KR102284699B1 - A guard pence of offshore photovoltaic power generation apparatus - Google Patents

Abstract

The present invention relates to a guard fence of an offshore photovoltaic device, and more particularly, by converting the traveling direction of a wave to the opposite direction to prevent damage to the offshore photovoltaic device due to the clear water phenomenon, and to prevent damage to the offshore photovoltaic device It relates to a guard fence of an offshore solar power plant that can prevent the spread of contaminants into the sea.
To this end, a body moored around the offshore photovoltaic device is provided in plurality to partition the offshore photovoltaic device and the sea in a linear or annular shape; and a curvature groove in the form of a concave groove formed on one or both sides of the body to change the traveling direction of the wave in the opposite direction. A buoyancy body having a larger volume than the body is further installed in the body, and a weight for lowering the center of gravity of the buoyancy body is installed in the center of the buoyancy body toward the bottom, and the curvature groove portion with respect to the moving direction of the wave, up and down It is formed to be rounded and concave in the direction to flexibly change the propagation direction of the wave in the opposite direction. It provides a guard fence of an offshore solar power generation device, characterized in that reducing the sway angle, the upper portion of the body is formed with a streamlined head portion convexly formed upwards to reduce wind resistance.

Description

Guard fence of offshore photovoltaic power generation apparatus {A guard pence of offshore photovoltaic power generation apparatus}

The present invention relates to a guard fence of an offshore photovoltaic device, and more particularly, to a guard fence of an offshore photovoltaic device that can block the fresh water phenomenon and the spread of contaminants of the offshore photovoltaic device into the sea. .

In connection with the energy problem, the development and use of new and renewable energy is actively carried out. Among them, solar power generation is receiving the most attention because it is easier to install and operate compared to other power generation methods, and it is possible to secure relatively stable power generation power. Such photovoltaic power generation is configured based on a solar cell that receives sunlight and produces power by the photoelectric effect, and a converter that converts the generated power generated by the solar cell into AC power or converts it to DC power. Compared to other power generation methods, solar power generation has the advantage of being relatively easy to install and operate and can be installed quickly. am. However, it is not easy to secure a site that meets the site conditions. In order to solve this problem, it is installed and operated on water and sea such as rivers, lakes, and reservoirs. In particular, since the offshore photovoltaic device utilizes the idle water surface, the cost of purchasing a site is reduced, and there is an advantage in that the cooling effect is excellent compared to the solar power facility on the ground.

As shown in FIG. 1 , the conventional offshore photovoltaic device is composed of a buoyancy body 10 , a photovoltaic module 20 , and a frame 30 . At this time, the buoyancy body 10 may be configured in plurality in consideration of the marine environment and the scale of the photovoltaic module 20 . On the other hand, the conventional offshore solar power generation device is always exposed to the influence of waves, and as shown in FIG. 2 due to large waves, long waves, or Calvin waves generated by ships, waves Green water may occur. There is a problem that waves can directly affect the offshore solar power generation device due to the fresh water phenomenon, and the waves can indirectly affect the offshore solar power generation device by carrying marine debris and various floating objects. In addition, there is a problem that pollutants generated by washing of the offshore photovoltaic device or an accident of the offshore photovoltaic device may spread to distant seas. Therefore, there is a need for a means to prevent the waves from hitting the offshore photovoltaic device and prevent the spread of contaminants from the offshore photovoltaic device.

Republic of Korea Patent Registration No. 10-1246487

The present invention has been devised to solve the above problems, and an object of the present invention is to install a floating object in the vicinity of the offshore photovoltaic device to access waves and sea to the offshore photovoltaic device by green water. It is intended to provide a guard fence for offshore solar power generation devices to prevent the spread of contaminants from the solar power generation device to the sea.

In order to achieve the above object, the present invention is a body moored to the periphery of the offshore photovoltaic device, which is provided in plurality to partition the offshore photovoltaic device and the sea in a linear or annular shape; and a curvature groove in the form of a concave groove formed on one side or both sides of the body to change the traveling direction of the wave in the opposite direction. A buoyancy body having a larger volume than the body is further installed in the body, and a weight for lowering the center of gravity of the buoyancy body is installed in the center of the buoyancy body toward the bottom, and the curvature groove portion with respect to the traveling direction of the wave, up and down It is formed to be rounded and concave in the direction to flexibly change the propagation direction of the wave in the opposite direction. It provides a guard fence of the offshore solar power generation device, characterized in that reducing the sway angle, the upper portion of the body is formed with a streamlined head convexly formed toward the upper side to reduce wind resistance.

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The guard fence of the offshore photovoltaic device according to the present invention is installed around the offshore photovoltaic device, and by forming a curved groove with respect to the traveling direction of the wave, it is possible to prevent the blue water phenomenon that the wave hits the offshore photovoltaic device there is an effect That is, the wave not only changes the direction of travel through the curvature groove, but also attenuates the energy of the wave, and as the wave energy is attenuated, the wave height also decreases. It has a deterrent effect.

