KR101679538B1 - Flexible type floating solar power generating system - Google Patents

Abstract

The present invention relates to a column-fixed type flexible floating solar power generating system. The column-fixed type flexible floating solar power generating system comprises: a plurality of mooring fixing columns fixed to the ground under water and including lifting devices vertically moving depending on a level of water, respectively; main connection ropes connecting lifting devices of the two mooring fixing columns adjacent to each of the other mooring fixing columns; auxiliary connection ropes connecting the main connection ropes in horizontal and vertical directions; a supporting floating structure positioned at least one unit area of a rectangular unit area formed by the auxiliary connection ropes or formed by the auxiliary connection ropes and the main connection ropes; a photovoltaic module installed on the supporting floating structure; and unit connection devices fixing the supporting floating structure by connecting the supporting floating structure with the main connection ropes and the auxiliary connection ropes forming the unit area. According to the present invention, the photovoltaic modules are flexibly moved depending on the wave when there are high waves. The large amount of photovoltaic modules can be installed in the water, and the structure of the module in the water is simple.

Description

FLEXIBLE TYPE FLOATING SOLAR POWER GENERATING SYSTEM [0001]

The present invention relates to a column-type flexible water-state photovoltaic power generation system.

At present, the problem of resource exhaustion due to the finite nature of hydrocarbons fossil energy resources, along with the increase of greenhouse gas emitted by its use, has adversely affected the global environment and threatened the survival of mankind. In addition, nuclear power generation is also threatened by the depletion of resources and the impact on the global environment and the survival of humankind in case of an accident, as seen in the case of Chernobyl and Fukushima nuclear power plants.

For the above reasons, the use of renewable energy such as solar power, wind power, and tidal power generation, which have no environmental pollution and infinite duration, is increasing all over the world. Among the renewable energies, solar energy is distributed evenly in people's inhabitants of the earth and solar energy is converted directly into electric energy, so solar power generation is the most effective, while solar energy is low in energy density and needs a large area Do.

Until now, photovoltaic power generation facilities have been installed in tidal fields, agricultural lands, and forests, but they are causing other environmental problems, such as land use and forest destruction, in addition to the pure function of using renewable energy. It is not welcomed by local residents because of contention, and is facing difficulties due to various complaints. Therefore, there is active and some research on solar power generation in desert areas and aquifers that do not compete with humans with limited land resources, and do not adversely affect the environment such as farmland destruction or deforestation.

A photovoltaic power plant installed on a lake, a river, or the sea's surface is called a water-state power generation system. This is human-friendly because it does not conflict with people and land. Reducing the rise in water temperature reduces evaporation and helps preserve fresh water and reduces fog damage in the surrounding area. In addition, it is effective to improve water quality by promoting convection of water by temperature difference due to shade of water-state power generation system and preventing green tide. Shade by water-condition lighting power generation system protects fish resources by providing fishes with spawning places, .

Generally, a water-state photovoltaic power generating system includes a floating structure suspended on a water surface, a solar photovoltaic device mounted on an upper portion of the floating structure to generate electric energy by sunlight, Direction, as well as moving up and down according to the water level.

In Korean Patent No. 10-1134289 (hereinafter referred to as Prior Art 1) (hereinafter referred to as Prior Art 1), a plurality of pontoons made of buoyancy material are arranged in the forward direction, vertical connecting frames are connected in the vertical direction, An aquamarine solar power generation system in which horizontal support frames are arranged in a horizontal direction and horizontal support frames and support frames are arranged on top of a horizontal connection frame and a vertical connection frame and first and second solar battery modules are arranged in support frames, Lt; / RTI > In the prior art 1, the pontoons, which are buoyant materials, are connected to the horizontal connection frame and the vertical connection frame to firmly support the first and second solar battery modules. However, when a wave occurs on the surface due to a storm, The horizontal connection frame and the vertical connection frame that connect to each other can not flexibly move according to the wave of the water surface, so that the horizontal connection frame and the vertical connection frame may be damaged. If the cross-sectional size is increased to increase the strength of the horizontal connection frame and the vertical connection frame, the weight of the horizontal connection frame and the vertical connection frame increases to increase the volume of the pontoons. There is a problem that it increases.

