KR102319793B1 - Floating structure for solar power generating on water - Google Patents

Abstract

The present invention relates to a floating structure for solar power generation on water, capable of securing a water channel to transfer foreign substances floating on the water in at least one of the first and second directions in a floating structure in response to an arrangement direction of solar modules, and reducing algal blooms on the water where the floating structure is installed, while leading the foreign substances and the algal blooms to flow to the outside of the floating structure. To achieve the purpose, the floating structure for solar power generation on water includes: a main buoyant body installed on the surface of water while kept combined with a solar module, and having a main coupling part formed on an edge; a walking buoyant body installed on the surface of water such that a worker can move around the solar module, and having a walking coupling part; a connection assembly connecting two walking buoyant bodies adjacent to each other, while having a connection coupling part formed on an edge; a link assembly connecting two main buoyant bodies adjacent to each other while having a link coupling part formed on an edge; and a connection pin combining parts, in which at least two among the main coupling part, the walking coupling part, the connection coupling part and the link coupling part are overlapped, such that at least two, adjacent to each other, from the main buoyant body, the walking buoyant body, the connection assembly and the link assembly.

Description

Floating structure for floating solar power generation {FLOATING STRUCTURE FOR SOLAR POWER GENERATING ON WATER}

The present invention relates to a floating structure for floating photovoltaic power generation, and more specifically, foreign substances floating in water in at least one of the first direction and the second direction in the floating structure corresponding to the arrangement direction of the solar modules. It relates to a floating structure for floating photovoltaic power generation that secures a movable water passage and reduces the phenomenon of algae in water in which the floating structure is installed, while allowing foreign substances and algae to move to the outside of the floating structure.

In general, solar cells convert light energy of the sun into electrical energy. The smallest unit that generates power using the photoelectric effect is called a cell, and a photovoltaic module that generates power by connecting a plurality of cells in series or parallel is called a photovoltaic module.

A photovoltaic power plant (also called a photovoltaic power generation system) is an assembly of structures in which a plurality of photovoltaic modules are connected in series or in parallel.

These photovoltaic power plants are generally installed on land, which incurs huge site purchase costs and civil engineering costs, and destroys the environment because they are mainly used as a site by cutting down hills. In addition, when installed on land, in summer, the solar modules are heated by geothermal heat, so that the solar modules are not effectively cooled. Due to this, the power generation efficiency of the solar module is reduced.

In order to solve such a problem, a method for installing on the water surface of a lake, river, pond, dam, etc. has been developed. This floating photovoltaic power generation system is a power generation system using a plurality of floating structures for floating photovoltaic power generation in which a plurality of photovoltaic modules installed on the water surface together with a buoy are arranged.

These floating structures should be connected to each other in a solid state. The floating structure includes a photovoltaic module main buoyancy body floating on the water surface in a state where the photovoltaic module is fixed, and a walking buoyancy body installed on the water surface so that a worker can walk around the photovoltaic module.

The solar module main buoyancy body and the walking buoyancy body are connected to each other, and the walking buoyancy body and the walking buoyancy body are also connected to each other.

Therefore, it is possible to construct a floating photovoltaic power generation system in which a plurality of photovoltaic modules are disposed through the connection of the photovoltaic module main buoyancy body and the walking buoyancy body. Since some of the buoyancy bodies maintain a state submerged in water, water is confined in the inner space formed by the connected buoyancy bodies.

In this case, there is no flow path or passage through which the water in the floating structure can flow to the outside, so foreign substances floating on the water surface during summer floods or rainy seasons enter the power generation system and become trapped inside the power generation system. There is this stagnant problem.

In addition, when the floating matter flows into the space formed by the buoyant bodies during a summer flood, when the foreign material is attached to the solar module, it affects the power generation system of the solar module and there is a difficulty in reducing the energy production efficiency. .

In addition, the temperature of the photovoltaic module rises due to the solar power generation system in summer and the increase in ambient radiant heat transfers heat to the eutrophic substances (nitrogen components flowing in from fertilizer and livestock wastewater) mixed in the water of a reservoir or freshwater lake. As a result, a phenomenon of deepening of green algae in and around the power plant occurred.

On the other hand, in the prior art literature, a technique for smoothing the circulation of water in a floating structure has been disclosed. However, the rigidity of the connecting foot plate is weak in the water passage part for water circulation, which may cause damage to the connecting foot plate or damage to the coupling part.

Republic of Korea Patent Publication No. 10-2017295 (Title of the invention: floating structure for floating solar power generation, 2019. 09. 02. Announcement)

It is an object of the present invention to solve the problems of the prior art, and a water passage through which foreign substances floating in water can move in at least one of the first and second directions in the floating structure corresponding to the arrangement direction of the solar modules. It is to provide a floating structure for floating photovoltaic power generation that secures and reduces the phenomenon of algae in the water in which the floating structure is installed, while allowing foreign substances and algae to move to the outside of the floating structure.

According to a preferred embodiment for achieving the above object of the present invention, the floating structure for floating photovoltaic power generation according to the present invention is installed on the water surface in a state in which the solar module is coupled, and the main buoyancy body with the main fastening part formed on the edge ; a walking buoyant body installed on the water surface so that a worker can walk around the solar module and formed with a walking fastening part; a connecting assembly connecting two adjacent walking buoyancy bodies, and having a connecting fastening part formed at an edge thereof; a link assembly connecting two adjacent main buoyancy bodies, the link fastening part being formed at the edge; and two or more of the main fastening part, the walking fastening part, the connecting fastening part, and the link fastening part overlap so that at least two adjacent ones of the main buoyancy body, the walking buoyancy body, the connection assembly and the link assembly are coupled to each other. Including; a connecting pin for coupling the part, the main buoyancy body and the walking buoyancy body have buoyancy and the rest protrude above the water surface in a state where some are immersed in the water surface, and the link between the two adjacent main buoyancy bodies A portion in which the assembly is disposed, a water passage through which water and foreign substances can pass at the water surface; is provided.

Here, based on the planar state, the long side of the walking buoyancy body except for the walking fastening part is formed larger than the short side of the main buoyant body except for the main fastening part, so that the walking buoyant body is formed to protrude from the side of the main buoyant body, The walking fastening unit may include: a first walking fastening part formed on the long side edge of the walking buoyant body for coupling with the main fastening part; and a second fastening part for walking that is spaced apart from the first fastening part of the walk and formed on the edge of the walking buoyant body for coupling with the fastening part of the walk.

Here, the link assembly includes a link body disposed between the two main fastening parts facing each other, and at both edges of the link body, the link fastening parts are provided for coupling with a pair of the main fastening parts facing each other. formed main link; and a link module including a module body elongated between two opposite main buoyancy bodies, wherein the link coupling parts are formed on both edges of the module body for coupling with two or more pairs of mutually facing main fastening parts; includes any one of

Here, the water passage is formed between the link assembly and the water surface as the link assembly is spaced apart from the water surface.

Here, the water passage is formed on the upper side of the link assembly as the link assembly is immersed under the water surface.

Here, the water passage is further provided in at least one of the lower portion of the main buoyancy body and the portion where the connection assembly is disposed between the two adjacent walking buoyancy bodies.

Here, the connecting assembly may include: a connecting buoyancy body having a block shape and formed with the connecting fastening part on the edge for coupling with the walking fastening part; and a connecting panel having a panel shape and formed with the connecting fastening part at an edge for coupling with the walking fastening part; includes any one of

Here, the water passage is formed between the connection assembly and the water surface as the connection assembly is spaced apart from the water surface.

