KR101785579B1 - Solar power generating system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar power generation system, and more particularly, And a flexible connection unit for flexibly connecting two adjacent unit frames of the unit frames, wherein the flexible connection unit comprises: a connection wire for connecting the two unit frames; And a spring supporting the two unit frames. According to the present invention, not only the interval of the unit frames provided with the solar cell module (s) is maintained at a predetermined interval, but also the unit frames can move flexibly in the vertical direction and minimizes the operation of the wind force by the wind.

Description

Solar power generation system {SOLAR POWER GENERATING SYSTEM}

The present invention relates to a solar 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 generation system installed on a lake, river, or sea surface is called a "photovoltaic power generation system." This is human-friendly because it does not conflict with people and land. It restricts the entry of solar energy into water when installed in lakes or rivers. Reducing the rise in water temperature reduces evaporation and helps preserve fresh water and reduces fog damage in the surrounding area.

Generally, a water photovoltaic power generation system includes a floating structure suspended on a water surface, a solar photovoltaic device mounted on an upper part 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) (hereinafter referred to as prior art), 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 power generation system in which a horizontal connection frame is connected in a horizontal direction, 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 on support frames, . In the prior art, the pontoons, which are buoyancy 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 or the like, The horizontal connection frame and the vertical connection frame may not flexibly move according to the wave of the water surface, and 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 addition, since the wind force acts on the solar cell module positioned at an inclined position, the upward force acts on the solar cell module, so that force acts on the horizontal connecting frame and the vertical connecting frame greatly, and the horizontal and vertical connecting frames may be damaged.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solar power generation system in which the intervals of unit frames in which the solar cell module (s) are installed are kept at predetermined intervals, and the unit frames can move flexibly in the vertical direction.

It is another object of the present invention to provide a photovoltaic power generation system that minimizes the wind-induced wind force.

In order to achieve the object of the present invention, there is provided a solar cell module comprising: a rectangular plate-shaped solar cell module for generating electricity by sunlight; Unit frames; A flexible connection unit for flexibly connecting two adjacent unit frames among the unit frames; Wherein the unit frame supports the solar cell module, one side of the solar cell module is rotatably fixed and the other side of the solar cell module is supported in a non-fixed state, so that the horizontal wind pressure acting on the solar cell module And a module supporting unit for adjusting an angle of the solar cell module by the connecting unit, wherein the flexible connecting unit comprises: a connecting wire connecting the two unit frames; And a spring supporting the two unit frames, wherein the spring is a compression coil spring, the connection wire is located inside the spring, and the module supporting unit is located on one side of the solar cell module A plurality of vertical support members fixed to the unit frame and positioned in a vertical direction; A hinge-type clamp rotatably coupled to each upper end of the vertical support members and fixing one side of the solar cell module; Wherein the vertical support member is provided on the unit frame so as to be positioned at an opposite side of one side of the solar cell module in which the vertical support members are located and has a height smaller than a height of the vertical support member, And an elastic supporting unit for supporting the other side of the solar cell module by an elastic force so that the other side of the solar cell module moves up and down with the hinge type clamp as an axis.

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A first connecting member is connected to one unit frame of the two unit frames and a second connecting member is connected to another unit frame of the two unit frames, It is preferable that one end of the spring is supported by the first linking member and the other end is supported by the second linking member.

Preferably, the first and second connecting members each include an insertion groove into which one of the spring is inserted and a fixing portion which is provided in the insertion groove and to which one of the connection wires is fixed.

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Wherein the elastic supporting unit comprises: a sliding member provided on the other side of the solar cell module; a rotation support member rotatably coupled to the unit frame; and one side of the rotation support member is coupled with the sliding member, And a cap member for covering the upper end of the guide tube. The guide member may be formed of a metal plate, Do.

According to another aspect of the present invention, there is provided a solar cell module comprising: a rectangular plate-shaped solar cell module for generating electricity by sunlight; Unit frame; Wherein the unit frame supports the solar cell module, one side of the solar cell module is rotatably fixed and the other side of the solar cell module is supported in a non-fixed state, so that the horizontal wind pressure acting on the solar cell module And a module supporting unit for controlling an angle of the solar cell module by the plurality of solar cells, wherein the module supporting unit is fixed to the unit frame so as to be positioned at one side of the solar cell module, Vertical support members; A hinge-type clamp rotatably coupled to each upper end of the vertical support members and fixing one side of the solar cell module; The vertical support members are disposed on opposite sides of one side of the solar cell module in which the vertical support members are located, the height of the vertical support members is smaller than the height of the vertical support members, And an elastic supporting unit that supports the other side of the solar cell module by an elastic force so that the other side of the solar cell module moves up and down with the hinge type clamp as an axis.

