KR20160119671A - Floating solar power generating system - Google Patents

Abstract

The present invention relates to a floating solar power generating system having solar power facilities on a floating body floating on the water, and more specifically, to a floating solar power generating system. A foamed styrofoam coupler surrounded by a hard skin forms a lower base under the water. A concrete molded body including a fixing fastening means capable of directly fixing materials for installation of solar cell modules and a connecting means for connecting floating bodies includes concrete floating bodies that form upper caps above the water, and connects the concrete floating bodies with connecting members. The concrete floating bodies and the solar cell modules are alternately installed in a north-south direction. Thus, the floating solar power generating system can minimize the output loss of the solar cell modules due to temperature rise, can optimally manage the inclined angle of the solar cell module by changing gaps between the concrete floating bodies depending on seasons and situations, and can obtain the maximum amount of electricity of the year by maximally preventing the solar cell modules from being shaded.

Description

[0001] FLOATING SOLAR POWER GENERATING SYSTEM [0002]

The present invention relates to a water-state photovoltaic power generation apparatus having a solar power generation facility in a float phase suspended in a water phase, and more particularly to a water-based photovoltaic power generation system in which a foamed styrofoam assembly surrounded by an outer skin forms a lower base The upper space exposed to the water surface is provided with a concrete part fluid composed of a concrete cap containing fixing means for fixing the solar cell module installation material directly, and a plurality of concrete part fluids are connected to the connection member The distance between the concrete floats can be changed to prevent the solar cell module from being shaded and the solar cell module is installed on the water surface between the concrete floors to minimize the output loss of the solar cell module And more particularly to a water-state photovoltaic power generation apparatus.

Production of electricity using underground resources such as coal and oil is limited due to problems of pollution and resource depletion, and development of technologies using natural energy is urgently required. The use of traditional natural energy is hydroelectric power, which generates electric power by constructing a dam on a river. In recent years, wind power using wind, tidal power using tidal water only, and solar power using solar power It is getting attention.

Wind power generation, hydro power generation, and tidal power generation have advantages of relatively high power generation efficiency. However, after maintenance such as replacement due to mechanical failure, maintenance work should be carried out. In case of severe case, Sometimes it is necessary to discard. On the other hand, solar power can not ignore the influence of the weather, but if there is no mechanical operating element in the construction system, installing only the solar module and the related system can achieve stable generation over a certain level without a large range of maintenance system There are advantages.

In the case of photovoltaic power generation, since the solar cell module can produce power only when it is irradiated with solar light, in order to allow the solar cell module to emit a sufficient amount of sunlight, the influence of the shadow created by the surrounding geographical environment or the spatial constraint is minimum It is necessary to secure a space as wide as possible. For this reason, in order to install the photovoltaic power generation facilities on the mainland, large spaces such as open spaces, open spaces, farmland and forests were preferred, and rooftops and street parking lots of some buildings were also noted.

However, as a typical technology of electric power production using natural energy, as the photovoltaic power generation has been established, a large number of photovoltaic power generation facilities such as farmland or forest land have been installed. As a result, friction with surrounding farmers and residents increases, And concerns about environmental pollution are expanding.

As a substitute for installing photovoltaic power generation equipment, there has been a great interest in the inner surface including lakes, reservoirs and dams. The solar power plant installed on the surface of the water is called a water-state power plant. The water-state power plant has the following advantages.

First, water-condition lighting power plants usually use some of the water surface of lakes, reservoirs and dams that have a large surface area, thus minimizing shadows caused by surrounding mountains, trees, and buildings.

Second, if a suitable method of minimizing the radiant heat supplied to the solar cell module is used, since the solar heat radiated from the water surface is smaller than the solar heat radiated from the ground surface of the land photovoltaic power plant, the temperature of the solar cell module can be kept lower More output can be obtained from the solar cell module.

Third, if the solar zenith angle is large, the albedo of the water surface increases. That is, the amount of solar energy reflected on the surface of the water is great in the morning or evening when the solar altitude is low. Therefore, in the morning or evening, when the direct sunlight is low, the water-based photovoltaic power generation is more advantageous than the land photovoltaic power generation.

On the other hand, there are many disadvantages that must be solved because the water-based power plant is located on the water surface rather than on the ground.

First, a general land solar power plant consists of a solar cell module and a module installation structure, while the water-state power plant requires additional float in addition to these solar cell modules and structures. Solar cell modules and module mounting structures all float above the surface of the water so that they will not be immersed in water. Floating bodies of adequate volume must be provided to provide sufficient buoyancy. Therefore, the larger the number of components of the water-state power plant, the larger the floater is required, and the higher the cost, the higher the cost.

Second, in a water-state power plant, a floating structure having a certain area is formed by connecting a plurality of floats, a structure for installing a solar cell module is connected to the floating structure, a solar cell module is connected to the structure, A plurality of components having respective functions are complexly connected, which complicates construction.

Third, in order to minimize the shadow effect between the solar modules when arranging the solar modules in the north-south direction in the solar power plant, the distance between the solar modules is kept constant in the north-south direction. This distance interval is closely related to the inclination angle of the solar module have. In order to increase the annual power generation amount in a land photovoltaic power generation plant, it is general to change the inclination angle of the solar cell module about two or three times depending on the seasons, after securing the distance in the north-south direction. As mentioned above, since the floating structure and floating structure are expensive to manufacture in the water-state power plant, the entire floating structure is formed in a certain size area. Therefore, in a water-state power plant, it is impossible to use the technology for changing the inclination angle of a solar cell module commonly used in a land photovoltaic power generation plant, or to use it in a very limited range.

Fourth, the materials used to fabricate the float of the water-state power plant are those with small specific gravity in order to generate large buoyancy, and the float is also produced in a form having an empty space in the interior. However, materials with a low specific gravity are generally weak in mechanical strength, and in many cases, they are vulnerable to ultraviolet rays because they are used in an environment where they are directly exposed to sunlight. If a floating body made of a material weak in mechanical strength or vulnerable to ultraviolet rays has an empty space in order to increase buoyancy, if water penetrates into empty space inside the float due to mechanical damage or chemical deformation or breakdown in the long term, The floating body has a disadvantage of increasing the possibility of losing its buoyancy.

Registered Patent No. 10-1493723 (issued on February 16, 2015) Registered Utility Model No. 20-0464027 (Notice of December 06, 2012) Registered Patent No. 10-0830891 (published on May 22, 2008)

In order to solve the above-mentioned problems, the present invention provides a solar cell module in which a plurality of float fluids are connected, and a solar cell module is installed on water, which is an empty space between a plurality of fluids, So that it is possible to perform stable power generation with efficiency.