In Korean Patent Laid-Open Publication No. 2016-0001106 (published on June 6, 2016) (hereinafter referred to as Prior Art 2), a support body supporting a plurality of solar panels on the water surface by buoyancy, A mooring rope for mooring the support, and a sinker for fixing the mooring rope to the underwater ground. The prior art 2 can be moored to the area where the support is set by the mooring rope. However, when the solar panels are installed on the waterfront on a large scale, not only the support can be broken by the surf wave, but also the structure of the mooring ropes Is complicated.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a column-type flexible water-state photovoltaic power generation system in which solar cell modules can flexibly move according to a wave when a high- .

It is another object of the present invention to provide a flexible water-state photovoltaic power generation system in which a solar cell module can be installed on a watercraft on a large scale and a structure in water is simple and fixed.

In order to accomplish the object of the present invention, a plurality of mooring fixed columns fixed to an underwater ground and each having elevating mechanisms moving up and down according to a water level; Main connecting ropes connecting elevating mechanisms of two mooring fixed columns adjacent to each other of the mooring fixed columns; Auxiliary connection ropes connecting the main connection ropes in a lateral direction and a vertical direction; A support floating structure positioned in at least one unit area of the square unit areas formed by the main connection ropes and the auxiliary connection ropes or by the auxiliary connection ropes; A solar cell module mounted on the supporting structure; And a unit connecting mechanism for connecting the supporting suspension structure and the auxiliary connection ropes connecting the main connection ropes forming the unit area and the auxiliary suspension ropes to fix the supporting suspension structure, .

The crossing portions of the main connecting ropes and the auxiliary connecting ropes or the intersecting portions of the auxiliary connecting ropes forming the rectangular unit area are preferably connected and fixed by fixing means.

The mooring type fixing columns are arranged so as to form a quadrangle, wherein at least two mooring fixing columns are arranged on one side of the quadrangle, and one side of the quadrangle in which the two or more mooring fixing columns are arranged, It is preferable to be positioned so as to be oriented.

It is preferable that a plurality of the suspended structures for supporting are located in the rectangular unit area.

A plurality of mooring fixed columns fixed to the underwater ground and each having elevating mechanisms moving up and down according to a water level; Main connecting ropes connecting the elevating mechanisms of two mooring fixed columns adjacent to each other among the mooring fixing columns, wherein two adjacent ropes are positioned side by side; Supporting floating structures positioned between two adjacent main connecting ropes of the main connecting ropes; A solar cell module mounted on the supporting structure; And a unit connection mechanism for connecting the support floating structure to the main connection ropes and fixing the support floating structure to the main connection ropes.

A plurality of mooring fixed columns fixed to the underwater ground so as to be arranged in a plurality of lattice forms and each having elevating mechanisms moving up and down according to a water level; Main connecting ropes connecting elevating mechanisms of two mooring fixed columns adjacent to each other of the mooring fixed columns; A plurality of support floating structures provided in at least one unit area of the rectangular unit areas formed by the main connection ropes; A solar cell module mounted on the floating structure for support; And unit connecting mechanisms connecting the main connecting ropes and the supporting floating structure or connecting the two floating supporting structures adjacent to each other.

It is preferable that a plurality of solar cell modules are provided on the supporting structure for supporting.

The mooring fixed columns are preferably positioned to form a quadrangle.

The unit connection mechanism is preferably a rope, a chain, a connecting rod, a hook, or a compression clamp.

Since the present invention is connected by a plurality of main connection ropes each of which is provided with the solar cell module (s), auxiliary connection ropes and main connection ropes are moored by the mooring fixed columns, a high wave The floating structures that support the solar cell modules according to the waves are flexibly moved along the waves to minimize the forces acting on the supporting floating structures by the waves. This increases the stability of the entire system.

In addition, since the present invention supports a plurality of supporting floating structures by mooring fixed columns, main connecting ropes, auxiliary connecting ropes and unit connecting mechanisms, installation cost for installing a large-scale power generation system is minimized .

Further, since the auxiliary connecting ropes, the unit connecting mechanisms and the supporting floating structures are located inside the main connecting ropes connecting the plurality of mooring-type fixing columns and the mooring-type fixing columns, and the mooring-type fixing columns are provided In a large-scale system, the structure in water is simplified.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view showing a first embodiment of a column-fixed flexible water-
FIG. 2 is a side view showing a first embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention,
FIG. 3 is a plan view showing a plurality of support floating structures in a unit area constituting the first embodiment of the column-fixed flexible water-state photovoltaic power generation system according to the present invention,
FIG. 4 is a plan view showing a second embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention,
FIG. 5 is a plan view showing a third embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention,
6 is a plan view showing a fourth embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention will be described with reference to the accompanying drawings.