In addition, since the guard fence of the offshore photovoltaic device comprises a weight at the lower end, the center of gravity can be lowered, thereby increasing the restoring force according to the lateral sway. In particular, the weight can increase the viscous resistance when the lateral oscillation of the guard fence occurs to reduce the lateral oscillation angle, thereby increasing the efficiency of preventing movement of water contaminants.

In addition, the guard fence of the offshore photovoltaic device further comprises a vortex-forming member capable of forming a vortex at the lower end, thereby increasing the kinetic energy consumption of the guard fence when lateral oscillation occurs, thereby increasing the energy attenuation efficiency of waves. there is.

In addition, the guard fence of the offshore photovoltaic device has an effect of reducing wind resistance by configuring a streamlined head portion on the upper portion.

1 is a view showing a state in which an offshore solar power generation device is floated on the sea.
FIG. 2 is a view showing the fresh water phenomenon in which waves cover the top of the offshore solar power generation device.
3 is a perspective view showing a guard fence of the offshore solar power generation device according to the first embodiment of the present invention.
4 is a view showing a guard fence of the offshore solar power generation device according to the second embodiment of the present invention.
5 is a view showing a guard fence of the offshore solar power generation device according to the third embodiment of the present invention.
6A and 6B are views and operational diagrams of a guard fence of an offshore solar power generation device according to a fourth embodiment of the present invention.
7 is a view showing a guard fence of the offshore solar power generation device according to the fifth embodiment of the present invention.
8 is a view showing a state in which the guard fence of the offshore photovoltaic device according to the fifth embodiment of the present invention is installed on one side of the offshore photovoltaic device.
9a is a plan view showing a state in which the guard fence of the offshore photovoltaic device according to the present invention is linearly arranged on one side of the offshore photovoltaic device.
9b is a plan view showing a state in which the guard fence of the offshore photovoltaic device according to the present invention is arranged in an annular shape on one side of the offshore photovoltaic device.

The terms or words used in the present specification and claims are not to be construed as limited in their ordinary or dictionary meanings, and on the principle that the inventor can appropriately define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a guard fence (hereinafter, referred to as a 'guard fence) of the offshore solar power generation device according to the first embodiment of the present invention will be described with reference to FIG. 3 attached.

The guard fence is installed on one side of the offshore photovoltaic device to prevent damage to the offshore photovoltaic device due to the clear water phenomenon, and to block the spread of contaminants from the offshore photovoltaic device to the sea.

The guard fence includes a body 100 and a curved groove 200 as shown in FIG. 3 . The body 100 constitutes the exterior of the guard fence, and is provided with a material having buoyancy. The shape of the body is not specifically limited, and for convenience of explanation, a rectangular shape is exemplified in this bottle.

The curvature groove 200 serves to change the direction in which the wave wave travels. The curvature groove 200 is configured to change the wave traveling toward the guard fence in the reverse direction. The curvature groove 200 is formed on one or both sides of the body 100 , and is preferably formed on both sides of the body 100 . The curvature groove 200 is preferably concave and rounded in the body 100 . That is, the rounded shape of the curvature groove portion 200 is such that the traveling direction of the wave can be flexibly changed in the opposite direction.

It is preferable that an energy attenuation protrusion 210 is further formed at the upper end of the curvature groove 200 to attenuate the energy of the wave. The energy attenuation protrusion 210 is formed downward from the upper end of the curved groove portion 200 . The wave is guided along the curvature groove portion 200, the direction of travel in the opposite direction is changed, and while being crushed by the energy attenuation protrusion 210, some energy is lost. That is, the wave loses some of the energy due to the curvature groove 200 in which the energy attenuation protrusion 210 is formed, and the wave height is reduced as much as proportional to the route of the energy lost by the wave. that can be reduced

In addition, the guard fence can not only reduce the possibility of generating fresh water as described above, but also prevent the contaminants generated from the offshore solar power generation device from spreading to the sea. Contaminants may be contaminated water due to the washing of offshore solar power generators or debris that may occur when offshore photovoltaic devices are damaged. It is possible to block the movement of contaminants between the generator and the guard fence into the sea.

Figure 4 shows a guard fence according to a second embodiment of the present invention, it is possible to further configure the buoyancy body 300 to the body 100. The volume of the buoyancy body 300 is formed to be larger than the volume of the body 100 and is installed in the lower portion of the body 100 . As the buoyancy body 300 is additionally configured in the body 100, it is possible to increase the buoyancy of the guard fence, and since the height of the guard fence increases, it is possible to increase the efficiency of preventing flooding of waves according to the green water phenomenon.

