed on the first frame 210.

Meanwhile, in the above, it has been described that the first frame 210 is installed in the X-axis direction in the drawing to fix the plurality of floating solar power modules 100, but the present invention is not limited thereto, and a plurality of the first frame 210 is installed in the Y-axis direction in the drawing. The second frame 220 may have a unit structure in which a plurality of second frames 220 are disposed to connect the two first frames 210.

The drum-type floating body 300 is installed on the water surface under the first frame 210 and provides buoyancy for floating the frame portion 200 supporting the floating photovoltaic module 100. According to the present embodiment, it is illustrated that three drum-type floating bodies 300 are installed in one first frame 210 (in the X-axis direction in the drawing), but the present invention is not limited thereto, and one or more Dogs can be installed.

This drum-type floating body 300 is fixed and coupled to the body frame 200 by the fixing part 400. In addition, the drum-type floating body 300 is disposed to be connected to each other in the vertical direction (Y-axis direction) on the drawing by the fixing part 400. That is, the drum-type floating body 300 is arranged in a plurality of horizontal rows and vertical rows, and the horizontal rows are arranged by being coupled to the main frame 200 at regular intervals by the fixing part 400, and the vertical rows are arranged. They are connected and arranged to be adjacent to each other by the fixing part 400.

The floating photovoltaic device 10 according to the embodiment of the present invention is configured to include a spud part 500 extending from the frame part 200 to maintain the balance of the floating photovoltaic device 10.

The spud part 500 includes a connection frame 510, a leg 520 and a spud 530.

The connection frame 510 is installed parallel to the coupling frame 420 on the first frame 210 and extends from the first frame 210.

The legs 520 are installed on the connection frame 510 in a vertical direction toward the underwater ground, and the length can be adjusted according to the height of the ground. The leg 520 is divided into an upper leg 521 and a lower leg 522 so that the length can be adjusted using a hydraulic cylinder.

Meanwhile, in the above, it has been described that the leg 520 is divided into an upper leg 521 and a lower leg 522 and the length of the leg 520 is adjusted using a hydraulic cylinder, but the present invention is not limited thereto, and the leg 520 ) May be provided with an elevating drive device for relative movement in the vertical direction to the connection frame 510.

The spud 530 is provided at the lower end of the leg 520 and is provided to stably support the end of the leg 520 on the underwater ground.

As described above, according to the present invention, when the water level is changed due to drought or the like by adjusting the length of the leg 520 or moving it in the vertical direction, the balance of the floating solar power generation device 10 can be maintained even if the height of the underwater ground is not constant. have.

In addition, when the water level is lowered, the spud 530 supports the underwater ground, thereby preventing collisions with the underwater ground of the floating photovoltaic device 10 and damage resulting therefrom.

Referring to FIG. 5, the drum-type floating body 300 has a cylindrical sealed structure and has a dual structure consisting of an inner skin 310 and an outer skin 320.

The inner skin 310 has an inner space and has a structure made of plastic. The outer skin 320 is formed to surround the inner skin and has a metal structure. According to the present embodiment, the outer shell 320 is formed of a steel plate made of iron, and a paint coating layer for preventing corrosion is coated on the surface. In addition, on the upper or lower surface of the drum-type floating body 300, an outlet port 330 is formed to pass through the outer skin 320 and the endothelium 310, and through the outlet port 330, the inner space of the inner skin 310 Compressed air for control can be injected and discharged.

As described above, according to the present invention, the drum-type floating body 300 has a double outer shell of a sealed structure, so that the structure is stable and buoyancy can be stably provided, and a paint layer is formed on the outer shell 320 made of a metal material. It has the advantage of strong resistance to corrosion and a beautiful appearance, and it is possible to inject compressed air into the drum-type floating body 300 through the outlet port 330, thereby improving buoyancy and controlling buoyancy. have.

6 to 7, the fixing part 400 includes a clamp part 410 and a coupling frame 420.

The clamp part 410 has a ring shape so as to surround the drum-type floating body 300 and includes a coupling flange 412 having a fastening hole for fastening bolts thereon.

In the coupling frame 420, an upper end of the clamp part 410 is fastened with a bolt, and a fastening hole through which the lower end of the first frame 210 can be fastened with a bolt is formed at the top. In one embodiment of the present invention, the coupling frame 420 has a'I'-shaped frame shape, but the present invention is not limited thereto, and various other configurations such as a'H'-shaped frame may be used.

