KR20150136854A - Sunlight structure for stabilizing azimuth angle on water surface - Google Patents

Abstract

Disclosed is a water sunlight structure which can provide stabilization by maintaining an azimuth angle of a solar battery module arranged on the water. To this end, the water sunlight structure for stabilizing the azimuth angle of a solar battery module comprises: a solar battery module support portion which arranges a plurality of support structures for supporting the solar battery module on the water to be spaced at certain intervals; pulley portions coupled in parallel with first support structures arranged on both ends among a plurality of support structures through pulley coupling portions; anchor portions fixed in parallel onto the water corresponding to external angles of the first support structures; a mooring rope portion where one end which passes by the pulley portions is fixed into a first anchor portion among the anchor portions while the other end is fixed into a second anchor portion of an opposite side which faces the first anchor portion; and a weight portion moved in a water surface direction as the length of the mooring rope portion is lengthened when the water level is higher, and moved in a water surface downward direction as the length of the mooring rope portion is shortened when the water level is lower. Accordingly, the water sunlight structure of the present invention can fundamentally increase the sunlight generation amount by suppressing a change in locations of the support structure and a sunlight module, and the azimuth angle.

Description

≪ Desc / Clms Page number 1 > SUNLIGHT STRUCTURE FOR STABILIZING AZIMUTH ANGLE ON WATER SURFACE <

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an aquamarine structure, and more particularly, to an aquamarine structure capable of stabilizing an azimuth angle of a solar cell module disposed in an aquarium.

As fossil fuels such as petroleum and coal are depleted, alternative energy development is being actively pursued. In particular, development of energy resources utilizing solar energy has become more active.

Power generation technologies that utilize solar energy to produce electricity include solar power generation that uses solar heat to drive a heat engine to generate electricity, and solar power generation that generates electricity from solar cells using solar light.

Here, the solar cell used for solar power generation generally uses silicon and a composite material. Specifically, a solar cell uses a P-type semiconductor and an N-type semiconductor in combination, and utilizes a photoelectric effect to generate electricity by receiving sunlight.

Most of the solar cells are composed of large-area P-N junction diodes, and the electromotive force generated at the opposite ends of the P-N junction diode is connected to an external circuit. The smallest unit of such a solar cell is referred to as a cell. Actually, the solar cell is rarely used as a cell.

This is because the voltage from one cell is very small, about 0.5 V, compared to several tens or hundreds of volts (V) of voltage required for practical use. This is why a plurality of unit solar cells can be connected in series or parallel It was connected and used.

In addition, when the solar cell is used outdoors, it is subjected to various harsh environments. Therefore, in order to protect a large number of cells connected with a necessary unit capacity in a harsh environment, a solar cell module Respectively.

However, since the conventional solar cell module has to be used in a large amount in order to obtain a certain electric power, there are restrictions on the installation site, restriction on the deformation of the lower support structure depending on the arrangement structure of the solar cell module, There was no problem at the time of installation, but installation at the waterfront was not easy in terms of cost and technology, because many supporting structures were needed incidentally at the waterfront.

In spite of this unfortunate situation, a water photovoltaic structure for installing a large amount of photovoltaic module in a water pavilion was developed continuously. Among them, a buoyant body was installed to float a conventional solar photovoltaic structure from an aquarium, And the support structure for supporting the solar cell module is complicated and enlarged, thereby increasing the construction cost and manufacturing cost.

Above all, conventional solar photovoltaic structures have attempted to maintain the azimuth angle of the solar cell module by reducing mobility at the water surface by installing a mooring structure. However, when the water level fluctuates due to the causes such as the rain or flood, the mooring structure may be excessively strained or loosely deformed The breakage of the mooring structure or the position and the azimuth angle of the supporting structure are changed, ultimately the azimuth angle of the solar cell module is deformed and the generation amount is reduced.

1. Korea Registered Patent: No. 1377616, Registered Date: Mar. 18, 2014 Title of invention: Floating marine structure for photovoltaic power generation. 2. Korean Patent Publication No. 2012-0130810, Disclosure Date: December 04, 2012 Title of invention: Buoyant body preventing conduction of water-state power generation device.