Another object of the present invention is to provide a floating body which can perform buoyancy generating function, fixing function of a structure for mounting a solar cell module, working space for maintenance of a solar power generating device, and shadow effect avoidance space function between solar cell module arrays Thereby minimizing components of the water-state light-electricity generating device.

Another object of the present invention is to provide a method for manufacturing a float, wherein the base of the float is formed of a lightweight plate made of a material that does not dissolve in water and has a foamed styrofoam inside thereof, Is to make a cap with a hard concrete material so that it can maintain its function stably over a long period of time without being damaged, deformed or denatured, against mechanical impacts or photochemical hazards externally applied.

It is still another object of the present invention to provide a method of reinforcing concrete by replacing a reinforcing bar by binding a reinforcing material such as hot-dip galvanized wire, stainless steel, or carbon fiber to the inside of the concrete to increase the mechanical rigidity of concrete while preventing corrosion by water, So as to have a stable structure.

It is a further object of the present invention to minimize the shading of the solar cell module by changing the spacing between the floats in the north-south direction and to adjust the inclination angle of the solar cell module to the optimum inclination angle, .

It is a further object of the present invention to provide a solar cell module in which the upper part of the south solar cell modules and the lower part of the north solar cell modules are located in the floating fluid upper space existing between the floating fluid- And a reflector connected to the solar cell module is installed so that more sunlight energy is incident on the solar cell module, thereby increasing the output of the solar cell module.

It is a further object of the present invention to provide a hinge structure in a structure for supporting a float coupling material or a solar cell module so that a stable structure can be maintained even against fluctuation of a wave.

In order to accomplish the above object, the present invention provides a method of manufacturing a semiconductor device, comprising: a plurality of floats including a foam material; A solar cell module coupled to the plurality of float upper portions; And a solar cell module mounted on the float by the solar cell module mounting part for mounting the solar cell module on the upper surface of the solar cell module, And is located on the space between the floats.

In a preferred embodiment of the present invention, one side panel mounting portion supporting one side of one solar cell module is installed in one side fluid, and the other side mounting portion for supporting the other side of the solar cell module is installed in another side fluid. And a water-state power generation device.

In a preferred embodiment of the present invention, there is provided a fluid coupling member for connecting a plurality of the sub-fluids, wherein the fluid coupling member is rotatably coupled to both side fluid sides facing each other; Pivotally engaging the adjacent upper surface between the two side floats; A rotatably coupled to an underside of the battery plate mounting portion provided on both side fluids; And a combination so that both floaters do not flow; And the two side fluids are connected to each other by a combination of any one of them.

In a preferred embodiment of the present invention, a plurality of solar cell modules are installed between a plurality of floats, and further include a reflector installed between the plurality of solar cell modules in an inclined manner. do.

In a preferred embodiment of the present invention, the solar cell module includes: an electrode plate holder for fixing the solar cell module to the floating body; And a float connecting member for connecting the plurality of floatings, wherein the cell plate mounting portion includes a single vertical column fixed to the one side float; And a module support frame supporting the slant photovoltaic module, wherein the upper part of the single vertical column and the lower part of the inclined module support frame are fixed.

In a preferred embodiment of the present invention, the solar cell module includes: an electrode plate holder for fixing the solar cell module to the floating body; A module base frame rotatably coupled to upper surfaces of both side fluids and having a fluid coupling member for connecting the plurality of fluid fluids; A connection frame vertical post fixed to one side of the module base frame; And a floating connection module frame supporting the lower part of the solar cell module in an inclined state above the connection frame vertical column.

In a preferred embodiment of the present invention, the solar cell module includes: And a float connecting member for connecting the plurality of float flaps, wherein the flap panel mounting portion is fixed to the float connecting member.

In a preferred embodiment of the present invention, the battery plate mounting portion includes: a lower vertical column rotatably coupled to one side fluid; An upper column pivotally coupled to the other fluid; And an integral module frame which supports the lower part of the sloping solar cell module and whose inclined lower part is fixed to the lower vertical column and the inclined upper part is fixed to the upper column, and the lower vertical column, the upper column, And the solar cell module is installed while the two side fluids are connected to each other.

In a preferred embodiment of the present invention, the solar cell module includes: And an auxiliary fluid connecting member for connecting the two side fluids, wherein the battery panel mounting portion comprises: an anchor lower vertical column vertically installed on the connection rotating anchor for rotatably coupling the fluid inflow connecting member to both fluid side, and an anchor vertical Wherein the anchor lower vertical column is rotatably coupled to the lower side of the inclined solar cell module and is formed with a long groove in the back surface direction of the solar cell module, And a vertical column is rotatably coupled to the vertical column.

In a preferred embodiment of the present invention, the solar cell module includes: And a secondary fluid connecting member for connecting the secondary fluid to the secondary fluid connecting member, wherein the secondary battery mounting portion comprises two central vertical columns erected at the center of the two float connecting members; A horizontal column connecting two central vertical columns; A tilted tilting pivotal pivotally coupled to two of the horizontal pillar; And a rear pivotal portion rotatably coupled to the bottom of the inclined pivot and fixed to the float.

In a preferred embodiment of the present invention, the solar cell module is provided with a float connecting member for connecting two or more float fluids, and the lower part of the solar cell module provided on the space between the two float floats is fixed to the fluid on one side A long rod mounting structure in which a solar cell module is coupled to an inclined column erected on the fluid of the other side, and the inclination angle of the solar cell module is maintained at a predetermined angle; A spacing adjustable mounting arrangement capable of adjusting the spacing between the two subfluids connected by the float connecting member; And a tilt angle adjustment installation structure capable of adjusting the tilt angle of a solar cell module installed on both side fluid or fluid coupling members; The water-state photovoltaic generation apparatus according to claim 1,

According to the present invention configured as described above, a plurality of concrete part fluids are connected and connected, and a solar cell module is installed on water, which is an empty space between a plurality of connected concrete fluids, So that the temperature rise of the solar cell module during power generation can be suppressed.

The present invention provides a concrete floater with multiple functions such as a buoyancy generating function, a fixing function of a structure for installing a solar cell module, a work space for maintenance of a solar cell power generation device, and a shadow effect avoidance space function between solar cell module arrays, It is possible to minimize the components of the photovoltaic power generation device, thereby reducing the construction cost and the maintenance cost, and drastically shortening the construction time period.

The present invention is characterized in that the structure of the concrete partitions is divided into an upper part and a lower part, and the styrofoam base and the concrete cap are appropriately formed in accordance with the purpose and function of each part so as not to be damaged by external mechanical impact, The photochemical action that can be caused by exposure to ultraviolet rays for a long time is also effective in securing stability that is not deformed or denatured.

