KR101827520B1 - Block assembly type photovoltaic power generation apparatus - Google Patents

Abstract

In the present invention, the solar module is mounted on a buoyant body floating on the water surface, and is assembled in a predetermined block unit, while a connecting passage is provided in a block unit, but the connecting portion between the buoyant body and the connecting passage maintains a coupled state regardless of a wave.
The present invention provides a buoyancy body having an inner space formed with a predetermined width and formed with a heat discharge hole vertically passing through the center thereof and a flange having a connecting hole formed at an edge thereof to protrude, A buckling member having a buoyancy between the buoyancy member and a flange protruding from an edge portion of the buoyancy member so as to be connected to a flange of the buoyancy member, The flange of the sieve and the flange of the connecting passage are overlapped with each other so that the connecting holes are made to coincide with each other, the cylindrical urethane rubber is inserted into the connecting hole and the hollow bolt is fixed to the inside of the urethane rubber.

Description

[0001] The present invention relates to a block assembly type photovoltaic power generation apparatus,

In the present invention, the solar module is mounted on a buoyant body floating on the water surface, and is assembled in a predetermined block unit, while a connecting passage is provided in a block unit, but the connecting portion between the buoyant body and the connecting passage maintains a coupled state regardless of a wave.

In recent years, photovoltaic power generation facilities have been widely used. However, in order to generate large-scale photovoltaic power generation, a wide range of photovoltaic power generation facilities Because it requires an area, securing the site is not easy and it has a bad influence on the environment.

In order to solve this problem, a water photovoltaic power generation device is used. In a water photovoltaic power generating device, a solar cell module is installed in a place made of a buoyant body after connecting a buoyant body having a buoyancy with a certain area. The buoyant body and the buoyant body must be connected so as not to be damaged by the flow of the wave, while the weight of the solar module installed on the upper part must be able to withstand and the solar module should not be heated.

In addition, when the solar module is installed continuously, the manpower necessary for the maintenance of the solar module is not easily accessible to the solar module, and the area for installing the solar module on the water surface is also freely freely In particular, since the buoyant body is installed on the water surface and the buoyant body is connected to each other, there is a problem that the portion connecting the buoyant body is broken or damaged due to the influence of the wave generated by the wind .

Korea Patent Registration No. 10-1170777 (Registered July 27, 2012) Korea Patent Registration No. 10-1171683 (Registered July 30, 2012) Korea Patent Registration No. 10-1535511 (Registered on July 3, 2015) Korea Patent Registration 10-1562814 (Registered on October 19, 2015)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a solar module on the upper portion of a buoyancy body, And the connecting portion of the buoyant body and the connecting passage and the connecting passage are kept connected to the change of the height of the wave caused by the wind while preventing the breakage or damage from occurring. So that breakage or damage does not occur due to the elasticity of the urethane rubber even if the angle is maintained at different angles by the wave.

The present invention provides a buoyancy body having an inner space formed with a predetermined width and formed with a heat discharge hole vertically passing through the center thereof and a flange having a connecting hole formed at an edge thereof to protrude, A buckling member having a buoyancy between the buoyancy member and a flange protruding from an edge portion of the buoyancy member so as to be connected to a flange of the buoyancy member, The flange of the sieve and the flange of the connecting passage are overlapped with each other to make the connecting holes coincide with each other, the cylindrical urethane rubber is inserted into the connecting hole and the hollow bolt is fixed to the inside of the urethane rubber.

The buoyant body is provided with a solar module on the upper side of the present invention. The buoyant body is connected between front and rear directions of the buoyant body by interposing a connection passage. A constant interval is maintained in the lateral direction of the buoyant body, A cylindrical urethane rubber is inserted into the hole of the flange, and a hollow bolt is inserted through the urethane rubber. At the upper and lower sides of the hollow bolt, a hollow nut is provided on the outer side of the flange So that the connection state can be maintained without being damaged or damaged by the elasticity of the urethane rubber even if the buoyant body and the connection channel are kept at different angles by the wave.