Since the unit frames provided with the solar cell module (s) are connected by the flexible connection unit (s), when a high wave is generated in the water column installed with the solar cell power generation system according to the present invention, The force acting on the unit frames is minimized, and the intervals of the unit frames are excessively distanced or the unit frames are prevented from colliding with each other. Also, when the water in the lake where the PV system is installed is reduced and the PV system is brought to the bottom of the uneven lake, the unit frames are connected by the flexible connecting units so that the unit frames are bent And is supported on the bottom of the lake to prevent the unit frames and the solar cell modules installed in the unit frames from being damaged.

In addition, since the solar cell module is supported by the module supporting unit, when the wind force does not act, the solar cell module is inclined and efficiently accommodates the sunlight. When the wind force acts on the solar cell module, The solar cell module moves up and down with respect to one side, and the wind force acting on the solar cell module is minimized. Accordingly, the lifting force by the wind force acting on the solar cell module is minimized to minimize the lifting force acting on the unit frames and the floats, thereby preventing damage to the unit frames and the float.

In addition, when the unit frames include aluminum material, not only the structural strength of the unit frame is increased but also the weight of the unit frame is reduced, so that the size of the float can be reduced, thereby reducing the size of the system.

1 is a perspective view illustrating an embodiment of a solar power generation system according to the present invention,
2 is a plan view showing an embodiment of a solar power generation system according to the present invention,
FIG. 3 is a plan view showing an example of a flexible connection unit constituting an embodiment of the solar power generation system according to the present invention,
4 is a side view showing an example of a module supporting unit constituting an embodiment of the solar power generation system according to the present invention,
5 is a side view showing an example of a module supporting unit constituting an embodiment of a photovoltaic power generation system according to the present invention.
FIG. 6 is a perspective view illustrating an example of a vertical support member and a hinge type clamp that constitute an embodiment of the solar power generation system according to the present invention. FIG.
7 is a front view showing an example of an elastic supporting unit constituting an embodiment of the solar power generation system according to the present invention.
8 is a perspective view showing an example of an elastic supporting unit constituting an embodiment of the solar power generation system according to the present invention.

Hereinafter, embodiments of a photovoltaic power generation system according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view illustrating an embodiment of a solar power generation system according to the present invention. 2 is a plan view showing an embodiment of a solar power generation system according to the present invention.

1 and 2, an embodiment of a photovoltaic power generation system according to the present invention includes solar cell modules 100, unit frames 200, float 300, a flexible connection unit 400).

The solar cell module 100 receives solar light (light) to generate electrical energy.

One or more solar cell modules 100 are installed in the unit frame 200. In the unit frame 200, the unit frames 200 are connected to the vertical pipes 210, which are positioned parallel to each other with an interval, and the vertical pipes 210, so as to be positioned between the vertical pipes 210 And a plurality of transverse pipes 220 connected to each other at an interval. The vertical pipes 210 and the horizontal pipes 220 of the unit frame 200 are preferably located on the same plane. The vertical pipes 210 and the horizontal pipes 220 preferably each include an aluminum material. A plurality of unit frames 200 are connected to each other, and unit frames 200 adjacent to each other are connected by a flexible connection unit 400.

The float (300) is suspended in the water phase. The float 300 is connected to the unit frame 200 to float the unit frame 200. One float 300 may be connected to the unit frame 200 or a plurality of float 300 may be connected to the unit frame 200.

It is preferable that the flexible connection unit 400 connects two adjacent unit frames 200 among the unit frames 200 and the two unit frames 200 are connected by a plurality of flexible connection units 400 .

3, the flexible connection unit 400 supports a connection wire 410 connecting two unit frames 200 and two unit frames 200, (Not shown). The connecting wire 410 has flexibility. The connecting wires 410 prevent the two unit frames 200 adjacent to each other from being spaced apart from each other by a distance greater than the length of the connecting wires 410 when an external force acts on the unit frames 200, So that the frames 200 can be positioned vertically up and down. When the external force acts on the two unit frames 200 adjacent to each other and the distance between the two unit frames 200 is narrowed, The elastic force is applied. That is, when the interval between two unit frames 200 adjacent to each other is maintained at a predetermined interval by the flexible connection unit 400 and an external force acts on the two unit frames 200, The interval between the two unit frames 200 becomes narrower within the length.