In addition, the present invention has the effect of increasing the mechanical stiffness of concrete while preventing corrosion caused by water by replacing the reinforcing steel which is likely to be corroded by moisture, and bonding the reinforcing material such as hot-dip galvanized wire, stainless steel or carbon fiber have.

In addition, the present invention minimizes shading of the solar cell module by changing the spacing between the concrete partitions and allows the inclination angle of the solar cell module to be kept optimal throughout the year, thereby increasing the generation amount during the year by 4 to 5% , The reflection plate connecting the upper part of the southern solar cell module and the lower part of the northern solar cell module can be installed in the space above the concrete part to increase the solar radiation amount by 10 ~ 15% during the year. As a result, .

In addition, the present invention has a hinge structure in a structure for supporting a concrete part fluid connection material or a solar cell module, so that it is possible to maintain a stable structure against external disturbances such as waves.

FIG. 1 is a view showing an embodiment in which a plurality of solar cell modules are installed between a plurality of concrete floats in the water-state photovoltaic generation apparatus according to the present invention.
FIG. 2 is a view illustrating a state in which a plurality of solar cell modules are separated upward from a plurality of concrete floats in the water-state photovoltaic power generation apparatus according to the present invention.
3 is a side view illustrating a state in which a plurality of solar cell modules are installed between a plurality of concrete floats in the water-state photovoltaic power generation apparatus according to the present invention.
4 is a flowchart illustrating a process of manufacturing a concrete part fluid of the water-state photovoltaic generation apparatus according to the present invention.
5 is a side cross-sectional view of a concrete part fluid of the water-state photovoltaic generation apparatus according to the present invention.
6 is a view illustrating a state in which a plurality of solar cell modules and reflection plates are installed between a plurality of concrete floats in the water-state photovoltaic generation apparatus according to the present invention.
7 is a side view illustrating a state in which a reflection plate inclined between a plurality of solar cell modules installed between a plurality of concrete floats in a water-state photovoltaic power generation apparatus according to the present invention is installed.
8 is a side view illustrating a state in which a plurality of concrete part fluids are connected by connecting the anchors for mounting solar cell modules in the water-state photovoltaic power generating device according to the present invention.
FIG. 9 is a side view of a state in which the water-state photovoltaic power generator according to the present invention is rotatably connected to the side surfaces of a plurality of concrete part fluids.
10 is a side view illustrating a state where a plurality of concrete floats are connected to a side of a plurality of concrete floors by a float connecting member and the plurality of concrete floats are bound so as not to be rotated in the water-state photovoltaic power generating apparatus according to the present invention.
FIG. 11 is a view illustrating an example of a side supporting embodiment in which a solar cell module is fixedly installed from one concrete part fluid among a plurality of concrete part fluids in the water-state photovoltaic power generation apparatus according to the present invention.
12 is a view illustrating an example of fastening a connecting frame on one side of a solar cell module in a vertical column on a module base frame connected to upper portions of two side concrete floors in the water-state photovoltaic power generating apparatus according to the present invention. to be.
13 is a view illustrating an embodiment of a re-installation of a float connection part in which a solar cell module is fixedly installed on a float connecting member connecting two-side concrete part fluids in the water-state photovoltaic power generating device according to the present invention.
FIG. 14 is a perspective view of a water-based photovoltaic power generating apparatus according to an embodiment of the present invention. FIG. 14 is a perspective view of a solar cell module according to a second embodiment of the present invention. .
FIG. 15 is a view illustrating a connection anchor supporting embodiment for supporting a solar cell module in an anchor for rotatably connecting a fluid of a concrete body and a float coupling member in a water-state bi-electric power generating apparatus according to the present invention.
16 is a vertical sectional view of a water-state photovoltaic power generating apparatus according to the present invention, in which a vertical column is erected upright at the center of a float connecting member for connecting between two side concrete part fluids, Fig. 8 is an example of fastening to a column installation example.
17 is a perspective view of a water-state photovoltaic power generating apparatus according to the present invention, in which a vertical column is erected upright at the center of a float connecting member for connecting between two side concrete part fluids, and a vertical vertical Fig. 8 is an illustration showing an assembly state of each frame or column in the column installation example. Fig.
18 is a view illustrating an embodiment of a long-rod connection in which a plurality of concrete part fluids are connected to a long-length long-length fluid connection member in the water-state photovoltaic power generation apparatus according to the present invention.
19 is a schematic view showing a state in which a solar cell module is installed in a float connecting member in which a fluid of both sides of a concrete is connected in a water-state photovoltaic power generating apparatus according to the present invention, and a solar cell module is tilted to a mild slope Fig.
FIG. 20 is a schematic view illustrating a state in which a solar cell module is installed in a float connecting member in which a fluid of both sides of a concrete is connected in the water-state photovoltaic power generating apparatus according to the present invention, Fig.
21 is a perspective view of a water-state photovoltaic power generating apparatus according to an embodiment of the present invention, in which a solar cell module is installed in a float connecting member connecting two side concrete floors and an inclination angle adjusting device for adjusting a tilt angle of the solar cell module, FIG. 8 is a view showing an embodiment of a summer use state for a tilted state with a mild slope;
22 is a perspective view of a solar cell module according to another embodiment of the present invention; FIG. 22 is a perspective view of the solar cell module of FIG. Fig. 8 is a view showing an embodiment of a winter condition in which a tilt angle is raised; Fig.

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

That is, the water-state photovoltaic power generation apparatus according to the present invention is related to a water-state photovoltaic power generation apparatus 20 that is provided with water, such as a lake, a reservoir, a dam, etc.,

In particular, the water-state photovoltaic power generation device 20 comprises a plurality of float floating on the water to be installed in the water phase, and a solar cell module 21 installed on the float.

The water-state photovoltaic device of the prior art is composed of a floating structure for floating function, a steel structure for installing a solar cell module, a structure for providing a worker passage for facility maintenance and maintenance, and a solar cell module on the upper part of the float However, in the present invention, the structure of the water-state photovoltaic power generation apparatus is simplified by merely providing the float with a multifunctional function and coupling the float and the solar cell module.

That is, as in the example of the accompanying drawings, a plurality of floats are provided, and the solar cell module 21 coupled with the upper portion of the plurality of floats is provided, thus completing the water installation of the water-state photovoltaic generation device.

The solar cell module 21 is stably fixed by providing the solar cell module 21 with the solar cell module mount portion 22 for fixing the solar cell module 21 to the float.