In the present invention, a solar module is mounted on an upper side of a buoyant body so as to be connected to each other by a connecting passage in forward and backward directions, thereby preventing a solar module from being shaded by shadows and being utilized as a passageway of an operator. A heat exhaust hole is vertically formed at the center so that heat generated from the solar module can be easily discharged and the shaking of the water can be relieved, and the buoyancy member and the connection passage are connected through the flange, The urethane rubber is inserted in the center of the buoyancy member so that the buoyancy member and the connection channel are distorted by the wave, so that the connection is not broken or damaged and the connection state is maintained.

In the present invention, the buoyant body to which the solar module is installed is connected to the solar module through the connection channel, and the solar module is adjacent to the solar module in the lateral direction. However, It is possible to easily increase or decrease the installation area because the number of solar modules of the block can be changed variously.

1 is a perspective view showing a state in which a solar panel is installed in a buoyant body according to the present invention,
FIG. 2 is a perspective view of a solar panel according to the present invention in a state where a buoyant body and a connection path are connected to form a certain block.
3 is a side view showing a connection state between the buoyancy member and the connection passage of the present invention
4 is a side elevation view of the flange connection portion of the present invention
FIG. 5 is a cross-sectional view illustrating the flange connection portion of the present invention
6 is a cross-sectional view of the flange of the present invention
7 is a cross-sectional view of the flange of the present invention in which the urethane rubber is inserted into the connection hole
8 is a cross-sectional view of the urethane rubber of the present invention with a hollow bolt inserted therein
9 is a cross-sectional view of the hollow bolt of the present invention with a hollow nut inserted therein

The present invention is characterized in that a space filled with air is formed in a buoyant body having a predetermined thickness in a rectangular shape and has a buoyancy and a center of the buoyant body forms a heat exhaust hole penetrating up and down, A flange protruding laterally is formed at a corner portion, and a connection hole is formed at the center of the flange.

In the buoyant body of the present invention, a steel band fixing the solar modules to the upper front and rear sides is fixed, and the solar modules, which are fixed to be fixed to the steel band by forming a lower front and a higher rear, To be exposed.

The connecting passage of the present invention is formed in a rectangular shape and has a predetermined thickness but forms a space filled with air therein while a non-slip projection is formed on the surface of the connecting passage, and a flange protruding laterally is formed at a corner of the connecting passage The flange is formed with a height difference so as to overlap with the flange of the buoyant body, and a connecting hole through which the urethane rubber is fitted is formed at the center of the flange.

The buoyant body of the present invention is connected to the connecting passage through a flange. The flange of the buoyant body and the flange of the connecting passage are made to overlap with each other. Then, the cylindrical urethane rubber is inserted into the connecting hole of the flange, And a hollow nut is fitted to the outer side of the flange on both sides of the hollow bolt to prevent the hollow bolt from being detached from the urethane rubber.

In the present invention, a solar module is mounted at an angle using a steel band fixed on the upper side of a buoyant body, and a connecting passage is connected to the buoyant body in a forward and backward direction. The flange of the connecting passage is overlapped with the buoyant body. After inserting a cylindrical urethane rubber inside, insert a hollow bolt into the urethane rubber and insert a hollow nut into the hollow bolt from the outside of the flange.

Here, the photovoltaic module connects the buoyant body to the connection channel so as to maintain the state close to the side, and the space is secured by the connection channel so that the shadow does not occur in the forward and backward directions of the buoyant body.

A plurality of solar modules installed in a buoyant body may be collected to form one block, a plurality of blocks may be installed continuously, or a number of solar modules may be increased or decreased. The increase in the number and the installation area of the block can be freely adjusted.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention is based on the fact that solar power is generated by installing the solar module 10 on the water surface and the amount of power generation is determined according to the installation area of the solar module 10, , So that damage or damage is not caused by the wave after the work.

In the present invention, the solar module 10 is installed on the upper portion of the buoyant body 20, and has a rectangular shape and is formed with a buoyant body 20 in which a space for providing buoyancy is filled with air inside, A heat exhaust hole 21 is formed at the center of the heat exchanger 20 and a flange 22 is formed at a corner of the flange 22 so as to protrude laterally and a connection hole 23 is formed in the flange 22.