Here, the water passage is formed on the upper side of the connection assembly as the connection assembly is immersed under the water surface.

Here, the main buoyancy body, the main body installed on the water surface; and a main wing extending from the upper end of the main body so that the water passage is formed in the lower portion, wherein the main body is installed on the water surface with buoyancy, and the first main buoyancy part is provided with the main fastening part at the edge ; and a second main buoyancy part that is spaced apart from the first main buoyancy part and installed on the water surface with buoyancy, the second main buoyancy part having the main fastening part on the edge, wherein the main wing includes the water passage in the lower part. and a main wing buoyancy unit integrally connecting the upper end of the first main buoyancy and the upper end of the second main buoyancy.

Here, the main buoyancy body, the main body installed on the water surface; and a main wing extending from the upper end of the main body so that the water passage is formed in the lower portion, wherein the main body includes a main buoyancy unit installed on the water surface with buoyancy, and the main wing is a lower a first main wing buoyancy unit extending from an upper end of one side of the main buoyancy unit so that the water passage is formed in the water passage and having the main fastening unit at the edge; and a second main wing buoyancy unit extending from the upper end of the other side of the main buoyancy unit so that the water passage is formed in the lower portion and having the main fastening unit at the edge.

Here, the main buoyancy body, the main body installed on the water surface; and a main wing extending from the upper end of the main body so that the water passage is formed in the lower portion, wherein the water passage is formed on the upper side of the main wing as the main wing is immersed under the water surface.

According to the floating structure for floating photovoltaic power generation according to the present invention, a water passage through which foreign substances floating in the water can move in at least one of the first direction and the second direction in the floating structure in response to the arrangement direction of the solar modules , while reducing the phenomenon of algae in the water in which the floating structure is installed, foreign substances and algae can move to the outside of the floating structure.

In addition, the present invention can prevent foreign substances from stagnation in the floating structure to minimize the attachment of foreign substances to the solar module, and increase the energy production efficiency of the solar module.

In addition, the present invention suppresses the occurrence of algae in the vicinity of the floating structure, thereby preventing damage to the floating solar power generation system due to the algae, damage to the floating structure, and contamination of the water in which the floating structure is installed.

In addition, the present invention can improve the durability and strength of the floating structure through the connecting pin, and prevent the connecting pin from being damaged by an external force in advance.

In addition, the present invention can maintain a more solid state in the floating structure in the water, it is possible to maintain and safety management of the floating solar power system and floating structure.

In addition, the present invention secures a water passage between the two main buoyancy bodies that are continuously coupled through the detailed coupling relationship of the link assembly and the floating structure, so that water and foreign substances pass stably.

In addition, the present invention improves the floating stability of the floating structure while dispersing the load of the solar module and the floating structure by maximizing the contact area between the floating structure and the water surface through the detailed configuration of the main buoyancy body and the walking buoyancy body, and the main buoyancy body Alternatively, it is possible to prevent a decrease in the strength of the connection assembly.

In addition, the present invention secures a water passage in a part of the main buoyancy body through the detailed configuration of the main buoyancy body so that water and foreign substances pass through it stably.

In addition, the present invention secures a water passage through the detailed configuration of the connection assembly so that water and foreign substances pass stably.

In addition, the present invention is when the floating structure is installed on the water surface in designing the main buoyancy body and the walking buoyancy body and the connection assembly through the thickness calculation formula of the main buoyancy body and the thickness calculation formula of the connection assembly, the main buoyancy body and the walking buoyancy body It is possible to prevent a decrease in buoyancy and form a stable water passage in a part of the main buoyancy body or in a portion where the connection assembly is disposed between the walking buoyancy body.

In addition, the present invention prevents the flow between the main buoyancy body and the walking buoyancy body and the connection assembly based on the plane through the detailed coupling relationship between the main buoyancy body and the walking buoyancy body and the detailed coupling relationship between the walking buoyancy body and the connecting assembly On the other hand, it is possible to keep the separation distance between the main buoyancy body constant.

In addition, the present invention forms only a movement path of water and foreign substances when the water passage is disposed between the adjacent main buoyancy body or a part of the main buoyancy body or the lower part of the connection assembly, but the link assembly or part of the main buoyancy body or the connection assembly As the water passage is immersed below the surface of the water, the water passage can form a movement path for water and foreign substances, while preventing the spread of fire between two adjacent floating buoyancy bodies.

1 is a first side view showing a floating structure for floating photovoltaic power generation according to a first embodiment of the present invention.
2 is a plan view showing a floating structure for floating photovoltaic power generation according to a first embodiment of the present invention.
3 is a second side view showing a floating structure for floating photovoltaic power generation according to a first embodiment of the present invention.
Figure 4 is a view showing the coupling state of the main link and the adjacent main buoyancy in the floating structure for floating photovoltaic power generation according to the first embodiment of the present invention.
5 is a view showing the main link in the floating structure for floating photovoltaic power generation according to the first embodiment of the present invention.
6 is a view showing a walking buoyancy body in the floating structure for floating photovoltaic power generation according to the first embodiment of the present invention.
7 is a view showing a connection buoyancy body of the connection assembly in the floating structure for floating photovoltaic power generation according to the first embodiment of the present invention.
8 is a first side view showing a floating structure for floating photovoltaic power generation according to a second embodiment of the present invention.
9 is a plan view showing a floating structure for floating solar power generation according to a second embodiment of the present invention.
10 is a second side view showing a floating structure for floating photovoltaic power generation according to a second embodiment of the present invention.
11 is a view showing the coupling state of the adjacent main buoyancy body and the link module in the floating structure for floating photovoltaic power generation according to a second embodiment of the present invention.
12 is a view showing a link module in a floating structure for floating photovoltaic power generation according to a second embodiment of the present invention.

Hereinafter, an embodiment of a floating structure for underwater photovoltaic power generation according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted in order to clarify the gist of the present invention.

The floating structure for floating photovoltaic power generation according to the present invention may include a buoyancy body for floating the device constituting the floating photovoltaic power generation system (hereinafter referred to as the photovoltaic module 1) on the water. The floating structure for floating photovoltaic power generation according to the present invention will be described by dividing it into two embodiments as follows.

In the floating structure for floating photovoltaic power generation according to the present invention, the first direction indicates the opening direction of the water passage P in the portion where the connection assembly 30 is disposed, and the second direction is the main buoyancy body 10 in which the main buoyancy body 10 is disposed. In the portion, the opening direction of the water passage P is indicated. In other words, based on the plane of the floating structure for floating photovoltaic power generation according to the present invention, the first direction represents the up-down direction, and the second direction represents the left-right direction.

1 to 7, the floating structure for floating photovoltaic power generation according to the first embodiment of the present invention is a main buoyancy body 10, a walking buoyancy body 20, a connection assembly 30 and connection It includes a pin 40 and a link assembly 50 .

The main buoyancy body 10 is installed on the water surface in a state in which the solar module 1 is coupled. The main buoyancy body 10 has buoyancy so that a part is immersed in the water surface, and the rest protrude above the water surface. Here, the coupling relationship between the photovoltaic module 1 and the main buoyancy body 10 may be applied to various known techniques, and a description thereof will be omitted.

A main fastening part 11 is formed at the edge of the main buoyancy body 10 . The main fastening part 11 is disposed on the upper part of the main buoyancy body 10 to minimize contact with water, and it is possible to simplify maintenance of the operator.