In addition, the upper surface of the float is provided with a mounting anchor (38) embedded for fixing the solar cell mounting part (22). Particularly, the solar cell module (21) installed in the auxiliary fluid by the solar cell mounting part (22) And is located on the space between the fluids.

In addition, in the case of the float according to the present invention, since it must be used always in an environment where it is always floating on the water, but is always fluctuated by waves and waves, it should have durability against mechanical impact. A preferred structure for this purpose will be described with reference to the accompanying drawings as follows.

That is, the float is composed of a floating upper layer 31 to which the water-state photovoltaic device 20 is coupled at an upper portion, and a floating lower base 32 which is located at the bottom of the floating upper layer 31 and forms a floating body of water .

Thus, the floating lower base 32 is a solid outer wall body of the floating lower base 32, with the buoyancy body portion 33 having an open top and a hollow shape. The buoyant body portion 33 encloses the lower surface of the float and the lower surface of the float to protect the buoyant body from external waves or waves. It also prevents corrosion and erosion by water. The buoyancy container body portion 33 may be formed of a low density polyethylene sheet or may be coated with low density polyethylene.

And a base foaming portion 34 located inside the buoyancy accommodating portion 33 and made of a foamed material such as expanded polystyrene. That is, the base foam 34, which is a footing material, fills the inside of the buoyancy container body 33.

The floating upper layer portion 31 includes a plurality of foam reinforcing portions 35 located on the base foam portion 34 and made of foamed material such as expanded polystyrene.

Particularly, in the water-state photovoltaic power generating apparatus according to the present invention, the flocculant is provided with the concrete float 30 as a structure in which the upper and outer surfaces are made of concrete and the foam material is wrapped inside and below. Thus, the foam material floats well on the water phase, and the concrete material forms a hard outer surface, thereby facilitating the installation of the facility. One concrete embodiment of the concrete float 30 includes a concrete cap 36 which surrounds a plurality of foam reinforcement portions 35 and the outside of the foam reinforcement portions 35, The concrete cap 36 covers the space between the plurality of foam reinforcement parts 35 and thus has a solid state as a whole. Hereinafter, the float is described as a concrete floater, and floating bodies of various other materials may be applied.

The concrete cap (36) is made of a concrete material to prevent the internal foam materials from being eroded or damaged by water, and the thermal deformation of the float due to the sunlight, particularly the deformation or deformation of the float due to ultraviolet rays, . When the coupling rods (coupling rods) (not shown) are provided to be fixed to the inside of the concrete by providing the coupling rods (coupling rods) on the buoyant coupling body portions 33 of the lower floating base 32 below, Tightly tightened between the upper floating base 36 and the lower floating base 32.

The concrete cap 36 made of a concrete material is a constituent of the reinforcing bars (coupling roots) inside the concrete cap 36. The reinforced concrete rope 36 covers the space between the plurality of foam reinforcing portions 35 and the outside of the foam reinforcing portion 35, The reinforcing material for concrete 37 is provided together with the concrete material.

The concrete reinforcing material 37 may be a hot-dip galvanized wire mesh; Stainless steel rebars made of stainless steel rods; Carbon fiber rebars made of carbon fibers; A carbon fiber frame in which carbon fiber tape is woven horizontally and vertically; And glass fiber. Or some of them may be put in a mixed state with each other, and so on.

The concrete reinforcing member 37 and the like included in the concrete cap 36 formed by the concrete casting 36 and the concrete casting 36 as shown in FIGS. 4 and 5 and the like are formed by a plurality of foam reinforcing portions 35 The entire outer portion and the upper portion are wrapped to protect the foaming reinforcement 35, which is a foaming material, from damage.

In addition, the concrete cap 36 and the reinforcing material 37 for concrete are also connected between the plurality of foam reinforcing portions 35, so that the plurality of foam reinforcing portions 35 are more tightened. The concrete cap 36 includes a concrete gap column portion 361 connected to the upper portion of the concrete cap 36 and extended to a gap between a plurality of foam reinforcing portions 35, Also includes a gap reinforcing portion 371 which is included in the concrete gap column portion 361 extended to the gap between the plurality of foam reinforcing portions 35 and installed more firmly.

Whereby the plurality of foam reinforcing portions 35 and the concrete caps 36 are more firmly coupled.

Particularly, before the pouring, the gap reinforcement portion 371 connected to the upper portion of the concrete reinforcing material 37 forms a mold of the mold, while the concrete clearance pillar portion 361 after the concrete is cured and cured forms a plurality of foam reinforcement portions 35, So that even when various facilities are installed on the concrete cap 36, the concrete pillar 361 supports the concrete pillar 361 to support the load of the pillar, .

The concrete cap 36 is securely protected while the plurality of foam reinforcing portions 35 are firmly protected by the concrete clearance pillar portion 361 and the clearance reinforcing portion 371 provided in the gap between the plurality of foam reinforcing portions 35. [ A plurality of foam reinforcing portions 35, and further a base foam portion 34 forming a large area.

The water-state photovoltaic apparatus 20 according to the present invention is provided with the integral concrete float 30 for flooding on the water while the solar cell module 21 is installed. The concrete float 30, A foamed material such as foamed polystyrene is used to obtain buoyancy, and a low density polyethylene plate is covered on the lower surface of the foamed material to constitute the buoyancy container body portion 33. [ The side surface and the upper surface are covered with a concrete material so as to be entirely rigid.

In this case, it is possible to mix concrete with glass fiber, or to place a carbon fiber tape in place of reinforcing steel at a predetermined position in the concrete, or to construct a concrete facility including a galvanizing material such as a hot-dip galvanized wire mesh will be.

As described above, the concrete float 30 of the present invention is formed by enclosing the side surface and the upper surface of the foamed polystyrene on the upper side together with the foamed material on the lower side of the concrete to cover the concrete, thereby improving the mechanical durability of the concrete float It accomplishes.

In addition, before the concrete is poured, the fixing material is previously installed at a predetermined position in the inside of the concrete cover on the side surface and the upper surface, and when the concrete is laid, these fixing materials are located inside the concrete and have a more solid state.

Further, after the poured concrete is cured, the fixing materials partially embedded in the concrete are connected to the metal structure for fixing the solar cell module 21 installed on the upper side, ). ≪ / RTI >

Such a concrete float 30 is used as a foundation for a structure for a water-state photovoltaic power generation device (for example, a connection panel or an inverter) and is used as an installation base for a metal structure for mounting a solar cell module 21, It can also be used as a means of connecting concrete floors by connecting metallic structures for mounting of multiple concrete floors together.