The spring 420 is a compression coil spring, and the connecting wire 410 is preferably located inside the spring 420.

Preferably, the flexible connection unit 400 further includes two connection members 430. When the two connecting members are referred to as first and second connecting members 430A and 430B, a first connecting member 430A is connected to one unit frame 200 of two adjacent unit frames 200 The second connection member 430B is connected to the other unit frame 200 of the two unit frames 200. [ One end of the connecting wire 410 is fixed to the first connecting member 43A and the other end of the connecting wire 410 is fixed to the second connecting member 430B. It is also preferable that one end of the spring 420 is supported by the first connection member 430A and the other end of the spring 420 is supported by the second connection member 430B.

The first connection member 430A includes an insertion groove 431 into which one of the spring 420 is inserted and a fixing portion 432 provided inside the insertion groove 431 to fix one side of the connection wire 410 . The second connection member 430B also has an insertion groove 431 into which the other end of the spring 420 is inserted and a fixing portion 431 which is provided in the insertion groove 431 and to which the other end of the connection wire 410 is fixed 432). The insertion groove 431 and the fixing portion 432 of the first connection member 430A are preferably formed in the same shape as the insertion groove 431 and the fixing portion 432 of the second connection member 430B. It is preferable that the insertion groove 431 is formed in a cylindrical shape so that one side of the spring 420 is inserted and the fixing portion 432 is formed in the form of a pin or a hook so that the connection wire 410 is fixed.

As an example of the connecting member 430, it is preferable that the connecting member 430 is formed in a cross shape. Two protruding portions of the four protruding portions are provided with insertion grooves 431 and fixing portions 432 respectively and the other two protruding portions are formed by the horizontal pipe 220 and the vertical pipe 210 constituting the unit frame 200 And one protruding portion is connected to the transverse pipe 220 and the other protruding portion is connected to the vertical pipe 210. That is, the connecting member 430 is connected to the flexible connection unit 400 while connecting the horizontal pipe 220 and the vertical pipe 210 constituting the unit frame 200 to each other.

The spring 420 and the connection wire 410 may connect two adjacent unit frames 200 at different positions.

On the other hand, the unit frame 200 is provided with a module supporting unit 500 for supporting the solar cell module 100, respectively. The module supporting unit 500 supports the solar cell module 100 while adjusting the angle of the solar cell module 100 according to the wind pressure acting on the solar cell module 100.

4 and 5, the module supporting unit 500 includes a plurality of vertical supporting members 510 each fixed to the unit frame 200 in the vertical direction, A hinge type clamp 520 rotatably coupled to each upper end portion of the vertical support members 510 and to which one side of the solar cell module 100 is fixed and a hinge type clamp 520 rotatably coupled to the upper side of the hinge type clamps 520 according to the wind pressure acting on the solar cell module 100. [ And an elastic supporting unit (B) for supporting the solar cell module (100) so that the solar cell module (100) moves up and down with the axis (520) as an axis.

The vertical support members 510 have a predetermined length and are fixedly coupled to the transverse pipe 220 of the unit frame 200 at regular intervals. That is, when the vertical support member 510 is vertically positioned, one end of the vertical support member 510 is fixedly coupled to the horizontal pipe 220 of the unit frame 200.

As shown in FIG. 6, the hinge-type clamp 520 includes a clamping portion 521 formed in a diagonal shape and coupled to one side of the solar cell module 100, And a connection shaft portion 522 extending from the support portion 521 and rotatably coupled to the upper end of the vertical support member 510.

7 and 8, the elastic supporting unit includes a sliding member 530 provided on the other side of the solar cell module 100, and a sliding member 530 provided on the other side of the unit frame 200, A guide pipe 550 having one side connected to the rotation support member 540 and having a guide slit in which the sliding member 530 can be inserted in a vertical direction, First and second springs 560 and 570 inserted into the guide pipe 550 so as to be positioned at both sides of the member 530 and a cap member 580 covering the upper end of the guide pipe 550. The sliding member 530 has a clamping portion 531 formed in a diagonal shape and to which one side of the solar cell module 100 is coupled and a guide slit (not shown) extending from one side of the clamping portion 531, 551, respectively. The clamping portion 531 of the sliding member 530 is fixedly coupled to the solar cell module 100 and a portion of the lever portion 532 is inserted through the guide slit 551 of the guide tube 550. The rotation support member 540 includes a coupling tube portion 541 into which the transverse pipe 220 of the unit frame 200 is movably inserted and a coupling tube portion 542 extending from the outer surface of the coupling tube portion 541 do. The guide tube 550 has a length shorter than the length of the vertical support member 510 and the guide slit 551 has a uniform width and length and the longitudinal direction of the guide slit 551 is the length of the guide tube 550 Direction. One end of the guide tube 550 is connected to the connection tube portion 542 of the rotation support member 540. The first and second springs 560 and 570 are preferably compression coil springs. The first spring 560 is positioned below the lever portion 532 of the sliding member 530 and the second spring 570 is positioned above the lever portion 532. One end of the spring 570 is positioned on the cap member 580 And is fixedly coupled.