1 is a plan view showing a first embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention. FIG. 2 is a side view showing a first embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention.

1 and 2, a first embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention includes mooring fixed columns 10, main connection ropes 20, (30), a floating structure for support (40), a solar cell module (50), and unit connection mechanisms (60).

The mooring fixed columns 10 are fixed to the underwater ground where the solar power generation system is to be installed and include a lift mechanism F. [ The mooring fixed columns 10 are preferably arranged in a rectangular shape. The mooring type fixed columns 10 include a fixed column S fixed to the underwater ground and an elevating mechanism F provided on the fixed column S and moving up and down according to the water level. There are a plurality of elevator mechanisms (F). As an example of the elevating mechanism F, the elevating mechanism F includes a float slidably inserted up and down along the fixed column S. In another example (not shown) of the elevating mechanism F, the elevating mechanism F includes two guide grooves provided in the fixed column S in the longitudinal direction of the fixed column S, Rollers positioned respectively on the rollers, and connection brackets connecting the rollers and connecting the ropes. The elevating mechanism F may be implemented in various forms.

The main connecting ropes 20 connect the elevating mechanism F of the two mooring fixed columns 10 adjacent to each other of the mooring fixed columns 10. The four mooring fixed columns 10 are referred to as first, second, third and fourth mooring fixed columns 11, 12, 13 and 14 in the counterclockwise direction, The elevating mechanism F of the elevating mechanism 12 is connected by the main connecting rope 21 and the elevating mechanism F of the second and third mooring fixing pillars 12 and 13 is connected to the main connecting rope 22 And the elevating mechanism F of the third and fourth mooring fixed columns 13 and 14 is connected by the main connecting rope 23 and the elevating mechanism F of the fourth and first mooring fixed columns 14 and 11 is connected by the main connecting rope 23, A ball F is connected by a main connecting rope 24. The main connecting rope 21 connecting the elevating mechanism F of the first and second mooring fixed columns 11 and 12 is connected to the first main connecting rope 21 and the first main connecting rope 21 in the counterclockwise direction Second, third and fourth main connecting ropes 22, 23 and 24, respectively. The main connecting ropes may each be a chain.

The auxiliary connecting ropes 30 connect the main connecting ropes 20 in the lateral direction and the longitudinal direction. That is, the first main connecting rope 21 and the third main connecting rope 23 are connected to the auxiliary connecting ropes, and the first and third main connecting ropes 21 and 23, do. The auxiliary connecting rope connecting the first and third main connecting ropes 21 and 23 is referred to as a lateral auxiliary connecting rope 31. [ It is preferable that the transverse auxiliary connecting ropes 31 are located at uniform intervals. The second and fourth main connecting ropes 22 and 24 are connected to the auxiliary connecting ropes at a distance in the longitudinal direction of the second and fourth main connecting ropes 22 and 24. And the auxiliary connecting rope connecting the second and fourth main connecting ropes 22 and 24 is referred to as a vertical auxiliary connecting rope 32. [ It is preferable that the vertical auxiliary connecting ropes 32 are located at equal intervals. Each of the auxiliary connection ropes 30 may be a chain.

The first, second, third and fourth main connection ropes 21, 22, 23 and 24 and the auxiliary auxiliary connection ropes 31 and the auxiliary auxiliary connection ropes 32 are connected to the first, And four main connecting ropes 21, 22, 23, and 24 are formed. The crossing portions of the main connecting ropes 20 and the auxiliary connecting ropes 30 or the intersecting portions of the auxiliary connecting ropes 30 forming the rectangular unit area are connected and fixed by the fixing means 33. The fixing means 33 is preferably a wire.

The support floating structure 40 is located in at least one unit area of the rectangular unit areas formed by the main connection ropes 20 and the auxiliary connection ropes 30 or the auxiliary connection ropes 30, Lt; / RTI > The supporting structure 40 for supporting includes a plurality of floating members 41 floating on the water phase and a base frame 42 connecting the plurality of floating members 41 do.