The main fastening part 11 includes a main bracket 111 protruding from the main buoyancy body 10 and a main hole 112 penetrating through the main bracket 111 for fitting of the connecting pin 40 . can do.

The walking buoyancy body 20 is installed on the water surface so that the operator can walk around the solar module 1 . The walking buoyancy body 20 is partially immersed in the water surface, and the rest has buoyancy to protrude above the water surface.

A walking fastening part is formed in the walking buoyancy body 20 . The walking fastening part can be divided into a first walking fastening part 21 for coupling with the main buoyancy body 10 and a second walking fastening part 22 for coupling with the connecting assembly 30 .

The connecting assembly 30 connects the two adjacent walking buoyancy bodies 20 to each other. A connection fastening part 31 is formed at the edge of the connection assembly 30 . The connection fastening part 31 is disposed on the edge of the connection assembly 30 to minimize the contact of water, and it is possible to simplify the maintenance of the operator.

The connection fastening part 31 includes a connection bracket 311 protruding from the connection assembly 30 and a connection hole 312 formed through the connection bracket 311 for fitting of the connection pin 40 . can

The long side (horizontal length) of the walking buoyancy body 20 excluding the walking fastening part 21 based on the planar state of the floating structure shown in FIG. 2 is the short side of the main buoyant body 10 excluding the main fastening part 11 Since it is formed larger than (horizontal length), the main fastening part 11 overlaps the first walking fastening part 21, and the connecting fastening part 31 is spaced apart from the first walking fastening part 21 and fastens the second walk. It is possible to adjust the separation distance between the walking buoyancy body 20 and the connection assembly 30 while maintaining the adhesion between the part 22 and the main buoyancy body 10 and the walking buoyancy body 20 .

In addition, the long side (horizontal length) of the walking buoyancy body 20 excluding the walking fastening part with respect to the horizontal direction based on the planar state of the floating structure shown in FIG. 2 is the connecting assembly 30 except for the connecting fastening part 31. Longer than the long side (horizontal length), the separation distance between the main buoyancy body 10 is the long side (horizontal length) of the connection assembly 30 except for the connection fastening part 21 and the walking fastening part from the side of the main buoyancy body 10 Since the walking buoyancy body 20 except for the protruding length is represented by the sum of the protruding lengths, it is substantially the same as the long side (horizontal length) of the connecting footrest except for the fastening part in the prior art document (Republic of Korea Patent Publication No. 10-2017295), and the main The buoyancy bodies 10 may be spaced apart at equal intervals.

The connecting pin 40 includes the main fastening unit 11 and the walking fastening unit so that at least two adjacent ones of the main buoyancy body 10, the walking buoyancy body 20, the connecting assembly 30 and the link assembly 50 are coupled to each other. Two or more of the connection fastening parts 31 are coupled to the overlapping portion. The connecting pin 40 may connect the main fastening part 11 and the first walking fastening part 21 to each other, and connecting the second walking fastening part 22 and the connecting fastening part 31 to each other, and adjacent to each other. It shows a structure capable of connecting the two main fastening parts 11 to each other.

Here, the main buoyancy body 10 is provided with one through the connecting pin 40 between the pair of walking buoyancy body 20, or the connecting pin 40 between the pair of walking buoyancy body 20. Two may be provided as a medium.

Although not shown, referring to the prior art literature (Republic of Korea Patent Publication No. 10-2017295), the connection pin 40 has a flange formed at the lower end, and a reinforcing part and a screw part are provided in a certain area on the upper part of the flange, A plurality of reinforcing ribs are provided.

The reinforcing parts are supported in contact with the fastening parts overlapping each other.

The reinforcing rib extends from the inside of the reinforcing portion by the extent of the reinforcing portion. The reinforcing ribs are spaced apart at regular intervals along the circumferential direction and spaced apart in a direction facing each other. The reinforcing rib reinforces the connecting pin 40 , gives rigidity to the connecting pin 40 to increase its own strength, prevents the connecting pin from being damaged by an external force, and protects the reinforcing portion of the connecting pin 40 . zoom in

A fixing nut may be coupled to the screw portion of the connecting pin 40 to fix two or more overlapping fastening parts to each other.

The connecting pin 40 may further include a reinforcing member inserted into the outer circumferential surface of the reinforcing unit to reinforce the reinforcing unit. The reinforcing member may have a cylindrical shape or a hat shape. In particular, the hat-shaped reinforcing member may have a reinforcing flange formed at the lower end in the circumferential direction to cover the flange of the connecting pin, and reinforce the lower portion of the connecting pin. The reinforcing member may be made of a plastic injection molding product or a steel material such as an iron plate.

The connecting pin 40 may further include a core reinforcing material that is positioned at the center of the reinforcing ribs inside the reinforcing unit and is press-fitted in contact with the reinforcing unit to reinforce the reinforcing unit.

The core reinforcing material has a disk-shaped head, a cylindrical body extending from the head, and a step is formed at the end of the body to be caught by the reinforcing rib and fixed with a plurality of cutouts so that the end of the body can be closed. It may include a fixing part.

The coupling relationship between the fastening parts 11 , 21 , 31 , 51 and the connecting pin 40 disclosed in the present invention can be applied to various known techniques.

At this time, by making the upper surface of the main buoyancy body 10 and the upper surface of the walking buoyancy body 20 and the upper surface of the connection assembly 30 substantially coplanar, the operator can move safely. In addition, at least the upper surface of the walking buoyancy body 20 and the upper surface of the connection assembly 30 are formed with concavo-convex portions, so that when the operator moves, it is prevented from slipping, and it is possible to prevent a safety accident of the operator in the floating structure.

Here, in the first embodiment of the present invention, since the main buoyancy body 10 and the walking buoyancy body 20 have buoyancy and the rest protrude above the water surface in a state in which some are immersed in the water surface, the load and the sun of the floating structure on the water surface The load of the optical module 1 can be distributed stably, and even if the load of the operator is transmitted to the individual walking buoyancy body 20 or the individual connection assembly 30 in response to the movement of the operator, the buoyancy body goes to the water surface. Sitting can be minimized.

In particular, in the floating structure according to the first embodiment of the present invention, a link assembly 50 is added, whereby a water passage P is provided in a portion where the link assembly is disposed between two main buoyancy bodies adjacent to each other. There is a characteristic.

The link assembly 50 connects the two main buoyancy bodies 50 adjacent to each other. A link fastening part 51 is formed at the edge of the link assembly 50 . The link fastening part 51 is disposed on the edge of the link assembly 50 to minimize contact with water, and it is possible to simplify the maintenance of the operator.

The link fastening part 51 may include a link bracket 511 protruding from the link assembly 50 and a link hole 512 formed through the link bracket 511 for fitting and coupling of the connection pin 40 . can

And the water passage (P) is formed in the portion where the link assembly 50 is disposed between the two adjacent main buoyancy body 10 to allow water and foreign substances to pass through at the water surface. Then, the link assembly 50 is spaced apart above the water surface.

In the first embodiment of the present invention, a water passage (P) is provided in the lower portion of the link assembly 50, but by the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20, the secured water passage (P) ) can be kept stable. The water passage (P) is a space formed in a portion where the link assembly 50 is disposed between the two main buoyancy bodies 10 adjacent to each other, and water and foreign substances can pass through the water surface. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

Here, the link assembly 50 includes any one of the main link 50a and the link module 50b.