The main characteristic elements of the concrete float 30 for the water-state power generation device for this purpose are foamed materials such as foamed polystyrene which generates a large buoyancy due to its specific gravity smaller than that of water, In order to prevent breakage, separation, etc., the concrete is wrapped with a sheet of low-density polyethylene as an outer body, and the upper side or side of the upper side is covered with concrete with little deformation or damage to ensure mechanical stiffness and chemical stability .

This serves not only as a buoyancy generating body but also as an installation base for the mounting structure of the solar cell module 21 of the water-state photovoltaic power generation apparatus. At the same time, the concrete float 30 can be used as a maintenance passage of the water-state power generation device 20 or as a foundation of a small scale device.

The foamed body portion 33 is provided as a low-density polyethylene material plate to enclose the base foamed portion 34 made of the foamed material below the concrete float 30 to protect the foamed foamed portion 34 against external force, Of the foamed material is prevented from being split into small pieces and released.

In this way, the concrete float 30 is pushed downward into the buoyancy accommodating portion 33 so as to cover the outer and upper portions of the foamed reinforced portion 35 made of a small foamed material as the base foamed portion 34 of the foamed material FIG. 5 shows a construction of a concrete cap 36 made of a cured concrete material, and FIG. 4 is a view showing an example of a process of manufacturing such a concrete float.

As described above, the concrete cap 36 made of a concrete material having a rigid structure on the upper side is not used as a usual general method for reinforcing the tensile strength of concrete. In the case of ordinary reinforcing weave, since the reinforcing bars can easily be corroded by water, various methods have been applied to avoid the corrosion of the reinforcing bars by moisture.

In other words, it is used as concrete reinforcement (37), which is reinforcing rod (reinforcement member) of concrete, and is used as rebar reinforcement in reinforced concrete by using hot-dip galvanized wire mesh.

In addition, stainless steel rebar, carbon fiber rebar, etc. can be used as reinforcing material for reinforced concrete in the concrete.

In the case of the concrete reinforcement material (37), which is a reinforcement rope made of stainless steel or carbon fiber rope, a plurality of reinforcing rods such as stainless steel rods or carbon fiber ropes are connected to each other to form a single large structure. do.

Or reinforcing material 37 may be provided by forming a net-like frame in the form of a weave of carbon fiber tape horizontally and vertically in the concrete by a reinforcing material 37 for concrete as a reinforcement rod in concrete. In other words, it is made of carbon fiber tape to weave like a net.

 In addition, it is possible to achieve an embodiment in which glass fibers are mixed with concrete as reinforcing bars of the concrete reinforcing material 37 of another embodiment to enhance the rigidity of the concrete itself.

As described above, the concrete float 30 according to the present invention can float on the water phase while fixing the solar cell module 21 to the upper side, and consequently, the concrete float 30 is formed of a light foamed material And the upper part is made of a hard material so that various facilities such as a solar cell module can be easily installed and the outer wall is made of a concrete material to protect the inner foam material from external forces such as waves .

An example of the process of manufacturing the concrete float 30 will be described with reference to FIG.

The buoyant body portion 33 is provided with a buoyant body portion 33 having a box shape in which the lower and the four sides are closed and the upper portion is opened with the floating lower base 32 corresponding to the lower portion of the concrete float 30, May be made of a low-density polyethylene material.

The base foaming portion 34, which is a foamed material such as expanded polystyrene, is formed in the buoyancy accommodating portion 33 by a predetermined method.

Next, the foam reinforcement 35, which is a foamed material such as a plurality of foamed polystyrene, is placed on the floating lower base 32 such as the buoyant body portion 33 and the base foam portion 34, 35 and a reinforcing member 37 for reinforcing concrete so as to surround the outside and the upper side. Such reinforcing material for concrete (37) replaces the reinforcing steel and is contained in the concrete to be cured, thereby strengthening the entire concrete.

In this state, the concrete mold 36 is provided after placing the mold 39 that surrounds the plurality of foam reinforcing portions 35 and the concrete reinforcing member 37. To fix the solar cell module module 21 as a column supporting the solar cell module module 21 or to fix the float connecting member 40 for connecting the plural concrete floats 30 A plurality of anchors including the anchors 38 are previously bound to the concrete reinforcement 37 or placed in a predetermined position before the concrete is poured to pour the concrete.

Thus, after the concrete is laid, many anchors such as anchoring anchor are integrally fixed with the concrete and concrete float 30, and then the solar cell module is installed or other concrete components are connected by easily fastening the other members.

After the concrete is poured, the mold is removed to complete the manufacture of the concrete float 30.

When a plurality of concrete floors 30 manufactured as described above are manufactured, and a plurality of concrete floors 30 are connected, when a solar cell module 21 is installed on the concrete floors 30, .

The concrete float 30 of the water-state photovoltaic apparatus 20 according to the present invention is provided with the photovoltaic module 21 for the photovoltaic power generation between the connections of the plurality of concrete floors 30 The float bottom portion 32, which is the base of the lower portion of the water surface, forms the buoyant body portion 33 with the outer shell of a light and hard material. And a base foaming portion 34, which is a foaming member, is provided in the interior surrounded by the buoyancy hermetically-sealed portion 33 and coupled.

The floating upper layer portion 31 on the upper side coupled with the floating lower base 32 is made of a material such as stainless steel rods such as hot-dip galvanized wire or stainless steel pipe, carbon fiber rods made of carbon fiber rods, And a concrete cap 36 as a structure is formed. In addition, a concrete anchor 38, which is a fixing means for installing the solar cell module 21, is embedded in the concrete cap 36 and fixed to the concrete, and includes a conduit for transmitting other signals or electric power.

As described above, the concrete float 30 according to the present invention is shown as an embodiment of the float of the water-state photovoltaic power generating apparatus, which is a photovoltaic power generation facility, as a preferred embodiment, It is possible to apply the present invention to other structures such as structures, barges, and the like. That is, the upper part is made of a hard concrete material and the lower part is made of a foaming material to float, which is advantageous in that it can achieve a stable structure even when various facilities are installed while supporting a heavy load.

As a method of connecting a plurality of concrete floors 30 as described below, it is possible to connect the concrete floors 30 with a separate float connecting member 40, or to connect a plurality of concrete floors 30 when the waves are gentle The concrete partitions are fixedly coupled.

Or to connect a plurality of concrete floors with members for fixing the solar cell module.

1 to 3 and the like, a plurality of concrete floats 30 are rotatably connected to two float connecting members 40 respectively, and solar cell modules 21 are mounted on water, which is an empty space between concrete floats, So that the entire water-state photovoltaic power generation device 20 is provided.