The solar cell module 50 is installed on the floating structure 40 for supporting. It is preferable that a supporting frame is provided on the supporting structure 40 and the solar cell module 50 is installed on the supporting frame. The solar cell module 50 receives sunlight to generate electric energy. A plurality of solar cell modules 50 may be installed on the supporting structure 40 for supporting.

The unit connecting mechanisms 60 connect the main connecting ropes 20 and the auxiliary connecting ropes 30 forming the unit area to the supporting floating structure 40 or connect the auxiliary connecting ropes 30 Thereby fixing the floating structure 40 for support. It is preferable that the unit connection mechanisms 60 are located at a uniform interval. The unit connection mechanisms 60 may each be a rope, a chain, a connecting rod, a hook, or a compression clamp.

3, a plurality of support floating structures 40 are located in the unit area and a plurality of support floating structures 40 are connected to each other by the unit connection mechanisms 60, The floating structures 40 are connected to the main connection ropes 20 and the auxiliary connection ropes 30 forming the rectangular unit area by the unit connection mechanisms 60 or connected to the auxiliary connection ropes 30 do. It is preferable that the plurality of support floating structures 40 are arranged in a square within a unit area of a quadrangle. The solar cell module 50 is installed in each of the plurality of support floating structures 40 located in the unit area of the square.

The fixed pile (s) 75 are fixed to the underwater ground so as to be positioned adjacent to the mooring fixed column 10 and the supporting wire 76 connects the fixed pile 75 and the mooring fixed column 10, It is preferable to support the fixed post 10.

4 is a plan view showing a second embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention.

4, a second embodiment of the column-fixed flexible water-state photovoltaic power generation system according to the present invention includes mooring fixed columns 10, main connection ropes 20, auxiliary connection ropes 30, the support structure 40, the solar cell module 50, and the unit connection mechanisms 60. The mooring fixed columns 10 are arranged in a plurality of rows so as to form a plurality of squares.

The mooring fixed columns 10 are fixed to the underwater ground where the solar power generation system is to be installed and include a lift mechanism F. [ The mooring fixed columns 10 are arranged in a plurality of rows to form a plurality of squares. When the mooring fixed columns 10 are formed into two squares, the mooring fixed columns 10 are arranged in three rows (refer to FIG. 4), and the mooring fixed columns 10 are six . The mooring type fixed columns 10 include a fixed column S fixed to the underwater ground and an elevating mechanism F provided on the fixed column S and moving up and down according to the water level. There are a plurality of elevator mechanisms (F). The elevating mechanism F is the same as the elevating mechanism F of the first embodiment. The elevating mechanism F may be implemented in various forms.

The main connecting ropes 20 connect elevating mechanisms of two mooring fixed columns 10 adjacent to each other of the mooring fixed columns 10. [ When three rows of mooring fixed columns 10 are arranged, there are two main connecting ropes 20 connecting the columns and the two main connecting ropes 20 are positioned in a straight line. The three columns of moored suspended structures 10 are referred to as the first, second, and third columns from the left.

The auxiliary connecting ropes 30 connect the main connecting ropes 20 in the lateral direction and the longitudinal direction. A plurality of auxiliary auxiliary connecting ropes 20a, 20b, 20c, 20d, 20m, 20m, 20m, 20m, 20m, 20m, 20m, It is preferable that the spacing between the electrodes is uniform. A plurality of auxiliary auxiliary connecting ropes are disposed in the vertical direction and are spaced apart from each other by a horizontal auxiliary connecting rope connecting the two main connecting ropes 20 facing each other, It is preferable that the spacing between the electrodes is uniform. Each of the auxiliary connection ropes 30 may be a chain.

Main connection ropes 20 and auxiliary connection ropes 30 (horizontal auxiliary connection ropes and vertical auxiliary connection ropes) and auxiliary connection ropes 30 (horizontal auxiliary connection ropes 30, And the vertical auxiliary connection ropes). The crossing portions of the main connecting ropes 20 and the auxiliary connecting ropes 30 or the intersecting portions of the auxiliary connecting ropes 30 forming the rectangular unit area are connected and fixed by the fixing means 33. The fixing means 33 is preferably a wire.