The heat exhaust hole 21 formed at the center of the buoyant body 20 exposes the heat generated in the solar module 10 during the power generation process to the surface of the water to rapidly dissipate the heat and to stabilize the shaking of the water do.

The solar cell module 10 fixed to the steel band 11 by being fixed to the buoyant body 20 of the present invention by fixing the steel band 11 to the upper side and varying the height of the front and rear steel band bands 11, And the solar module 10 does not protrude forward and rearward of the buoyant body 20 but partially protrudes from the side surface of the buoyant body 20 so that the side surface of the solar module 10 The buoyant body 20 should be installed with a certain distance in the lateral direction.

Since the buoyant body 20 of the present invention has a heat exhaust hole 21 formed at the center thereof and a certain space is separated when the buoyant body 20 and the buoyant body 20 are laterally connected, It is possible to cool the heat radiating from the cold air of the water by using the cold air of the water and also to calm the water shake.

The buoyant body 20 of the present invention connects the connection passages 30 in the forward and backward directions so that the solar modules 10 are spaced apart from each other by a predetermined distance in the forward and backward directions to avoid the influence of shadows, So that repair or repair of the solar module 10 can be performed while the operator moves.

The connecting passage 30 of the present invention is formed with a space filled with air therein while a flange 32 protrudes at a corner portion and a connection hole 33 is formed in the flange 32, The flange 22 formed on the body 20 and the flange 32 formed on the connection path 30 are changed in height and tilt so as to be overlapped and connected to each other.

The flange 22 of the buoyant body 20 and the flange 32 of the connecting passage 30 are overlapped with each other and the flange 22 and the flange 22 are made to have different heights so that the buoyant body 20 and the connecting passage 30, So that the flanges 22 and 32 can be overlapped while maintaining the same height while the cylindrical urethane rubber 40 is fitted to the connecting holes 23 and 33 when the flanges 22 and 32 are overlapped. A hollow bolt 50 is inserted into the urethane rubber 40 and a hollow nut 51 is inserted into both ends of the hollow bolt 50. The hollow nut 51 is inserted into flanges 22 and 32 And is larger than the diameter of the connecting hole 23 (33).

The urethane rubber 40 of the present invention has a cylindrical shape and is inserted into the connection holes 23 and 33 of the flanges 22 and 32 on the outer side while the hollow bolt 50 is inserted inward. When the buoyant body 20 and the connecting passage 30 are swung by waves at different angles due to the wave in the state where the connecting channel 20 and the connecting channel 30 are connected to each other, The flange 22 and the flange 22 are prevented from being damaged or damaged by the elasticity of the flange 22 and the flange 22, .

In the present invention, a plurality of solar modules 10 constitute one block, and one block can constitute an outer perimeter as a whole by the connection passage 30, so that the number of installed solar modules 10 constituting the blocks It is easy to increase or decrease the area, and the desired area can be covered with the solar module 10 to control the solar power generation amount.

The flange 22 protruding forward and backward from the edge of the buoyant body 20 is overlapped with the flange 32 protruding from the corner of the connection passage 30 and the flange 22 The hollow bolts 50 are inserted into the urethane rubber 40 after fitting the cylindrical urethane rubber 40 into the connecting holes 23 and 33 in the state where the connecting holes 23 and 33 of the rivets 32 and 32 are aligned with each other. The hollow nut 51 is inserted into the hollow bolt 50 while the hollow nut 51 is positioned on the outer side of the flange 22 and the hollow nut 51 is inserted into the hollow nut 51, The connection is made.

The solar panel 10 is inclined and fixed to the upper portion of the buoyant body 20 using a steel band 11. The solar panel 10 receives solar light in a sloped state, The electricity thus developed is collected after being collected by an unillustrated rechargeable battery or the like.

The buoyant body 20 can be installed in a desired line in the forward and backward direction while continuously fixing a desired number of the buoyant body 20 in a lateral direction. The solar module 10 fixed on the buoyant body 20 has a predetermined area And the block having the predetermined area is changed into blocks so that the desired area and desired power generation amount can be obtained by changing the number of installed solar modules 10.