The solar cell module 21 is installed to be inclined at a predetermined angle toward the sun, and a short column on one side is fixed to one concrete fluid and a long column on the other side is fixed to the other concrete fluid, The solar cell module 21 is inclined. In addition, since the float connecting member 40 connecting the concrete floats is rotated with the concrete floats, the stable binding state can be maintained even if the individual concrete floors flow by the waves.

In addition, the float connecting member 40 is pivotally connected to the concrete floats, and the upper part of each column and the rear frame of the solar cell module 21 are also rotated to maintain a stable fastening state even if there is flow due to waves .

In the water-state photovoltaic apparatus 20 according to the present invention thus constructed, a plurality of concrete floors 30 are connected to each other by a float connecting member 40, and water between the plurality of concrete floors 30 The solar cell module 21 is installed such that the sun is mainly positioned to face south which is suitable for power generation efficiency.

As a result, a large number of concrete floors 30 maintaining a distance in the north-south direction and solar cell modules 21 installed on the water surface between the concrete floors are alternately arranged. In particular, the solar cell module 21 installed between the floats allows the module tilt angle to be changed so as to be adjusted to the sun altitude which is changed by the season. In addition, by adjusting the distance between the concrete floors 30, it is possible to change the distance in the north-south direction of the solar cell module 21, thereby maximizing power generation efficiency without shadows.

In addition, by providing a hinge structure at the middle or both ends of the connecting member for connecting the concrete inflows 30 or the installation structure of the solar cell module 21, a stable installation structure can be maintained even if there is fluctuation due to waves.

The water-state photovoltaic apparatus 20 according to the present invention will now be described in detail.

That is, a plurality of concrete floors 30 as described above are provided, and a solar cell module 21 coupled to the plurality of concrete floors 30 is installed.

And an electrode plate mounting portion 22 for fixing the solar cell module 21 to the concrete float 30.

The upper surface of the concrete float 30 is provided with a mounting anchor 38 embedded in order to fix the cell plate mounting portion 22. The solar cell 30 mounted on the concrete float 30 by the solar cell mounting portion 22, The module 21 is provided so as to be placed on the water as a space between the plural concrete part fluids.

1 to 3, one side panel mounting part 22 for supporting one side of one solar cell module 21 is installed on one side of the concrete part fluid 30, and the solar cell module 21 The other side panel plate mounting portion 22 'supporting the other side is installed in the other concrete float 30'.

As described above, there is provided a float connecting member 40 for connecting a plurality of concrete floors 30, and the float connecting member 40 can be used to connect the concrete floors 30, Thereby connecting the fluids.

FIG. 9 is a side view showing a side view of a state in which a plurality of concrete part fluids are rotatably connected to a side surface of a water-state photovoltaic power generating apparatus according to the present invention, wherein both side concrete portions 30 and 30 ' And is rotatably coupled to the side surface.

And is rotatably coupled to a close-up upper surface between the both-side concrete floors 30 and 30 '.

And FIG. 8 is a side view illustrating a state in which a plurality of concrete part fluids are connected by connecting the anchors for mounting a solar cell module in the water-state photovoltaic power generating device according to the present invention. That is, below the battery plate mounting portions 22 and 22 'provided on the two side concrete floors 30 and 30'.

10 is a perspective view of a water-state photovoltaic power generating apparatus according to an embodiment of the present invention.

The water-state photovoltaic device 20 according to the present invention is provided with the anchoring anchor 38, which is an anchor bolt for assembling the solar cell module 21, to the upper portion of the concrete 30, So that the mounting structure such as the solar cell module mounting portion 22 of the solar cell module 21 can be easily installed on the upper surface of the concrete float 30.

The concrete float 30 directly performs the function of the foundation of the mounting structure of the solar cell module 21 to connect the concrete floors 30 and the mounting structure of the solar cell module 21 So that no separate structure is required.

Alternatively, a structure for mounting the solar cell module 21 may be installed between the concrete float 30 and the concrete part fluid as an embodiment, and structures for mounting the solar cell module 21 may stably support the solar cell module 21 But also serves as a connecting material for connecting the concrete floors to each other.

In addition, since the pivoting members of the hinge structure are provided at both ends of the structure for mounting the solar cell module 21 between the concrete part fluid and the concrete part fluid, the concrete part fluids can move up and down by the waves, So that they can move freely.

In addition, by eliminating the external force that may occur between the concrete floats which move in different directions in the vertical direction, it is possible to prevent deformation and breakage of the concrete floors or the mounting structure of the solar cell module.

According to an embodiment of the present invention, a fixing bolt may be embedded in a concrete side surface or an upper surface portion of the concrete part fluid, the two side concrete part fluids may be connected, and a mounting structure for fixing the solar cell module 21 may be separately provided .

In one embodiment, instead of the structure for mounting the solar cell module, the concrete column that performs the solar cell module mounting function may be integrated with the concrete body fluid.

Accordingly, in the present invention, it is possible to embed signal lines such as ELP conduits, power lines, and the like in concrete in the longitudinal direction and the width direction, thereby securing an electrical connection path of the solar cell module arrays. Other wires may be wired or connected in various ways.

6 to 7, a plurality of solar cell modules 21 are installed between a plurality of concrete floors 30 and a reflector 50 installed between the plurality of solar cell modules 21 in an inclined manner, . As a result, sunlight is concentrated on the solar cell module 21 by the reflector 50, thereby improving power generation efficiency. Particularly, the reflector 50 according to the present invention may use the registered patent 10-1502084 registered by the present applicant.

As described above, in the water-state photovoltaic apparatus 20 according to the present invention, a plurality of concrete floors 30 are connected and the solar cell module 21 is installed on the water between the plurality of concrete floors 30 , And a reflector 50 is provided between the solar cell modules 21 installed to face the south direction. The reflector 50 is disposed between the upper part of the solar cell module installed on the south side of the reflection plate 50 and the lower part of the solar cell module installed on the north side A larger amount of light is concentrated on the solar cell module 21. In this case,

Next, as shown in FIGS. 11 to 19 and the like, various embodiments in which a plurality of concrete floors 30 and a solar cell module 21 are connected and installed in the water-state photovoltaic device 20 according to the present invention will be described Let's look at it.

11, a solar cell module 21 is fixed to a concrete float 30 by a solar cell module mounting part 22; And a float connecting member 40 for connecting the plurality of concrete floats 30.

The solar cell module 21 includes a module support frame 22a2 having a single vertical column 22a1 fixed to the first concrete part fluid 30 and supporting the lower part of the solar cell module 21, will be.