In the first embodiment of the present invention, the link assembly 50 includes a main link (50a).

4 and 5, the main link 50a includes a link body 52 disposed between the two main fastening parts 10 facing each other. Link fastening parts 51 are formed on both edges of the link body 52 for coupling with a pair of main fastening parts 11 facing each other. Since the link body 52 is spaced apart above the water surface, even if the load of the solar module 1 is applied to the link body 52, it is possible to stably maintain the spaced state above the water surface, and the main buoyancy body 10 and walking Prevents the link body 52 from being submerged below the water surface by the buoyancy of the buoyancy body 20, and the link body 52 is spaced apart from the water surface by the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20. The state is maintained and the water passage (P) can be stably maintained.

The floating structure according to the first embodiment of the present invention sets the maximum load that can be applied to the main buoyancy body 10 and the walking buoyancy body 20, and accordingly the main buoyancy body 10 and the walking buoyancy body 20 By calculating the depth that can be submerged in water, the volume of the main buoyancy body 10 and the walking buoyancy body 20 can be designed.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure can be evenly distributed to the main buoyancy body 10 and the walking buoyancy body 20, The height and width of the water passage P provided in the lower part of the link body 52 may be set according to the volume of the main buoyancy body 10 and the walking buoyancy body 20 .

In addition, in response to the size of the walking buoyancy body 20 in the first embodiment of the present invention, there is a characteristic in the detailed coupling relationship between the main buoyancy body 10 and the walking buoyancy body 20 and the connection assembly 30 .

In the first embodiment of the present invention, a water passage (P) is provided in the lower portion of the connection assembly (30), but by the buoyancy of the main buoyancy body (10) and the walking buoyancy body (20), the secured water passage (P) ) can be kept stable. The water passage (P) is a space formed in a portion where the connection assembly 30 is disposed between the two adjacent walking buoyancy bodies 20, and water and foreign substances can pass through the water surface. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

The walking fastening part includes a first walking fastening part 21 and a second walking fastening part 22 as described above.

The first walking fastening part 21 is for coupling with the main fastening part 11 , and is formed on the edge of the long side of the walking buoyancy body 20 .

The first walking fastening part 21 has a walking seating part 211 recessed in the upper surface edge of the walking buoyancy body 20 to correspond to the main fastening part 11, and a connecting pin ( 40) may include a walking coupling part 212 that is recessed or penetrating the walking seating part 211 for fitting.

The second walking fastening part 22 is spaced apart from the first walking fastening part 21 . The second walking fastening part 22 is formed on the edge of the walking buoyancy body 20 for coupling with the connecting fastening part 31 .

The second walking fastening part 22 is a walking bracket protruding from the edge of the walking buoyancy body 20 to correspond to the connecting fastening part 31, and the connecting pin 40 to correspond to the connecting hole 312. For this, it may include a walking hole 222 that is formed through the walking bracket 221 .

Then, the connecting pin 40 may couple the main hole 112 of the main fastening part 11 overlapping with each other and the walking coupling part 212 of the first walking fastening part 21 .

In addition, the water passage (P) may be further formed between the connection assembly 30 and the water surface as the connection assembly 30 is spaced apart from the water surface. Then, the connection assembly 30 is spaced apart above the water surface.

Here, the connection assembly 30 includes any one of the connection buoyancy body and the connection panel.

In the first embodiment of the present invention, the connecting assembly 30 includes a connecting buoyancy body.

The connecting buoyancy body represents a block shape. Since the connection buoyancy body is spaced apart above the water surface with buoyancy, when the load of the operator is applied to the connection buoyancy body, it can contact the water surface, but the buoyancy and the connection buoyancy of the main buoyancy body 10 and the walking buoyancy body 20 Prevents the connecting buoyancy body from submerging below the water level by the buoyancy of the body, and when the load of the operator is released from the connecting buoyancy body, the connecting buoyancy body is spaced apart above the water surface by the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20 is maintained and the water passage (P) can be stably maintained.

The floating structure according to the first embodiment of the present invention sets the maximum load that can be applied to the main buoyancy body 10 and the walking buoyancy body 20, and accordingly the main buoyancy body 10 and the walking buoyancy body 20 By calculating the depth that can be submerged in water, the volume of the main buoyancy body 10 and the walking buoyancy body 20 can be designed.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure can be evenly distributed to the main buoyancy body 10 and the walking buoyancy body 20, According to the volume of the main buoyancy body 10 and the walking buoyancy body 20, the volume of the connection buoyancy body and the height and width of the water passage P provided under the connection buoyancy body can be set.

Here, referring to FIG. 7, T is the thickness of the main buoyancy body 10 or the walking buoyancy body 20, t is the thickness of the connection assembly 30, the connection buoyancy body, d is the load of the entire floating structure If the main buoyancy body 10 or the walking buoyancy body 20 is submerged in water based on the basis, the height (h) from the water surface to the connection assembly (30, connection buoyancy body) can be set to h = Ttd recognition. .

Then, in designing the connection assembly (30, connection buoyancy body), when the floating structure is installed on the water surface, the thickness of the connection assembly (30, connection buoyancy body) can be limited, and the connection assembly 30, connection buoyancy body ) can be used as a stabilized water passage.

8 to 12, the floating structure for floating photovoltaic power generation according to the second embodiment of the present invention is a main buoyancy body 10, a walking buoyancy body 20, a connection assembly 30 and a connection It includes a pin 40 and a link assembly 50 .

The main buoyancy body 10 is installed on the water surface in a state in which the solar module 1 is coupled. The main buoyancy body 10 has buoyancy so that a part is immersed in the water surface, and the rest protrude above the water surface. Here, the coupling relationship between the photovoltaic module 1 and the main buoyancy body 10 may be applied to various known techniques, and a description thereof will be omitted.

A main fastening part 11 is formed at the edge of the main buoyancy body 10 . The main fastening part 11 is disposed on the upper part of the main buoyancy body 10 to minimize contact with water, and it is possible to simplify maintenance of the operator.

The main fastening part 11 includes a main bracket 111 protruding from the main buoyancy body 10 and a main hole 112 penetrating through the main bracket 111 for fitting of the connecting pin 40 . can do.

The walking buoyancy body 20 is installed on the water surface so that the operator can walk around the solar module 1 . The walking buoyancy body 20 is partially immersed in the water surface, and the rest has buoyancy to protrude above the water surface.

A walking fastening part is formed in the walking buoyancy body 20 . The walking fastening part can be divided into a first walking fastening part 21 for coupling with the main buoyancy body 10 and a second walking fastening part 22 for coupling with the connecting assembly 30 .

The connecting assembly 30 connects the two adjacent walking buoyancy bodies 20 to each other. A connection fastening part 31 is formed at the edge of the connection assembly 30 . The connection fastening part 31 is disposed on the edge of the connection assembly 30 to minimize the contact of water, and it is possible to simplify the maintenance of the operator.

The connection fastening part 31 includes a connection bracket 311 protruding from the connection assembly 30 and a connection hole 312 formed through the connection bracket 311 for fitting of the connection pin 40 . can

The long side (horizontal length) of the walking buoyancy body 20 excluding the walking fastening part 21 based on the planar state of the floating structure shown in FIG. 9 is the short side of the main buoyant body 10 excluding the main fastening part 11 Since it is formed larger than (horizontal length), the main fastening part 11 overlaps the first walking fastening part 21, and the connecting fastening part 31 is spaced apart from the first walking fastening part 21 and fastens the second walk. It is possible to adjust the separation distance between the walking buoyancy body 20 and the connection assembly 30 while maintaining the adhesion between the part 22 and the main buoyancy body 10 and the walking buoyancy body 20 .