It is preferable that one or more mooring fixed columns 10 are additionally arranged in three rows of the mooring fixed columns 10, respectively. It is preferable that the mooring fixed columns 10 arranged in each column are the same number as each other. The mooring fixed column (s) 10 further arranged in each row of the mooring fixed columns 10 are preferably located at the portion where the main connecting rope 20 meets the transverse auxiliary connecting ropes 30. On the other hand, the mooring fixed column (s) which are additionally arranged in each row of the mooring fixed columns 10 may be located beside the portions where the main connecting ropes 20 and the transverse auxiliary connecting ropes 30 meet. Fig. 4 shows three mooring fixed columns 10 arranged in each column. The three additional mooring fixing columns 10 are connected to the main connecting rope 20 and the lateral auxiliary connecting ropes 30 As shown in FIG.

The support floating structure 40 is located in at least one unit area of the rectangular unit areas formed by the main connection ropes 20 and the auxiliary connection ropes 30 or the auxiliary connection ropes 30, Lt; / RTI > It is preferable that the floating structure 40 for support is formed in a rectangular shape. The supporting structure 40 for supporting includes a plurality of floating members 41 floating on the water phase and a base frame 42 connecting the plurality of floating members 41 do.

The solar cell module 50 is installed on the floating structure 40 for supporting. It is preferable that a supporting frame is provided on the supporting structure 40 and the solar cell module 50 is installed on the supporting frame. The solar cell module 50 receives sunlight to generate electric energy. A plurality of solar cell modules 50 may be installed on the supporting structure 40 for supporting.

The unit connecting mechanisms 60 connect the auxiliary connecting ropes 30 with the main connecting ropes 20 forming the unit area with the supporting floating structure 40 or connect the auxiliary connecting ropes 30 Thereby fixing the floating structure 40 for support. It is preferable that the unit connection mechanisms 60 are located at a uniform interval. The unit connection mechanisms 60 may each be a rope, a chain, a connecting rod, a hook, or a compression clamp.

A plurality of support floating structures 40 may be located in a rectangular unit area.

The fixed pile (s) 75 are fixed to the underwater ground so as to be positioned adjacent to the mooring fixed column 10 and the supporting wire 76 connects the fixed pile 75 and the mooring fixed column 10, It is preferable to support the fixing post 10 (see FIG. 2). It is preferable that the fixed pile and the supporting wire are respectively provided on the mooring fixed columns 10 located at the corner portions.

The second embodiment of the column-fixed flexible water-state photovoltaic power generation system according to the present invention is preferably installed in a river having a weak flow rate. At this time, the water in which two or more mooring fixed columns 10 are arranged is installed in the water so as to be located in the vertical direction in which the water flows.

5 is a plan view showing a third embodiment of a column-fixed flexible water-state photovoltaic power generation system according to the present invention.

5, the third embodiment of the column-fixed flexible water-state photovoltaic power generation system according to the present invention includes mooring fixed columns 10, main connection ropes 20, floating structure for support 40, a solar cell module 50, and unit connection mechanisms 60.

The mooring fixed columns 10 are fixed to the underwater ground where the solar power generation system is to be installed and include a lift mechanism F. [ The mooring type fixing columns 10 are arranged in a plurality of rows, and the same number of mooring type fixing columns 10 are arranged in each column. For example, the mooring fixed columns 10 are arranged in three rows, each column having four mooring fixed columns 10 arranged. If the three columns are the first, second, and third columns from the left, the mooring fluids in each row are sequentially placed in the first, second, third, and fourth mooring fixed columns 15, 16, 17, The first, second, third and fourth mooring fixed columns 15, 16, 17 and 18 of each row are preferably located on the same straight line. The mooring type fixed columns 10 include a fixed column S fixed to the underwater ground and an elevating mechanism F provided on the fixed column S and moving up and down according to the water level. There are a plurality of elevator mechanisms (F). The elevating mechanism F is the same as the elevating mechanism F of the first embodiment. The elevating mechanism F may be implemented in various forms.

The main connecting ropes 20 connect the elevating mechanisms F of the mooring fixed columns 10 between two adjacent rows and columns among the mooring fixed columns 10 in a one-to-one relationship. For example, when the mooring fixed columns 10 are arranged in three rows and four mooring fixed columns 10 are arranged in each column, the first mooring fixed column 15 of the first row and the second row The first mooring fixed column 15 is connected by the main connecting rope and the first mooring fixed column 15 of the second row and the first mooring fixed column 15 of the third row are connected by the main connecting rope And the two main connecting ropes are preferably located on the same line. The main connecting ropes 20 are connected in the same manner to the second, third, and fourth mooring floating structures 16, 17, and 18 in each row. The main connecting ropes 20 may each be a chain.