As a result, the upper part of the single vertical column 22a1 and the lower part of the inclined module supporting frame 22a2 are fixed. As a result, the solar cell module 21 has a single short thick columnar shape And is supported by the battery plate mounting portion of the battery.

Of course, the two concrete sections are connected by the fluid connection member 40 between the two concrete partitions, and the solar cell module 21 is placed on the water in the empty space between the two concrete partitions, and the heat, which is heated by the solar heat, On the other hand, the influence of the cold water temperature can lead to the development in a temperature stabilized environment.

12, the one side supporting structure of the connection frame shown in FIG. 12 may include a solar cell module mounting structure for mounting the solar cell module 21 on the concrete float 30, (22); And a float connecting member 40 for connecting the plurality of concrete floats 30.

A connection frame vertical column 22b2 fixed to one side of the module base frame 22b1 and a floating connection module frame 22b3 supporting the lower part of the solar cell module 21 at an upper side of the connection frame vertical column 22b2 , One of the connecting frame vertical columns 22b2 is connected to the floating connection module frame 22b3 which is the rear frame of the solar cell module 21 and is finally fixed with a thick and short sturdy single pole.

In particular, in the example of FIG. 12, the module base frame 22b1 is rotatably coupled to the upper surfaces of the two-side concrete floors 30 and 30 '. The shape of the module base frame 22b1 is such that the connecting frame vertical column 22b2 on the upper side is properly configured to fix the solar cell module 21 while connecting the two side concrete floors 30 and 30 ' . Or it may be carried out to connect the two concrete floats with two separate long bars and raise the connecting frame vertical columns 22b2 above the bars.

13, the solar cell module 21 is mounted by the solar cell module mount portion 22, which may be composed of one or more columns. In this embodiment, (22); And a float connecting member 40 for connecting the plurality of concrete floatings 30. The battery plate mounting portion 22 is fixed to the float connecting member 40. [

Since the solar cell module 21 and the battery panel mounting portion 22 for fixing the solar cell module 21 are all provided on the float connecting member 40 connecting the two concrete portions of the fluid, Since there is an empty space in the upper part of the fluid in both sides of the concrete, it is possible to install a moving passage or other device on the upper part of the concrete part, and the space utilization becomes higher. In addition, unused concrete floors can be reduced in size and thus consumed less.

Next, according to one embodiment of the mounting suspension in Fig. 14, the structure for mounting the solar cell module 21 and the structure for connecting the two concrete part fluids are made as one member.

That is, the cell plate mounting portion 22 for supporting the solar cell module 21 includes a lower vertical column 22d1 rotatably coupled to the first concrete fluid 30 and a lower vertical column 22d1 rotatably coupled to the second concrete fluid 30 ' (30 ') by an upper column (22d2) coupled to the upper and lower concrete pillars (30, 30').

And a unit module frame 22d3 supporting the lower part of the inclined solar cell module 21 and having an inclined lower part fixed to the lower vertical column 22d1 and an inclined upper part fixed to the upper column 22d2 will be.

The lower vertical column 22d1 and the upper column 22d2 and the integral module frame 22d3 are integrally connected to each other so that the solar cell module 21 is supported while connecting the two side portions 30 and 30 ' Is installed.

Accordingly, it is not necessary to provide a member for connecting the separate concrete part fluids, thereby reducing the assembling process of the water-based photovoltaic device 20.

Next, referring to the connecting anchor supporting embodiment in Fig. 15, the solar cell module 21 includes an electrode plate mounting portion 22 for supporting the solar cell module 21; And a float connecting member 40 for connecting the both-side concrete floors 30 to each other.

The battery panel mounting part 22 rotatably couples the float coupling member 40 to the both side concrete floors 30 and is mounted upright on the coupling rotation anchor 22e1 fixed to the both side concrete floors 30, An anchor lower vertical column 22e2 and an anchor vertical column 22e3.

The anchor lower vertical column 22e2 is rotatably coupled to the lower side of the inclined solar cell module 21. [

In addition, the anchor-shaped vertical column 22e3 is rotatably coupled to an elongated frame 22e4 provided on the upper rear side of the solar cell module by forming a long groove in the rear direction of the solar cell module 21. [ Particularly, the upper part of the vertical column 22e3 on the anchor can be moved along the grooves of the grooved frame 22e4, thereby adjusting the inclination angle so as to match the height of the sun when the solar cell module 21 is installed for the first time, The solar cell module 21 can be easily adjusted in terms of the inclination.

Next, referring to the central vertical column mounting example shown in FIGS. 16 and 17, the solar cell module 21 includes an electrode plate mounting portion 22 for supporting the solar cell module 21; And a float connecting member 40 for connecting the both-side concrete floors 30 to each other.

The solar cell module 21 is a member for supporting the solar cell module 21. The solar cell module mounting portion 22 includes two central vertical columns 22f1 standing upright at the center of the two float coupling members 40, And a horizontal column 22f2 connecting the first and second electrodes 22f1 and 22f1.

The inclined rotating pillar 22f3 is rotatably coupled to two places of the horizontal pillar 22f2 and rotatably coupled to the lower portion of the inclined pivoting pillar 22f3, And a turning portion 22f4.

The horizontal column 22f2 and the inclined rotation column 22f3 are rotatably coupled and the inclined rotation columns 22f3 and the rear rotation portion 22f4 are rotatable so that the solar battery module can be rotated even if waves are generated. In addition, the inclination angle of the solar cell module can be adjusted by adjusting the distance between the horizontal column 22f2 and the inclined rotation column 22f3.

Next, FIGS. 18 to 20 show configurations in which the respective concrete part fluids are connected to each other by the float coupling member 40 so as not to be rotated with respect to each other without a hinge constitution different from that described above. In this case, a large number of concrete floats are formed as one large-sized concrete float group so that the solar cell module 21 can be installed over a wide area.

As an example without a hinge, a fluid-communicating member 40 for connecting concrete fluids as shown in FIG. 18 is formed to have a long shape and a plurality of concrete fluids are connected together. Then, a solar cell module is installed by allowing water to be seen between each concrete part fluid.

Alternatively, as shown in FIGS. 19 and 20, by providing the relatively short float connecting member 20 to couple the two concrete floats, the plurality of concrete floats can be individually connected to the float connecting members.

Hereinafter, the detailed configurations of the embodiments will be described.

That is, in the embodiment of FIGS. 18 to 20 and the like, there is provided a float connecting member 40 for connecting two or more concrete floors 30.