In addition, the long side (horizontal length) of the walking buoyancy body 20 excluding the walking fastening part with respect to the horizontal direction based on the planar state of the floating structure shown in FIG. 9 is the connecting assembly 30 excluding the connecting fastening part 31. Longer than the long side (horizontal length), the separation distance between the main buoyancy body 10 is the long side (horizontal length) of the connection assembly 30 except for the connection fastening part 21 and the walking fastening part from the side of the main buoyancy body 10 Since the walking buoyancy body 20 except for the protruding length is represented by the sum of the protruding lengths, it is substantially the same as the long side (horizontal length) of the connecting footrest except for the fastening part in the prior art document (Republic of Korea Patent Publication No. 10-2017295), and the main The buoyancy bodies 10 may be spaced apart at equal intervals.

The connecting pin 40 is the main fastening part 11, the walking fastening part and the connecting fastening part 31 so that two or more of the main buoyancy body 10, the walking buoyancy body 20, and the connecting assembly 30 are coupled to each other. Two or more of them join the overlapping parts. The connecting pin 40 may connect the main fastening part 11 and the first walking fastening part 21 to each other, and connecting the second walking fastening part 22 and the connecting fastening part 31 to each other, and adjacent to each other. It shows a structure capable of connecting the two main fastening parts 11 to each other.

Here, the main buoyancy body 10 is provided with one through the connecting pin 40 between the pair of walking buoyancy body 20, or the connecting pin 40 between the pair of walking buoyancy body 20. Two may be provided as a medium.

The connection pin 40 has the same configuration as the connection pin 40 according to the first embodiment of the present invention, and a description thereof will be omitted.

The coupling relationship between the fastening parts 11, 21, 31 and the connecting pin 40 disclosed in the present invention can be applied to a variety of known techniques.

At this time, by making the upper surface of the main buoyancy body 10 and the upper surface of the walking buoyancy body 20 and the upper surface of the connection assembly 30 substantially coplanar, the operator can move safely. In addition, at least the upper surface of the walking buoyancy body 20 and the upper surface of the connection assembly 30 are formed with concavo-convex portions, so that when the operator moves, it is prevented from slipping, and it is possible to prevent a safety accident of the operator in the floating structure.

Here, in the second embodiment of the present invention, since the main buoyancy body 10 and the walking buoyancy body 20 have buoyancy and the rest protrude above the water surface in a state where some are immersed in the water surface, the load and the sun of the floating structure on the water surface The load of the optical module 1 can be distributed stably, and even if the load of the operator is transmitted to the individual walking buoyancy body 20 or the individual connection assembly 30 in response to the movement of the operator, the buoyancy body goes to the water surface. Sitting can be minimized.

In particular, in the floating structure according to the second embodiment of the present invention, a link assembly 50 is added, whereby a water passage P is provided at a portion where the link assembly is disposed between two main buoyancy bodies adjacent to each other. There is a characteristic.

The link assembly 50 connects the two main buoyancy bodies 50 adjacent to each other. A link fastening part 51 is formed at the edge of the link assembly 50 . The link fastening part 51 is disposed on the edge of the link assembly 50 to minimize contact with water, and it is possible to simplify the maintenance of the operator.

The link fastening part 51 may include a link bracket 511 protruding from the link assembly 50 and a link hole 512 formed through the link bracket 511 for fitting and coupling of the connection pin 40 . can

And the water passage (P) is formed in the portion where the link assembly 50 is disposed between the two adjacent main buoyancy body 10 to allow water and foreign substances to pass through at the water surface. Then, the link assembly 50 is spaced apart above the water surface.

In the second embodiment of the present invention, a water passage (P) is provided in the lower portion of the link assembly (50), but by the buoyancy of the main buoyancy body (10) and the walking buoyancy body (20) acts, the secured water passage (P) ) can be kept stable. The water passage (P) is a space formed in a portion where the link assembly 50 is disposed between the two main buoyancy bodies 10 adjacent to each other, and water and foreign substances can pass through the water surface. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

Here, the link assembly 50 includes any one of the main link 50a and the link module 50b.

In the second embodiment of the present invention, the link assembly 50 includes a link module 50b.

11 and 12, the link module 50b includes a module body 53 that is long disposed between the two main buoyancy bodies 10 facing each other. Link fastening parts 51 are formed on both edges of the module body 53 for coupling with two or more pairs of main fastening parts 11 facing each other. Since the module link 53 is spaced apart above the water surface, even if the load of the solar module 1 is applied to the module link 53, it is possible to stably maintain the spaced state above the water surface, and the main buoyancy body 10 and walking By the buoyancy of the buoyancy body 20, the modular link 53 is prevented from being submerged below the water surface, and the modular link 53 is spaced apart from the water surface by the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20. The state is maintained and the water passage (P) can be stably maintained.

The floating structure according to the second embodiment of the present invention sets the maximum load that can be applied to the main buoyancy body 10 and the walking buoyancy body 20, and accordingly the main buoyancy body 10 and the walking buoyancy body 20. By calculating the depth that can be submerged in water, the volume of the main buoyancy body 10 and the walking buoyancy body 20 can be designed.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure can be evenly distributed to the main buoyancy body 10 and the walking buoyancy body 20, According to the volume of the main buoyancy body 10 and the walking buoyancy body 20, the height and width of the water passage P provided in the lower part of the module link 53 can be set.

In addition, in response to the size of the walking buoyancy body 20 in the second embodiment of the present invention, there is a characteristic in the detailed coupling relationship between the main buoyancy body 10 and the walking buoyancy body 20 and the connection assembly 30 .

The walking fastening part includes a first walking fastening part 21 and a second walking fastening part 22 as described above.

The first walking fastening part 21 is for coupling with the main fastening part 11 , and is formed on the edge of the long side of the walking buoyancy body 20 .

The first walking fastening part 21 has a walking seating part 211 recessed in the upper surface edge of the walking buoyancy body 20 to correspond to the main fastening part 11, and a connecting pin ( 40) may include a walking coupling part 212 that is recessed or penetrating the walking seating part 211 for fitting.

The second walking fastening part 22 is spaced apart from the first walking fastening part 21 . The second walking fastening part 22 is formed on the edge of the walking buoyancy body 20 for coupling with the connecting fastening part 31 .

The second walking fastening part 22 includes a walking bracket 221 protruding from the edge of the walking buoyancy body 20 to correspond to the connecting fastening part 31 and a connecting pin 40 corresponding to the connecting hole 312 . It may include a walking hole 222 that is formed through the walking bracket 221 for fitting.

Then, the connecting pin 40 may couple the main hole 112 of the main fastening part 11 overlapping with each other and the walking coupling part 212 of the first walking fastening part 21 .

In addition, the water passage (P) may be further formed between the connection assembly 30 and the water surface as the connection assembly 30 is spaced apart from the water surface. Then, the connection assembly 30 is spaced apart above the water surface.