5 is a view showing a guard fence according to a third embodiment of the present invention, the weight 400 is installed in the buoyancy body (300). As the weight 400 is installed on the buoyancy body 300, the center of gravity of the guard fence is lowered. Since the center of gravity of the guard fence is lowered, it is possible to increase the restoring force when the guard fence is swayed. In addition, since it is possible to increase the viscous resistance of the guard fence through the weight 400, it is possible to reduce the lateral yaw angle of the guard fence. A connection member 410 for installing the weight 400 is installed between the buoyancy body 300 and the weight 400 . The connecting member 410 is installed extending downwardly from the buoyancy body 300 as shown in FIG. 5 , and the weight 400 is installed at the lower end of the connecting member 410 .

Figure 6a shows a guard fence according to a fourth embodiment of the present invention, the vortex forming member 500 is installed on the weight (400). The vortex forming member 500 serves to form a vortex when the guard fence oscillates to further increase the viscous resistance of the guard fence and further reduce the oscillation angle. The vortex forming member 500 is formed downward from the weight 400 as shown in FIG. 6A . Accordingly, the guard fence increases the viscous resistance through the weight 400 to attenuate the external force that generates lateral oscillation, and generates a vortex through the vortex forming member 500 to distribute the external force, thereby reducing the lateral oscillation angle of the guard fence. can

7 is a view showing a guard fence according to a fifth embodiment of the present invention, a streamlined head portion 600 is formed on the upper portion of the body (100). Due to the nature of the windy sea, the movement of the guard fence may fluctuate severely due to the resistance of the wind. . In particular, the installation structure of the head portion 60) on the guard fence structure of the square shape can be expected to have an excellent effect of reducing wind resistance. On the other hand, the binding means 310 is installed in the buoyancy body 300 of the guard fence. The binding means 310 is a configuration for binding a plurality of guard fences to each other.

Hereinafter, the installation and operation of the guard fence of the offshore photovoltaic device configured as described above will be described with reference to FIGS. 8 to 9B.

As shown in Figure 8, the operator installs a guard fence on one side of the offshore solar power generation device. The guard fence is in a state of being suspended in the sea with a low center of gravity through the weight 400 . Afterwards, when a wave formed by a large wave, a long wave, or a Calvin wave of a ship, etc. proceeds toward the offshore photovoltaic device, the wave wave is blocked by the guard fence and cannot proceed to the offshore photovoltaic device. The wave wave is guided by the curvature groove 200 so that the traveling direction is changed in the reverse direction, and part of the energy is lost through the energy attenuation protrusion 210 . In addition, the viscous resistance of the guard fence is increased due to the weight 400 and the vortex forming member 500, so that lateral movement does not occur significantly. That is, the guard fence can block the movement of blue waves due to the fresh water phenomenon to the offshore solar power generation device while maintaining a stable state while floating on the sea.

On the other hand, the guard fence blocks the contaminants of the sea that move with the wave, for example, marine garbage, seaweed, and the like to prevent the contaminants from moving to the offshore solar power generation device. In addition, the guard fence can prevent the contaminants generated from the offshore photovoltaic device, such as leaked oil, and the debris of the offshore photovoltaic device, from spreading to the sea.

The above-mentioned guard fence may be installed linearly as shown in FIG. 9a around the offshore photovoltaic device, and may be installed in an annular shape surrounding the offshore photovoltaic device as shown in FIG. 9b. That is, in consideration of the offshore installation environment, the operator can use the binding means 310 of the guard fence to bind the adjacent guard fences to install it in a linear or annular shape around the offshore solar power generation device.

As described so far, the guard fence of the offshore photovoltaic device according to the present invention is installed around the offshore photovoltaic device to prevent the fresh water phenomenon, and to prevent the contaminants of the offshore photovoltaic device from spreading to the sea. made it possible Accordingly, it is possible to prevent the photovoltaic module from being damaged and to prevent the contaminants generated from the offshore photovoltaic device from spreading to the sea.

Although the present invention has been described in detail with respect to the described embodiments, it is apparent to those skilled in the art that various modifications and variations are possible within the scope of the technical spirit of the present invention, and it is natural that such variations and modifications belong to the appended claims.

100: body 200: curved groove
210: energy attenuation stone 300: buoyancy body
310: binding means 400: weight
410: connecting member 500: vortex forming member
600: head

Claims (4)

a body moored around the offshore photovoltaic device and provided in plurality to partition the offshore photovoltaic device and the sea in a linear or annular shape; and
Containing: on one or both sides of the body, a curved groove in the form of a concave groove formed so as to change the traveling direction of the wave in the opposite direction;
An energy attenuating protrusion extending downward is formed at the upper end of the curved groove portion,
A buoyant body larger in volume than the body is installed in the body,
In the center of the buoyancy body, a weight for lowering the center of gravity of the buoyancy body is installed downward,
The curvature groove portion is formed to be rounded and concave in the up and down directions with respect to the traveling direction of the wave to flexibly change the traveling direction of the wave in the opposite direction,
The weight is provided with a vortex forming member formed downward from the weight to form a vortex when the buoyant body oscillates to reduce the yaw angle of the buoyant body,
Guard fence of an offshore solar power generation device, characterized in that the upper portion of the body is formed with a streamlined head convexly formed upward to reduce wind resistance.

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