The present invention provides a solar photovoltaic structure for stabilizing the azimuth angle of the mooring structure, which can change the movement of the mooring structure even if the water level fluctuates due to a cause such as rain or flood It has its purpose.

Another object of the present invention is to provide a solar photovoltaic structure having a triangular structure for supporting a solar cell module of an aquarium and having an open structure to support the solar cell module in a lightened state.

It is another object of the present invention to provide a water solar photovoltaic structure capable of reducing corrosion by forming a support structure for supporting a solar cell module on the top of a buoyant body.

The features of the present invention for achieving the objects of the present invention as described above and performing the characteristic functions of the present invention described below are as follows.

According to one aspect of the present invention, there is provided a solar photovoltaic structure for stabilizing the azimuth angle of a solar cell module, the solar cell module comprising: a solar cell module support part for arranging a plurality of support structures for supporting the solar cell module at a predetermined distance, ; A first support structure disposed at both ends of the plurality of support structures and coupled to the first support structure via a pulley coupling portion; An anchor portion that is fixed on the water surface corresponding to the outer periphery of the first support structure; A mooring rope portion having one end passing through the pulley portion fixed to the first anchor portion of the anchor portion and the other end fixed to the second anchor portion opposite to the first anchor portion; And a weighing part which moves in the water surface direction by increasing the length of the mooring rope part when the water level is increased and the length of the mooring rope part is shortened when the water level is lowered to move in the downward direction of the water surface.

Here, the pulley portion and the anchor portion according to one aspect of the present invention are arranged side by side in at least one pair of the plurality of support structures, and at least one of the mooring rope portion and the weight portion is arranged side by side in the plurality of support structures Structure.

According to an aspect of the present invention, the supporting structure may include a first triangular shape and a second triangular shape, each of which is opened at a lower portion thereof, so as to be spaced apart from each other at a predetermined interval, A frame body disposed on the frame body; A body extension extending in pairs below the first and second triangular shapes; A body fixing part which is formed in parallel to the lower side and the other side of the first and second triangular shapes in the cross direction of the body extension part and fixed to the lower part of the frame body part; A buoyant body part which is fitted to the body fixing part and is formed on the body fixing part in a state where only a part of the body is immersed in water; And a fixing frame portion formed at a position where the lower portion of the first and second triangular shapes intersect with the body fixing portion to fix the body fixing portion after drawing the buoyant body portion into the body fixing portion. .

According to an aspect of the present invention, the body fixing part and the fixing frame part are formed on the upper part of the buoyant body part floating on the water, and the lower part of the body extending part is located in the water together with a part of the buoyant body part. Lt; / RTI >

In addition, the support structure according to one aspect of the present invention may further include an extension fixing part formed by being fixed in pairs on one side and the other side of the body extension part.

The supporting structure according to one aspect of the present invention further includes a mooring connection portion for fixing the mooring loop passing through the mooring claw portion to the water surface or the ground after inserting the mooring claw portion into the extension fixing portion in the cross direction Lt; / RTI >

As described above, according to the present invention, when the water level is increased, the length of the mooring rope portion is lengthened and when the water level is lowered, the length of the mooring rope portion is shortened to keep the mooring structure constant in tension, The azimuthal variation can be suppressed, and ultimately, the solar power generation amount can be increased.

In addition, the present invention provides a support structure for installing a solar cell module due to the structure of a triangular support structure, for example, a frame body portion and a body extension portion, formed in pairs corresponding to one solar cell module, It is possible to reduce the weight of the support structure, thereby reducing the construction cost and the manufacturing cost of the support structure.

Further, since the support structure, for example, the frame body portion, the body fixing portion, and the fixed frame portion are provided on the upper portion of the buoyant body that is present in the water, the support structure can be firmly held in the water level, There is an effect that corrosion can be prevented.

In addition, the present invention can firmly fix the frame body portion and the body extension portion, which are made lightweight, due to the structure of the body fixing portion and the fixing frame portion provided on the frame body portion and the body extension portion described above, And the manufacturing cost can be reduced.