In the second embodiment of the present invention, a water passage (P) is provided in the lower portion of the connection assembly (30), but by the buoyancy of the main buoyancy body (10) and the walking buoyancy body (20), the secured water passage (P) ) can be kept stable. The water passage (P) is a space formed in the portion where the connection assembly 30 is disposed between the two adjacent walking buoyancy bodies 20, and water and foreign substances can pass through the water surface. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

The floating structure according to the second embodiment of the present invention sets the maximum load that can be applied to the main buoyancy body 10 and the walking buoyancy body 20, and accordingly the main buoyancy body 10 and the walking buoyancy body 20. By calculating the depth that can be submerged in water, the volume of the main buoyancy body 10 and the walking buoyancy body 20 can be designed.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure can be evenly distributed to the main buoyancy body 10 and the walking buoyancy body 20, According to the volume of the main buoyancy body 10 and the walking buoyancy body 20, the volume of the connection panel 30b and the height and width of the water passage P provided under the connection panel 30b can be set.

In each embodiment of the present invention, for the coupling relationship between the main buoyancy body 10 and the walking buoyancy body 20, when the first walking fastening part 21 protrudes from the long side of the walking buoyancy body 20, the main buoyancy body On the short side of (10), the first structure in which the main fastening part 11 is protruded or recessed so as to overlap the first walking fastening part 21, and the main fastening part 11 is formed from the short side of the main buoyancy body 10 When the protrusion is formed, the long side of the walking buoyancy body 20 has a second structure in which the first walking fastening part 21 is protruded or recessed so as to overlap the main fastening part 11, and the first walking fastening part 21 is When the depression is formed on the long side of the walking buoyancy body 20 and the main fastening part 11 is recessed on the short side of the main buoyancy body 10, the coupling bracket is attached to the first walking fastening part 21 and the main fastening part 11. (not shown) may include any one of the third structure that is inserted and supported.

In other words, in each embodiment of the present invention, the main fastening part 11 is formed to protrude from the main buoyancy body 10 , and the first walking fastening part 21 is recessed from the walking buoyancy body 20 to form a connecting pin Although shown to be coupled by (40), it may further include two coupling methods as follows.

First, when the main fastening part 11 includes a seating part recessed at the edge of the body and a coupling part recessed or penetrating the seating part, the first walking coupling part 21 is formed to protrude from the body. Since the bracket includes a hole formed through the bracket to communicate with the coupling part, the connecting pin 40 may be coupled to the hole and the coupling part.

Second, when the main fastening part 11 and the first walking fastening part 21 include a seating part recessed on the edge of the body and a coupling part recessed or penetrating the seating part, inserted and supported in the seating part It further includes a separate insertion bracket, and since a pair of holes are formed through the insertion bracket corresponding to each coupling portion, the connection pin 40 may be coupled to the hole and the coupling portion.

Third, when the main fastening part 11 and the first walking fastening part 21 include a corresponding bracket protruding from the body and a hole formed through the bracket, the connecting pin 40 is located in the overlapping hole. can be combined.

In addition, the coupling relationship between the second walking fastening part 22 and the connecting fastening part 31 may also correspond to the change in the coupling relationship between the above-described main fastening part 11 and the first walking fastening part 21 .

In addition, the coupling relationship between the two main fastening parts 11 may also correspond to the change in the coupling relationship between the above-described main fastening part 11 and the first walking fastening part 21 .

Although not shown, the connection assembly 30 may include a connection panel.

The connection panel represents the panel shape. Since the connection panel is spaced apart above the water surface with buoyancy, even if the load of the operator is applied to the connection panel, it is possible to stably maintain the spaced state above the water surface, and to the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20 By preventing the connection panel from being locked below the water surface, and when the operator's load is released from the connection panel, the state of the connection panel spaced above the water surface is maintained by the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20, It is possible to keep the water passage (P) stable.

Although not shown, the lower portion of the main buoyancy body 10 is further provided with a water passage (P) spaced apart from the water surface through which water and foreign substances can pass. Then, the main buoyancy body 10 is to perform the function of generating buoyancy and the complex function of forming the water passage (P).

Then, the water passage (P) is provided in the lower part of the main buoyancy body 10, but by the buoyancy of the individual buoyancy bodies, it is possible to stably maintain the secured water passage (P). The water passage (P) is a space recessed from the lower portion of the main buoyancy body 10 and is spaced apart from the water surface so that water and foreign substances can pass therethrough. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

The main buoyancy body 10 may include a main body installed on the water surface, and a main wing extending from the upper end of the main body to form a water passage in the lower portion. The upper surface of the main body and the upper surface of the main wing may be substantially disposed on the same plane to form a horizontal plane in the floating structure.

The main body may include a first main buoyancy unit and a second main buoyancy unit.

The first main buoyancy unit is installed on the water surface with buoyancy. A main fastening part 11 is provided at the edge of the first main buoyancy part.

The second main buoyancy unit is spaced apart from the first main buoyancy unit and is installed on the water surface with buoyancy. At the edge of the second main buoyancy unit, a main fastening unit 11 is provided.

The main wing may include a main wing buoyancy unit that integrally connects the upper end of the first main buoyancy unit and the upper end of the second main buoyancy unit to form a water passage (P). Since the main wing buoyancy part extends from the upper end of the other side of the first main buoyancy part and is integrally connected to the upper end of one side of the second main buoyancy part, a water passage P may be formed in the lower part of the main wing buoyancy part.

And set the maximum load that can be applied to the main buoyancy body 10, the walking buoyancy body 20, the connection assembly 30 and the link assembly 50, and accordingly the main buoyancy body 10 and the walking buoyancy body 20 ) by calculating the depth that can be submerged in water, it is possible to design the volume of the main buoyancy body 10, the walking buoyancy body 20, the connection assembly 30 and the link assembly 50.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure is applied to the main buoyancy body 10 and the walking buoyancy body 20 and the connecting buoyancy body 30. It can be evenly distributed in the and link assembly 50, the volume of the main buoyancy body 10 and the main buoyancy body 10 according to the volume of the main buoyancy body 10 and the walking buoyancy body 20. The height of the water passage (P) can be set.

Here, T is the thickness of the main body, t is the thickness of the main wing, and d is the height of the main buoyancy body 10 submerged in water based on the load of the entire floating structure, the height from the water surface to the main wing ( h) can be set as h=Ttd.

Then, in designing the main buoyancy body 10, when the floating structure is installed on the water surface, the buoyancy of the main buoyancy body 10 is prevented from being lowered, and the water passage P stabilized in the main buoyancy body 10 ) can be formed.

Although not shown, the lower portion of the main buoyancy body 10 is provided with a water passage (P) spaced apart from the water surface through which water and foreign substances can pass. Then, the main buoyancy body 10 is to perform the function of generating buoyancy and the complex function of forming the water passage (P).

Then, the water passage (P) is provided in the lower part of the main buoyancy body 10, but by the buoyancy of the individual buoyancy bodies, it is possible to stably maintain the secured water passage (P). The water passage (P) is a space recessed from the lower portion of the main buoyancy body 10 and is spaced apart from the water surface so that water and foreign substances can pass therethrough. In the water passage (P), water in the center and the outside of the floating structure can circulate with each other. Since the water around the floating structure moves naturally, it is possible to minimize pollutants or algae caused by water stagnation.

The main buoyancy body 10 may include a main body installed on the water surface, and a main wing extending from the upper end of the main body to form a water passage (P) in the lower portion. The upper surface of the main body and the upper surface of the main wing may be substantially disposed on the same plane to form a horizontal plane in the floating structure.

The main body may include a main buoyancy unit installed on the water surface with buoyancy.