The flange 22 of the buoyant body 20 and the flange 32 of the connecting passage 30 are connected to each other by the urethane The urethane rubber 40 is fitted and fixed to the hollow bolt 50 so that the flange 22 (32 The connection of the buoyant body 20 and the connection passage 30 at a considerable angle without damaging or damaging the flanges 22 and 32 due to the elasticity of the urethane rubber 40 sandwiched between the connection holes 23 and 33 State can be maintained.

Accordingly, although it may be a problem in a place where high waves such as the sea are hit, the connection state is not released due to a deviation angle in which the buoyant body 20 of the present invention and the connection passage 30, As a matter of course, damage to the flanges 22, 32 is also prevented by the highly elastic urethane rubber 40.

The present invention is characterized in that a connecting passage 30 is provided at the front and rear of the buoyant body 20 in which the solar module 10 is assembled into a block and the solar module 10 is installed, The connecting passage 30 is connected to the side of the connecting passage 30 so that the slip prevention protrusion 31 is formed on the upper side of the connecting passage 30 so that the operator can move without slipping, Can be guaranteed.

The buoyant body 20 of the present invention is formed of an injected plastic and is buoyant with the air filled in the inside of the buoyant body 20 to be able to install the solar module 10 and form the heat exhaust hole 21, The space between the buoyant body 20 and the buoyant body 20 can be opened to cool the heat generated by the solar module 10, It quickly stabilizes it when it occurs.

In the present invention, the buoyant body 20 provided with the solar module 10 is connected to the connection passage 30 to form one block. The altitude of the solar module 10 can be adjusted, So that the solar module 10 can be positioned according to the azimuth angle of the sun to obtain optimal power generation efficiency regardless of the season and the time.

10: solar module 11: section steel band
20: Buoyant body 21: Heat exhaust hole
22: flange 23: connecting hole
30: connection passage 32: flange
33: connection hole 40: urethane rubber
50: hollow bolt 51: hollow nut

Claims (4)

A solar module 10,
The solar module 10 is mounted on the upper portion of the buoyant body 10 so as to be inclined by a steel band 11 having a different height and a buoyant body 20 formed by injecting plastic with buoyancy into a space, Respectively,
A heat exhaust hole 21 for exhausting heat is vertically formed at the center of the buoyant body 20 and a flange 22 having a connection hole 23 formed at each corner of the buoyant body 20 is protruded And the flange 22 of the buoyant body 20 is disposed at a position different from that of the flange 32 of the connection passage 30 so that the flange 22 of the buoyant body 20 and the flange 32 The float body 20 and the connecting passage 30 have the same height,
And a connecting passage 30 connected to the flange 22 of the buoyant body 20 and having a flange 32 having a connecting hole 33 at its four corners and injected with plastic,
The flange 32 of the connection passage 30 is different from the flange 22 of the buoyant body 20 so that the flange 32 of the connection passage 30 and the flange 22 of the buoyant body 20 The connecting passage 30 and the buoyant body 20 have the same height,
And a flange 22 of the buoyant body 20 and a flange 32 of the connecting passage 30 are overlapped with each other so as to be fitted into the connecting holes 23 and 33,
And a hollow bolt (50) inserted into the urethane rubber (40) and fixed by hollow nuts (51) outside the flanges (22) (32). delete delete The flange (22) formed at the four corners of the buoyant body (20) and the flange (32) formed at the four corners of the connection passage (30) The flange 22 and the flange 22 may be formed at different heights so that the buoyant body 20 and the connecting passage 30 maintain the same height and the connecting holes 23 The flanges 22 and 32 are fitted on the outer side of the urethane rubber 40. The hollow bolts 50 are inserted into the urethane rubber 40, A hollow nut 51 is inserted at the tip of the hollow bolt 50 and the hollow nut 51 is fixed to the outside of the flanges 22 and 32 to prevent the flanges 22 and 32 from being separated from each other. A block assembly type solar photovoltaic device.

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