1 is a perspective view illustrating an exemplary aquatic optical structure 1000 according to an embodiment of the present invention.
FIG. 2 is a front view showing an aquarium photovoltaic structure 1000 according to an embodiment of the present invention as viewed from above.
3 is a perspective view illustrating support structure 100A according to an embodiment of the present invention in more detail.
FIG. 4 is a side view illustrating the support structure 100A according to one embodiment of the present invention in more detail.
5 is a view showing a supporting body structure of a supporting structure 100A for supporting the solar cell module 10 according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

FIG. 1 is a perspective view illustrating an exemplary aquatic optical structure 1000 according to an exemplary embodiment of the present invention, and FIG. 2 is a perspective view illustrating an aquatic optical structure 1000 according to an exemplary embodiment of the present invention. Front view.

As shown in the drawing, the aquamarine solar structure 1000 according to an embodiment of the present invention includes a solar cell module support 100, a pulley 100a, An anchor portion 300, a mooring rope portion 400, and a weighing portion 500.

First, the solar cell module supporting part 100 according to the present invention includes a plurality of supporting structures 100A for supporting the solar cell module 10 at the watercraft. These support structures 100A are spaced apart from each other by a predetermined distance in the form of a lattice in the transverse direction and the longitudinal direction. Such a support structure 100A will be described later in more detail.

Next, the pulley 200 according to the present invention is fastened to the first support structure 100A-1 disposed at the both ends of the plurality of support structures 100A side by side via the pulley fastening portion (not shown) The pulley portion 200 includes a first pulley portion 210 and a second pulley portion 220.

At this time, when the pulley coupling part (not shown) is installed at the same position in the first supporting structure 100A-1 facing the pulley part 200, the pulley part 200 is fastened to the pulley coupling part (not shown). Here, the pulley 200 is formed at both ends of the first support structure 100A-1, but may be formed at various positions such as the center.

Next, the anchor portion 300 according to the present invention is fixed in parallel to the surface of the water surface corresponding to an arbitrary point of the outer periphery of the first support structure 100A-1 by the number of the pulley portions 200 described above.

The mooring rope unit 400 according to the present invention includes a first sheave portion 210 and a second sheave portion 220 which are wound around the first sheave portion 210 and the second sheave portion 220, The first supporting structure 100A-1 is fixed to a first anchor portion 310 provided at one side of the outer side of the first supporting structure 100A and the other end is connected to the anchor portion 300 through the second sheave portion 220 And is fixed to the second anchor portion 320 provided on the other side of the outer surface of the first support structure 100A-1.

In this case, the first anchor portion 310, the first sheave portion 210, and the second anchor portion 320 are located opposite to each other.

The weighing part 500 according to the present invention is characterized in that the weight between the first anchor part 310 and the first sheave part 210 and between the second anchor part 320 and the second sheave part 220 The lengths of the mooring rope portions 400 are extended to make movement in the water surface direction. When the movement is generated in this manner, the mooring ropes 400 at both ends of the support structure 100A maintain the same tensile force.

When the water level is lowered, the weight portion 500 according to the present invention is moved between the first anchor portion 310 and the first sheave portion 210 and between the second anchor portion 320 and the second sheave portion 220, The lengths of the rope portions 400 are shortened to make movement in the downward direction, i.e., in the water surface side direction. At this time as well, the mooring ropes 400 at both ends of the support structure 100A maintain the same tensile force.

Since the supporting structure 100A can be prevented from being deflected when the tensile force of both mooring rope portions 400 is kept the same, the incidence angle of the solar cell module 10 is constantly increased toward sunlight. . Therefore, the solar power generation amount can be increased due to the incident angle of the solar cell module 10 having the same directionality.

Although the pairs of pulleys 200 and 300 described above have been described above, they may be arranged in at least one or more pairs of the support structures 100A.

Although the mooring rope portion 400 and the weight portion 500 described above have been described in terms of a single number corresponding to a pair of the pulley portion 200 and the anchor portion 300, 100A. ≪ / RTI > As described above, the number of the mounting structures can be varied according to the number or size of the plurality of support structures 100A.

Hereinafter, the structure of the support structure 100A will be described in detail.

Examples of support structures

FIG. 3 is a perspective view illustrating the support structure 100A according to an embodiment of the present invention in more detail, and FIG. 4 is a side view illustrating the support structure 100A according to an embodiment of the present invention in more detail.