The main wing may include a first main wing buoyancy unit and a second main wing buoyancy unit.

The first main wing buoyancy unit extends from an upper end of one side of the main buoyancy unit. Then, a water passage (P) is formed in the lower portion of the buoyancy of the first main wing. A main fastening part 11 is provided at the edge of the first main wing buoyancy part.

The second main wing buoyancy unit extends from the upper end of the other side of the main buoyancy unit. Then, a water passage (P) is formed in the lower portion of the buoyancy of the first main wing. A main fastening part 11 is provided at the edge of the first main wing buoyancy part.

And set the maximum load that can be applied to the main buoyancy body 10, the walking buoyancy body 20, the connection assembly 30 and the link assembly 50, and accordingly the main buoyancy body 10 and the walking buoyancy body 20 ) by calculating the depth that can be submerged in water, it is possible to design the volume of the main buoyancy body 10, the walking buoyancy body 20, the connection assembly 30 and the link assembly 50.

Then, since the main buoyancy body 10 and the walking buoyancy body 20 are supported on the water surface, the maximum load that can be applied to the floating structure is applied to the main buoyancy body 10 and the walking buoyancy body 20 and the connecting buoyancy body 30. It can be evenly distributed in the and link assembly 50, the volume of the main buoyancy body 10 and the main buoyancy body 10 according to the volume of the main buoyancy body 10 and the walking buoyancy body 20. The height of the water passage (P) can be set.

Here, T is the thickness of the main body, t is the thickness of the main wing, and d is the height of the main buoyancy body 10 submerged in water based on the load of the entire floating structure, the height from the water surface to the main wing ( h) can be set as h=Ttd.

Then, in designing the main buoyancy body 10, when the floating structure is installed on the water surface, the buoyancy of the main buoyancy body 10 is prevented from being lowered, and the water passage P stabilized in the main buoyancy body 10 ) can be formed.

Although not shown, the main wing in the main buoyancy body 10 may be immersed below the water surface. At this time, the water passage (P) may be formed on the upper side of the main wing as the main wing is immersed under the water surface. Here, the main buoyancy body 10 includes a first main buoyancy part, a second main buoyancy part, and a main wing buoyancy part, but the main wing buoyancy part can connect the lower end of the first main buoyancy part and the lower end of the second main buoyancy part integrally. have. In addition, the main buoyancy body 10 includes a main buoyancy part, a first main wing buoyancy part, and a second main wing buoyancy part, and the first main wing buoyancy part and the second main wing buoyancy part are each at the lower ends of both sides of the main buoyancy part, respectively. can be extended Then, the water passage (P) formed on the upper side of the main wing separates the adjacent first main buoyancy part and the second main buoyancy part, as well as water passes between the first main buoyancy part and the second main buoyancy part. It is possible to prevent the fire from spreading between the first main buoyancy part and the second main buoyancy part.

Although not shown, the connection assembly 30 connects the two adjacent walking buoyancy bodies 20 , but may be immersed under the water surface. At this time, the water passage (P) may be formed on the upper side of the connection assembly 30 as the connection assembly 30 is immersed under the water surface. The water passage (P) formed on the upper side of the connection assembly 30 separates the two adjacent walking buoyancy bodies 20 as well as water passes between the two walking buoyancy bodies 20, so the two walking buoyancy bodies 20) It can prevent the fire from spreading between them.

In particular, since the connection assembly 30 has buoyancy in a state immersed under the water surface, it functions to distribute the buoyancy in response to the maximum load of the floating structure, and the main buoyancy body 10 and the walking buoyancy body 20 can reduce the height at which it is immersed below the water surface.

According to the floating structure for the above-described floating photovoltaic power generation, in response to the arrangement direction of the photovoltaic module (1) in the floating structure in at least one of the first direction and the second direction, foreign substances floating in the water can move The furnace P is secured, and while reducing the phenomenon of algae in the water in which the floating structure is installed, foreign substances and algae can move to the outside of the floating structure.

In addition, it is possible to prevent foreign substances from stagnation in the floating structure to minimize the adhesion of foreign substances to the photovoltaic module 1, and to increase the energy production efficiency of the photovoltaic module.

In addition, by suppressing the occurrence of algae around the floating structure, it is possible to prevent damage to the floating photovoltaic power generation system due to the algae, damage to the floating structure, and contamination of the water in which the floating structure is installed.

In addition, the durability and strength of the floating structure can be improved through the connecting pin 40 , and it is possible to prevent the connecting pin 40 from being damaged by an external force in advance.

In addition, the floating structure can maintain a more robust state in water, and maintenance and safety management of the floating solar power generation system and the floating structure are possible.

In addition, the water passage P is secured between the two main buoyancy bodies 10 that are continuously coupled through the detailed coupling relationship of the link assembly 50 and the floating structure so that water and foreign substances pass stably.

In addition, by maximizing the contact area between the floating structure and the water surface through the detailed configuration of the main buoyancy body 10 and the walking buoyancy body 20, the load stability of the floating structure is improved while distributing the load of the solar module 1 and the floating structure. To improve, it is possible to prevent the strength of the main buoyancy body 10 or the connection assembly 30 from being lowered.

In addition, the water passage P is secured in a part of the main buoyancy body 10 through the detailed configuration of the main buoyancy body 10 so that water and foreign substances pass stably.

In addition, the water passage P is secured through the detailed configuration of the connection assembly 30 so that water and foreign substances pass stably.

In addition, in designing the main buoyancy body 10, the walking buoyancy body 20 and the connection assembly 30 through the thickness calculation formula of the main buoyancy body 10 and the thickness calculation formula of the connection assembly 30, the floating structure is on the water surface. When installed, the buoyancy of the main buoyancy body 10 and the walking buoyancy body 20 is prevented from being lowered, and the connection assembly 30 is disposed between a part of the main buoyancy body 10 or the walking buoyancy body 20 . It is possible to form a stable water passage (P) in the portion to be.

In addition, through the detailed coupling relationship between the main buoyancy body 10 and the walking buoyancy body 20 and the detailed coupling relationship between the walking buoyancy body 20 and the connecting assembly 30, the main buoyancy body 10 based on the plane. And while preventing the flow between the walking buoyancy body 20 and the connection assembly 30, it is possible to maintain a constant separation distance between the main buoyancy body (10).

In addition, when the water passage (P) is disposed between the adjacent main buoyancy body 10 or a part of the main buoyancy body 10 or the lower part of the connection assembly 30, only the movement path of water and foreign substances is formed, but the link assembly (50) or a part of the main buoyancy body 10 or the connection assembly 30 is immersed below the water surface, the water passage (P) forms a movement path of water and foreign substances while two adjacent walking buoyancy bodies (20) It can prevent the fire from spreading between them.

Although the preferred embodiment of the present invention has been described with reference to the drawings as described above, those skilled in the art may vary the present invention in various ways without departing from the spirit and scope of the present invention as set forth in the following claims. may be modified or changed.