The supporting floating structure 40 is positioned between two adjacent main connecting ropes 20 and floats on the water. A plurality of supportive floating structures 40 are provided at intervals between two main connection ropes 20 adjacent to each other. It is preferable that the plurality of support floating structures 40 positioned between the two main connection ropes 20 are arranged in a line or arranged in a plurality of rows along the main connection ropes 20. [ It is preferable that the floating structure 40 for support is formed in a rectangular shape. The supporting structure 40 for supporting includes a plurality of floating members 41 floating on the water phase and a base frame 42 connecting the plurality of floating members 41 do.

The solar cell module 50 is installed on the floating structure 40 for supporting. It is preferable that a supporting frame is provided on the supporting structure 40 and the solar cell module 50 is installed on the supporting frame. The solar cell module 50 receives sunlight to generate electric energy. A plurality of solar cell modules 50 may be installed on the supporting structure 40 for supporting.

The unit connecting mechanisms 60 connect the supporting floating structure 40 and the main connecting ropes 20 positioned between the two main connecting ropes 20 to fix the supporting floating structure 40. It is preferable that the unit connection mechanisms 60 are located at a uniform interval. Two floating supporting structures 40 adjacent to each other when the floating structures 40 for supporting are arranged in a line or arranged in a plurality of rows between two main connection ropes 60 are connected to the unit connection mechanisms 60 . The unit connection mechanisms 60 may each be a rope, a chain, a connecting rod, a hook, or a compression clamp.

The fixed pile (s) 75 are fixed to the underwater ground so as to be positioned adjacent to the mooring fixed column 10 and the supporting wire 76 connects the fixed pile 75 and the mooring fixed column 10, It is preferable to support the fixing post 10 (see FIG. 2). It is preferable that the fixed pile and the supporting wire are respectively connected to the mooring fixed columns 10 located at the corner portions.

The third embodiment of the present invention excludes the auxiliary connecting ropes and simplifies the structure of the first and second embodiments of the present invention.

6 is a plan view showing a fourth embodiment of a column-fixed flexible water condition lighting system according to the present invention.

6, a third embodiment of the column-fixed flexible water-state photovoltaic power generation system according to the present invention includes mooring fixed columns 10, main connection ropes 20, supportive floating structures (40), a solar cell module (50), and unit connection mechanisms (60).

The mooring fixed columns 10 are fixed to the underwater ground where the solar power generation system is to be installed and include a lift mechanism F. [ The mooring fixed columns 10 float on the water column where the PV system will be installed. The mooring fixed columns 10 are arranged in a plurality of grid shapes like a checkerboard. The mooring type fixed columns 10 include a fixed column S fixed to the underwater ground and an elevating mechanism F provided on the fixed column S and moving up and down according to the water level. There are a plurality of elevator mechanisms (F). The elevating mechanism F is the same as the elevating mechanism F of the first embodiment. The elevating mechanism F may be implemented in various forms.

The main connecting ropes 20 connect two adjacent mooring fixed posts 10 of the mooring fixed columns 10, respectively. The mooring fixed columns 10 are formed with a plurality of rectangular unit areas by the connected main connection ropes 20. [ The main connecting rope may be a chain.

The supporting floating structures 40 are provided in at least one unit area of the rectangular unit areas formed by the main connection ropes 20. [ The floating structure 40 for supporting is the same as the floating structure for supporting in the third embodiment.

A plurality of solar cell modules (50) are provided in each of the supporting suspended structures (40).

The unit connection mechanisms 60 connect the main connecting ropes 20 and the supporting floating structure 40 or the two supporting floating structures 40 adjacent to each other. The unit connection mechanism 60 may be a rope, a chain, a connecting rod, a hook, or a clamping clamp.

The fixed pile (s) 75 are fixed to the underwater ground so as to be positioned adjacent to the mooring fixed column 10 and the supporting wire 76 connects the fixed pile 75 and the mooring fixed column 10, It is preferable to support the fixing post 10 (see FIG. 2). It is preferable that the fixed pile and the supporting wire are respectively provided on the mooring fixed columns 10 located at the outer periphery.