The support structure 100A according to an embodiment of the present invention includes a frame body 110, a body extension 120, a body fixing part 130 (not shown) for light weight support of the solar cell module 10, A buoyant body part 140, a fixed frame part 150, an extension body fixing part 160, and a mooring connection part 170. [

First, the frame body portion 110 according to the present invention has a first triangular shape 111 and a second triangular shape 112 having an empty space 102 as the lower portion thereof is opened. The first triangular shape 111 and the second triangular shape 112 are arranged side by side at a predetermined interval to form a first triangular shape 111 and an inclined surface 113 provided on the second triangular shape 112 The solar cell module 10 can be disposed in the space. In this case, it takes the form of a grid structure.

Although one solar cell module 10 is provided on the pair of inclined surfaces 113, the arrangement structure and the number of the solar cell modules 101 can be variously changed according to the solar photovoltaic capacity Of course it is.

Although not shown, the solar cell modules 10 may be coupled in a plurality of grid patterns, and may be spaced apart in the horizontal direction so as to maintain a gap between adjacent solar cell modules 10 .

This is for the purpose of allowing wind and snow to move when an external force such as wind or snow is generated in the solar cell module 10. The solar cell module 10 may be configured not only to form an interval in the horizontal direction, So that the height difference is generated.

Next, the body extension part 120 according to the present invention has a structure in which the first triangular shape 111 and the second triangular shape 112 are extended to the lower part and formed as a pair, 2 triangle shape 112, four frames are formed under the first triangle shape 111 and the second triangle shape 112. In other words,

Next, the body fixing part 130 according to the present invention is formed on the lower side and the other side of the first triangle shape 111 and the second triangle shape 112 in the cross direction of the body extension part 120 described above And may be fixed to a lower portion of the frame body 110.

The length of the body fixing part 130, which is provided in parallel with the pair of the first and second triangular shapes, may be the same as the first triangular shape and the second triangular shape described above, As shown in FIG.

Next, the buoyant body part 140 according to the present invention is formed on the body fixing part 130 in a state where the buoyant body part 140 is fitted into the body fixing part 130 described above and only a part thereof is immersed in water. The buoyant body portion 140 may have a substantially hexahedral shape such that it floats on a wave that is like a sea. However, the present invention is not limited thereto, and may have various shapes such as a cylindrical shape or a polyhedral shape.

Next, the fixed frame part 150 according to the present invention is formed side by side at the intersection of the lower portions of the first triangular shape 111 and the second triangular shape 112 and the body fixing parts 130, And serves to fix the fixing portion 130. Therefore, even if an assist force such as a sea wind acts, the distortion of the remaining support structure 100A supporting the solar cell module 101 can be prevented.

The fixed frame part 150 includes a first triangular shape 111 and a second triangular shape 112 at a position where the lower ends of the first triangular shape 111 and the second triangular shape 112 intersect with the body fixing part 130, It is preferable to fix the body fixing part 130 in a state of being in close contact with the lower outer surface of the body fixing part 112. Thus, the distortion of the remaining support structure 100A can be prevented.

Since the body fixing part 130 and the fixing frame part 150 described above are positioned at the center of the buoyant body part 140 partially floating on the water, the part immersed in water can be minimized, so that corrosion can be prevented .

The upper end of the body extension part 120 is formed on the upper part of the buoyant body part 140 like the body fixing part 130 and the fixed frame part 160 but the lower end of the body extension part 120 is formed with a part of the buoyant body part 140 It can have a structure that is located in the water. In this manner, the support structure 100A submerged in water is minimized.

Next, the extension fixing part 160 according to the present invention is formed by being fixed in pairs on one side and the other side of the lower side of the body extension part 120. That is, one end of the extension fixing part 160 provided in pairs is fixed to the body extension part 120 extending from the first triangular shape 111 and the other end is fixed to the body extension part 120 extending from the second triangular shape 112, (Not shown). Thus, the frame body 110 and the body extension 120 can be integrally formed.

The mooring connection part 170 according to the present invention includes a mooring loop 172 passing through the mooring claw part 171 after sandwiching the mooring claw part 171 near the center of the extension fixing part 160 described above, To the surface of water or the ground.