10: main buoyancy body 11: main fastening part 111: main bracket
112: main hall 20: walking buoyancy body 21: first walking fastening part
211: walking seating part 212: walking coupling part 22: second walking fastening part
221: walking bracket 222: walking hole 30: connection assembly
31: connection fastening part 311: connection bracket 312: connection hole
40: connecting pin 50: link assembly 50a: main link
50b: link module 51: link fastening unit 511: link bracket
512: link hole 52: link body 53: module body
P: water passage T, t: thickness d: immersion height
1: Solar module

Claims (12)

a main buoyant body installed on the water surface in a state in which a solar module is coupled, and a main fastening part is formed on the edge;
a walking buoyant body installed on the water surface so that a worker can walk around the solar module and formed with a walking fastening part;
a connecting assembly connecting two adjacent walking buoyancy bodies, and having a connecting fastening part formed at an edge thereof;
a link assembly connecting two adjacent main buoyancy bodies, the link fastening part being formed at the edge; and
At least two of the main fastening part, the walking fastening part, the connecting fastening part, and the link fastening part overlap so that at least two adjacent to each other of the main buoyancy body, the walking buoyancy body, the connection assembly and the link assembly are coupled Including; a connecting pin for coupling the part;
The main buoyancy body and the walking buoyancy body have buoyancy and the rest protrude above the water surface in a state in which some are immersed in the water surface,
At least one of a portion of the main buoyancy body, a portion where the connection assembly is disposed between two adjacent walking buoyancy bodies, and a portion where the link assembly is disposed between the two adjacent main buoyancy bodies,
A water passage through which water and foreign substances can pass at the water surface; is provided;
The water passage is
When a part of the main buoyancy body is immersed under the water surface, it is formed on the upper side of a part of the main buoyancy body so that water and foreign substances can pass through the upper side of a part of the main buoyancy body,
When the connection assembly is immersed under the water surface, it is formed on the upper side of the connection assembly so that water and foreign substances can pass through the upper side of the connection assembly between two adjacent walking buoyancy bodies,
When the link assembly is immersed below the water surface, it is formed on the upper side of the link assembly and between two adjacent main buoyancy bodies, water and foreign substances can pass through the upper side of the link assembly. .
a main buoyant body installed on the water surface in a state in which a solar module is coupled, and a main fastening part is formed on the edge;
a walking buoyant body installed on the water surface so that a worker can walk around the solar module and formed with a walking fastening part;
a connecting assembly connecting two adjacent walking buoyancy bodies, and having a connecting fastening part formed at an edge thereof;
a link assembly connecting two adjacent main buoyancy bodies, the link fastening part being formed at the edge; and
At least two of the main fastening part, the walking fastening part, the connecting fastening part, and the link fastening part overlap so that at least two adjacent to each other of the main buoyancy body, the walking buoyancy body, the connection assembly and the link assembly are coupled Including; a connecting pin for coupling the part;
The main buoyancy body and the walking buoyancy body have buoyancy and the rest protrude above the water surface in a state in which some are immersed in the water surface,
At least one of a portion of the main buoyancy body, a portion where the connection assembly is disposed between two adjacent walking buoyancy bodies, and a portion where the link assembly is disposed between the two adjacent main buoyancy bodies,
A water passage through which water and foreign substances can pass at the water surface; is provided;
The upper surface of the main buoyancy body and the upper surface of the walking buoyancy body form the same plane,
The main buoyancy body,
Main body installed on the water surface; and
Containing, including;
The main body is
a first main buoyancy unit installed on the water surface with buoyancy and provided with the main fastening unit at an edge thereof; and
and a second main buoyancy unit that is spaced apart from the first main buoyancy unit and installed on the water surface with buoyancy, and the main fastening unit is provided at the edge.
The main wing is
and a main wing buoyancy unit integrally connecting the upper end of the first main buoyancy and the upper end of the second main buoyancy so that the water passage is formed in the lower portion.
T is the thickness of the main body,
t is the thickness of the main wing,
If d is the height at which the main buoyancy body is submerged in water based on the load of the floating structure,
The height (h) from the water surface to the main wing is,
Floating structure for floating photovoltaic power generation, characterized in that it is set to h = Ttd recognition.
a main buoyant body installed on the water surface in a state in which a solar module is coupled, and a main fastening part is formed on the edge;
a walking buoyant body installed on the water surface so that a worker can walk around the solar module and formed with a walking fastening part;
a connecting assembly connecting two adjacent walking buoyancy bodies, and having a connecting fastening part formed at an edge thereof;
a link assembly connecting two adjacent main buoyancy bodies, the link fastening part being formed at the edge; and
At least two of the main fastening part, the walking fastening part, the connecting fastening part, and the link fastening part overlap so that at least two adjacent to each other of the main buoyancy body, the walking buoyancy body, the connection assembly and the link assembly are coupled Including; a connecting pin for coupling the part;
The main buoyancy body and the walking buoyancy body have buoyancy and the rest protrude above the water surface in a state in which some are immersed in the water surface,
At least one of a portion of the main buoyancy body, a portion where the connection assembly is disposed between two adjacent walking buoyancy bodies, and a portion where the link assembly is disposed between the two adjacent main buoyancy bodies,
A water passage through which water and foreign substances can pass at the water surface; is provided;
The upper surface of the main buoyancy body and the upper surface of the walking buoyancy body form the same plane,
The main buoyancy body,
Main body installed on the water surface; and
Containing, including;
The main body is
Including; the main buoyancy unit installed on the water surface with buoyancy;
The main wing is
a first main wing buoyancy unit extending from an upper end of one side of the main buoyancy unit so that the water passage is formed at a lower portion and having the main fastening unit at an edge thereof; and
a second main wing buoyancy part extending from the other upper end of the main buoyancy part so that the water passage is formed in the lower part and having the main fastening part at the edge;
T is the thickness of the main body,
t is the thickness of the main wing,
If d is the height at which the main buoyancy body is submerged in water based on the load of the floating structure,
The height (h) from the water surface to the main wing is,
Floating structure for floating photovoltaic power generation, characterized in that it is set to h = Ttd recognition.
According to claim 1,
The main buoyancy body,
Main body installed on the water surface; and
The main wing extending from the upper end or lower end of the main body to form the water passage; including,
The water passage is
When the main wing extends from the upper end of the main body, it is formed on the lower side of the main wing,
When the main wing extends from the lower end of the main body, floating structure for floating photovoltaic power generation, characterized in that formed on the upper side of the main wing.
5. The method according to any one of claims 1 to 4,
Based on the planar state, the long side of the walking buoyancy body except for the walking fastening part is formed to be larger than the short side of the main buoyant body except for the main fastening part, so that the walking buoyant body is formed to protrude from the side of the main buoyant body,
The walking fastening unit,
a first fastening part for walking formed on the long side edge of the walking buoyancy body for coupling with the main fastening part; and
Floating structure for floating photovoltaic power generation, characterized in that it comprises a; spaced apart from the first walking fastening portion, the second walking fastening portion formed on the edge of the walking buoyancy body for coupling with the connecting fastening portion.
5. The method according to any one of claims 1 to 4,
The link assembly is
a main link comprising a link body disposed between two main fastening parts facing each other, wherein the link fastening parts are formed on both edges of the link body for coupling with a pair of the main fastening parts facing each other; and
a link module comprising a module body elongatedly disposed between two opposite main buoyancy bodies, wherein the link fastening parts are formed on both edges of the module body for coupling with two or more pairs of mutually facing main fastening parts;
Floating structure for floating photovoltaic power generation, characterized in that it comprises any one.
5. The method according to any one of claims 1 to 4,
The connection assembly,
a connecting buoyancy body having a block shape and formed with the connecting fastening part on the edge for coupling with the walking fastening part; and
a connecting panel having a panel shape and having the connecting fastening part formed on the edge for coupling with the walking fastening part;
Floating structure for floating photovoltaic power generation, characterized in that it comprises any one.
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