In the case of the long rod connection embodiment shown in FIG. 18, the plurality of concrete part fluids are connected to the long length float connecting member 40. The solar cell module 21 installed on the space between the two concrete partitions 30 is connected to the one side of the concrete part fluid 30 by the long rod mounting structure of the solar cell module mounting part 22 for fixing the solar cell module 21. [ 30, and inclined columns 22g1 erected on the other side of the concrete, and the solar cell module 21 is coupled to the upper part of the inclined column 22g1. Thus, the inclination angle of the solar cell module 21 is maintained to maintain a predetermined angle.

19 and 22, the two concrete fluids are connected by the fluid coupling member 40, and the gap between the two concrete fluids 30 connected by the fluid coupling member 40 is adjustable And the inclination angle of the solar cell module 21 may be adjusted by adjusting the inclination angle of the inclined angle of the solar cell module 21 installed on both the concrete floors 30 or the float connecting member 40. [

19, the solar cell module 21 is laid down with a gentle slope because the height of the sun is high in the summer. The upper part of the inclined solar cell module 21 tilts the inclined column 22g1 toward the fluid of the other side of the concrete part so that the lower part of the solar cell module 21 rotates to the one concrete part fluid, 21) is gentle.

In addition, in FIG. 19, it is shown that the gap between two concrete portions is reduced.

20, the two concrete sections are connected by the float connecting member 40, and the solar cell module 21 is further raised because the sun is floated in the winter season. Thus, the lower part of the solar cell module 21 is rotated by the fluid of the one concrete part, the inclined column 22g1 supporting the upper part of the inclined solar cell module 21 is further set up, State.

In addition, in FIG. 20, an example in which the interval between the two concrete portions is wide is shown.

21 and 22 illustrate an embodiment of a solar cell module inclination angle adjusting device constituted by an end frame, wherein Fig. 21 can be used in summer, Fig. . ≪ / RTI >

Therefore, it is possible to reduce the total number of concrete inflows, and in the environment where the waves are frequently swirling, the interval of the concrete inflows is narrowed to make the whole stable facility.

In spite of the inclination angle of the solar cell module, it is expected to increase the amount of power generation by minimizing the shadow effect by arranging the float with a wide gap in the season where the wave is calm. On the other hand, So that the entire facility is made stable.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The technical idea of the present invention should not be construed as being limited.

20: water-state power plant 21: solar cell module
22: battery plate mounting portion 30: concrete fluid
33: float body part 34: base foam part
35: foaming reinforcement 36: concrete cap
37: Stiffener for concrete 38: Anchoring anchor
40: float connecting member 50: reflector

Claims (11)

Multiple floats, including foamed material;
A solar cell module coupled to the plurality of float upper portions; And
And an electrode plate mounting part for fixing the solar cell module to the floating body,
Wherein the upper surface of the floating body has a mounting anchor embedded therein for fixing the mounting portion of the battery plate,
Wherein the solar cell module installed in the float by the cell plate mounting part is located in a space between the plurality of fluids.
The method according to claim 1,
Wherein one solar cell module mounting part for supporting one solar cell module is installed on one side of the solar cell module and another solar cell module mounting part for supporting the other side of the solar cell module is installed on another solar cell module.
The method according to claim 1,
And a float connecting member for connecting the plurality of floatings,
Wherein the float connecting member comprises:
Pivotally coupled to the side surfaces of the opposite side surfaces facing each other;
Pivotally engaging the adjacent upper surface between the two side floats;
A rotatably coupled to an underside of the battery plate mounting portion provided on both side fluids; And
So that both floats do not flow;
And the two side fluids are connected to each other by a combination of any one of them.
The method according to claim 1,
A plurality of solar cell modules are installed between the plurality of floats,
Further comprising a reflector that is installed obliquely between the plurality of solar cell modules.
The method according to claim 1,
An electrode plate mounting portion for fixing the solar cell module to the float; And
And a float connecting member for connecting the plurality of floatings,
The battery panel mounting part includes a single vertical column fixed to one side fluid; And
And a module supporting frame for supporting underneath the inclined solar cell module,
Wherein an upper portion of the single vertical column and a lower portion of the inclined module support frame are fixed.
The method according to claim 1,
An electrode plate mounting portion for fixing the solar cell module to the float; And
And a float connecting member for connecting the plurality of floatings,
A modular base frame rotatably coupled to the top surface of both side fluids;
A connection frame vertical post fixed to one side of the module base frame; And
And a floating connection module frame supporting the lower portion of the solar cell module at an upper side of the connection frame vertical column.
The method according to claim 1,
An electrode plate mounting part for supporting the solar cell module; And
And a float connecting member for connecting the plurality of floatings,
Wherein the battery plate mounting portion is fixedly installed on the float connecting member.
The method according to claim 1,
The above-
A lower vertical column rotatably coupled to the one-side fluid;
An upper column pivotally coupled to the other fluid; And
And an inclined lower portion that is fixed to the lower vertical column and an inclined upper portion is fixed to the upper column,
Wherein the solar cell module is installed while the lower vertical column, the upper column, and the integral module frame are integrally connected to each other and the two side fluids are connected to each other.
The method according to claim 1,
An electrode plate mounting part for supporting the solar cell module; And
And a float connecting member for connecting the two side fluids,
The battery panel mounting portion includes a lower anchoring column and an anchoring vertical column which are installed upright on a connection rotation anchor for rotatably coupling a float coupling member to both side fluids,
The anchor lower vertical column is rotatably coupled to the lower side of the inclined solar cell module,
Wherein an anchor vertical column is rotatably coupled to an elongated frame provided on an upper rear surface of the solar cell module by forming an elongated groove in the back surface direction of the solar cell module.
The method according to claim 1,
An electrode plate mounting part for supporting the solar cell module; And
And a float connecting member for connecting the two side fluids,
The above-
Two central vertical columns erected at the center of the two float coupling members;
A horizontal column connecting two central vertical columns;
A tilted tilting pivotal pivotally coupled to two of the horizontal pillar; And
And a rear pivotal portion rotatably coupled to the bottom of the inclined pivotal column and fixed to the float.
The method according to claim 1,
And a float connecting member for connecting two or more float fluids,
The solar cell module is fixed to the inclined post established on the fluid of one side and the lower part of the solar cell module installed on the space between the two float is fixed to one side fluid and the inclination angle of the solar cell module is maintained at a predetermined angle Installation configuration;
A spacing adjustable mounting arrangement capable of adjusting the spacing between the two subfluids connected by the float connecting member; And
A tilt angle adjustment installation structure capable of adjusting the tilt angle of a solar cell module installed on both side fluid or fluid coupling members;
Wherein the water-state photovoltaic power generation device is provided in any one of the installation configurations.

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