As described above, when the mooring connection portion 170 is fixed in the cross direction in the vicinity of the substantial center of the extension fixing portion 160, it is possible to further reduce the flow of the support structure 100A described above with reference to FIGS. 1 and 2 . In addition, when the mooring connection portion 170 is provided, it is very helpful that the buoyant body portion 140 described above can be stably placed on the water level.

Although the frame body portion 110, the body extension portion 120, and the extension body fixing portion 160 described above have been described as being fixed to each other, they are preferably integrally formed. Such an integral support structure is shown in Fig.

5 is a view showing a supporting body structure of a supporting structure 100A for supporting a solar cell module 10 according to an embodiment of the present invention.

5, the supporting body structure of the supporting structure 100A according to the present invention is a supporting structure in which the frame body portion 110 and the body extending portion 120 are integrally formed and lightened as described above, And the solar battery module 10 and the buoyant body part 140 can be mounted at the same time, so that balance can be maintained in the water phase and the manufacturing cost can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. You can understand that you can do it. The embodiments described above are therefore to be considered in all respects as illustrative and not restrictive.

10; Solar Module 1000: Water Photovoltaic Structure
100; Solar cell module support part 100A: Support structure
110: frame body part 111: first triangular shape
112: second triangular shape 113: sloped surface
120: body extension part 130: body fixing part
140: buoyant body part 150: fixed frame part
160: Extension fixture 170: Mooring connection
171: Mooring ring 172: Mooring loop
200; Pulley portion 210: First pulley portion
220: 2nd pulley part 300: anchor part
310: first anchor portion 320: second anchor portion
400: mooring rope portion 500: weight portion

Claims (7)

A solar photovoltaic structure for stabilizing the azimuth angle of a solar cell module,
A solar cell module supporting part for disposing a plurality of supporting structures for supporting the solar cell module at a predetermined distance apart from each other;
A first support structure disposed at both ends of the plurality of support structures and coupled to the first support structure via a pulley coupling portion;
An anchor portion that is fixed on the water surface corresponding to the outer periphery of the first support structure;
A mooring rope portion having one end passing through the pulley portion fixed to the first anchor portion of the anchor portion and the other end fixed to the second anchor portion opposite to the first anchor portion; And
The weight of the mooring rope moving in the water surface direction becomes longer when the water level becomes higher and the length of the mooring rope becomes shorter when the water level becomes lower,
An aquifer structure. The method according to claim 1,
Wherein the pulley portion and the anchor portion are arranged side by side in at least one pair of the plurality of support structures,
Wherein at least one of the mooring rope portion and the weight portion is disposed side by side in the plurality of support structures. 3. The method of claim 2,
The support structure comprises:
A frame body portion for arranging the solar cell module on the inclined surfaces of the first and second triangular shapes by disposing a first triangular shape and a second triangular shape that are open at the lower side with a predetermined gap therebetween;
A body extension extending in pairs below the first and second triangular shapes;
A body fixing part which is formed in parallel to the lower side and the other side of the first and second triangular shapes in the cross direction of the body extension part and fixed to the lower part of the frame body part;
A buoyant body part which is fitted to the body fixing part and is formed on the body fixing part in a state where only a part of the body is immersed in water; And
A fixing frame part formed at a position where the lower part of the first and second triangular shapes intersect with the body fixing part to fix the body fixing part after drawing the body part to the body fixing part;
Wherein the solar cell structure comprises: The method of claim 3,
The body fixing part and the fixed frame part may include:
Wherein the floating structure is formed at an upper portion of the buoyant body part floating on the water. The method of claim 3,
And a lower portion of the body extension portion is located underwater together with a part of the buoyant body portion. The method of claim 3,
The support structure comprises:
An elongated body fixing part formed to be fixed to the other side and the other side of the body extension part in parallel;
Further comprising: a light source for emitting the visible light. The method according to claim 6,
The support structure comprises:
A mooring connection portion for fixing the mooring loop passing through the mooring claw portion to the water surface or the ground after inserting the mooring claw portion into the extension fixing portion in the cross direction;
Further comprising: a light source for emitting the visible light.

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