8 is a block diagram of a block for controlling and monitoring the floating photovoltaic device 10 according to an embodiment of the present invention.

The control module (C) includes a sensor module 600 for acquiring state and surrounding environment data of the floating solar power generation device 10, a spurt height adjustment unit 700 for adjusting the height of the leg 520, and on-water solar power generation. It includes a communication interface 800 for transmitting information on the device 10 to an external server 810.

The sensor module 600 includes a tilt sensor 610 that measures the inclination of the floating photovoltaic device 10, a pressure sensor 620 that measures the pressure applied to the spud 530, and the floating photovoltaic device (10) The water photovoltaic module sensor 630 that measures the power generation efficiency and state of the floating photovoltaic device 10, such as impact, the amount of sunlight, etc., the temperature around the floating photovoltaic device 10, water temperature, and It includes an ambient environment measurement sensor 640 that measures the surrounding environment such as water depth. In addition, the present invention is not limited thereto, and a sensor for collecting data for stable power generation and state maintenance of the floating photovoltaic device 10 may be further provided.

The spud height adjustment unit 700 includes means for adjusting the height of the leg 520 by receiving data collected by the sensor module 600.

The communication interface 800 receives the data collected by the sensor module 600 and transmits it to the server 810 located outside, so that the floating photovoltaic device 10 does not require the user to access the floating photovoltaic device 10. It is possible to monitor and control the status and surrounding conditions.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the specific embodiments described above. That is, a person of ordinary skill in the technical field to which the present invention pertains can make a number of changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications It should be considered that equivalents are also within the scope of the present invention.

10. Floating solar power device
100. Water solar power module 110. Solar panel
120. Inclined support 130. Vertical support
200. Frame part 210. First frame
220. Second frame 230. Safety footing
300. Drum type float 310. Endothelial
320. Outer sheath 330. Outlet port
400. Fixed part 410. Clamp part
420. Defective Frame
500. Spud part 510. Connection frame
520. Leg 530. Spud
600. Sensor module
700. Spud Height Adjuster
800. Communication interface 810. Server
C. Control module

Claims (5)

It relates to an aquatic solar power generation device 10 configured by connecting a plurality of water solar power modules 100,
Water solar power module 100;
A frame part 200 on which the water solar power module 100 is supported;
A cylindrical drum-type floating body 300 installed on the water surface under the frame part 200 to float the frame part 200;
A fixing part 400 for fixing and coupling the drum-type floating body 300 to the frame part 200 and for connecting the drum-type floating body 300 to be disposed adjacent to each other;
A spud portion 500 extending from the frame portion 200 to maintain the balance of the floating photovoltaic device 10; And,
And a control module (C) for acquiring state and surrounding environment data of the floating photovoltaic device (10) and controlling the operation of the spud unit (500).
The method of claim 1,
The spud part 500,
A connection frame 510 extending from the frame part 200;
A leg 520 that is vertically connected to the connection frame 510 and is adjustable in height;
And a spud 530 installed at the lower end of the leg 520 to support the leg 520.
The method of claim 1,
The drum-type floating body 300,
An inner skin 310 made of a plastic material having an inner space;
A metallic outer shell 320 formed to surround the inner skin 310 and coated with a paint coating for preventing corrosion on the surface thereof; And,
It is formed so as to penetrate the outer skin 320 and the inner skin 310 of either the upper or lower surface of the drum-type floating body 300, for injecting and discharging compressed air for buoyancy control into the inner space of the inner skin 310 Outlet and inlet 330; floating photovoltaic device comprising a.
The method of claim 1,
The fixing part 400 has a unit structure in which a plurality of clamp parts 410 are disposed so that a plurality of drum-type floating bodies 300 are inserted into one coupling frame 420. Device.
The method of claim 2,
The control module (C),
A sensor module 600 for acquiring state and surrounding environment data of the floating photovoltaic device 10;
A spud height adjustment unit 710 for adjusting the height of the leg 520 according to the information acquired by the sensor module 600; And,
And a communication interface 800 for transmitting the information acquired by the sensor module 600 to an external server 810.

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