Hereinafter, the operation and effects of the column-fixed flexible water-state photovoltaic power generation system will be described.

The column-fixed flexible water-state photovoltaic power generation system according to the present invention is installed in water ponds such as rivers, lakes, dams, coastal waters (e.g., Gwangyang Bay, etc.). The column-fixed flexible water-state photovoltaic power generation system according to the present invention generates electric energy from sunlight in the solar cell module 50 installed in each of the floating structures 40 for support in a state where the water-pumped water-

The present invention is characterized in that a plurality of mooring type fixing columns 10 are fixed to an underwater ground and a plurality of mooring type fixing columns 10 are connected by main connection ropes 20 and inside of main connection ropes 20 The auxiliary connecting ropes 30 are connected in the transverse direction and the longitudinal direction and are connected to the unit areas formed by the main connecting ropes 20 and the auxiliary connecting ropes 30 or the auxiliary connecting ropes 30, Since the floating structure (s) 40 are connected by the unit connection mechanisms 60 and the solar cell module 50 is installed in the supporting floating structure 40, the plurality of solar cell modules 50 can be stably And the solar cell modules 50 can be installed on a large scale.

In addition, the present invention is characterized in that a plurality of main connection ropes 20, auxiliary connection ropes 30, unit connection mechanisms 60, When the connection ropes 20 are moored by the mooring fixed columns 10, when a high wave is generated in the water due to the storm, the support floating structures 40, in which the solar cell module 50 is installed according to the waves, So that the force acting on the supportive floating structures 40 by the waves is minimized. This increases the stability of the entire system.

The present invention also includes a plurality of supporting floating structures 40 by mooring fixed columns 10, main connecting ropes 20, auxiliary connecting ropes 30 and unit connecting mechanisms 60 Thereby minimizing the installation cost required for installing a large-scale power generation system.

In addition, the present invention is characterized in that auxiliary connecting ropes (30) and unit connection mechanisms (30) are formed inside of main connecting ropes (20) connecting a plurality of mooring fixed columns (10) (60) and the supportive floating structures (40) are positioned, so that the structure in the water is simplified in a large scale system.

10; Mooring fixed columns 20; Main connection ropes
30; Auxiliary connection ropes 40; Floating structure for support
50; A solar cell module 60; Unit connection mechanisms

Claims (9)

A plurality of mooring fixed columns fixed to the underwater ground and each having elevating mechanisms moving up and down according to a water level; and a plurality of mooring fixed columns, Main connecting ropes, auxiliary connecting ropes connecting the main connecting ropes in the horizontal direction and the vertical direction, and auxiliary connecting ropes formed by the main connecting ropes and the auxiliary connecting ropes or formed by the auxiliary connecting ropes A solar cell module mounted on the supporting structure for supporting, the solar cell module comprising: a supporting structure for supporting at least one of unit areas of a rectangular unit area; And unit connecting mechanisms for connecting the floating structure for support and the auxiliary connection ropes connecting the main connection ropes forming the unit region and the auxiliary connection ropes,
The crossing portions of the main connecting ropes and the auxiliary connecting ropes or the intersecting portions of the auxiliary connecting ropes are fixed by fixing means,
A plurality of the floating structures for supporting are arranged in a rectangular unit area,
The auxiliary connection rope is divided into a horizontal auxiliary connection rope and a vertical auxiliary connection, and each of the auxiliary connection ropes is located at a uniform interval,
The unit connection mechanisms are disposed at uniform intervals,
The structure for supporting the floating structure and the main connection rope or the floating structure for support and the auxiliary connection ropes are connected through a plurality of unit connection mechanisms A pillar fixed type flexible water condition lighting power generation system containing. delete delete delete [2] The apparatus according to claim 1, wherein the mooring fixing posts are arranged to form a quadrangle, wherein at least two mooring fixing columns are arranged on one side of the quadrangle, and one side of the quadrangle on which the two or more mooring fixing columns are arranged And is positioned so as to be perpendicular to the direction in which the water flows. delete The pillar-fixed flexible water-state photovoltaic power generation system according to claim 1, wherein a plurality of solar cell modules are provided on the floating structure for support. The system of claim 1, wherein the mooring fixed columns are square. The system of claim 1, wherein the unit connection mechanism is a rope, a chain, a connecting rod, a hook, or a compression clamp.

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