The module supporting unit 500 is configured such that one side of the solar cell module 100 is supported by the vertical supporting members 510 when the wind power does not act on the solar cell module 100 and the other side of the solar cell module 100 is resilient And is supported by the support unit B so that the solar cell module 100 is supported so as to be inclined at a predetermined angle. At this time, the lever portion 532 of the sliding member 530 constituting the elastic supporting unit B is supported by the first spring 560. When the wind force acts on the rear surface of the solar cell module 100, the solar cell module 100 is moved upward by the wind force with respect to the hinge type clamp 520, Is positioned close to the horizontal. At this time, the lever portion 532 of the sliding member 530 supporting the other side of the solar cell module 100 is moved upward along the guide slit 551 of the guide pipe 550, and the guide pipe 550 And is erected vertically with the rotation support member 540 as an axis. As a result, the wind pressure acting on the solar cell module 100 is reduced. When the wind is small and the wind force becomes small, the solar cell module 100 moves downward on the opposite side with respect to the hinge type clamp 520 by the weight of the solar cell module 100, Is moved to the home position.

The float (300) or unit frames (200) are moored by a mooring device (not shown).

In another embodiment of the photovoltaic generation system according to the present invention, the photovoltaic power generation system includes a solar cell module 100 for generating electricity by solar light; A unit frame (200); The unit frame 200 supports the solar cell module 100 so that the angle of the solar cell module 100 is adjusted according to the wind pressure acting on the solar cell module 100, Unit 500, as shown in FIG.

One or more solar cell modules 100 are installed in the unit frame 200. The unit frame 200 includes vertical pipes 210 disposed parallel to each other with an interval therebetween and connected to the vertical pipes 210 to be positioned between the vertical pipes 210. [ And a plurality of transverse pipes 220 spaced from one another. The vertical pipes 210 and the horizontal pipes 220 of the unit frame 200 are preferably located on the same plane. The vertical pipes 210 and the horizontal pipes 220 preferably each include an aluminum material (see FIG. 2).

As an example of the module supporting unit 500, the module supporting unit 500 includes a plurality of vertical supporting members 510, each of which is fixed to the unit frame 200 in a vertical direction; A hinge type clamp 520 rotatably coupled to each upper end of the vertical support members 510 and having one side of the solar cell module 100 fixed; And an elastic supporting unit B for supporting the solar cell module 100 such that the solar cell module 100 moves up and down with respect to the hinge type clamp 520 in accordance with the wind pressure acting on the solar cell module 100 do. The vertical support members 510, the hinge clamp 520, and the elastic support unit B are as described above. Therefore, detailed description is omitted.

Hereinafter, the operation and effect of the solar power generation system according to the present invention will be described.

The photovoltaic power generation system according to the present invention is installed in a waterfront such as a river, a lake, a dam, and a coastal sea (for example, Gwangyang Bay). The unit frames 200 are floated by the floats 300 in the state where the solar power generation system according to the present invention is installed on the aquaplanes and the solar cells 100 are installed in the unit frames 200, And generates electric energy.

Since the unit frames 200 provided with the solar cell module 100 (s) are connected by the flexible connection unit 400 (s), when a high wave is generated in the aquarium where the solar power generation system is installed, The unit frames 200 are moved in a vertical direction with flexibility so as to minimize a force acting on the unit frames 200. In addition, 200 from bumping against each other. In addition, when the water of the lake where the photovoltaic power generation system is installed is reduced and the photovoltaic power generation system is brought into contact with the bottom of the lake which is not flat, the unit frames 200 are connected by the flexible connection units 400, Are supported on the bottom of the lake while being bent to conform to the topography of the bottom of the lake to prevent damage to the unit frames 200 and the solar cell modules 100 installed in the unit frames 200, respectively.

Further, since the solar cell module 100 is supported by the module supporting unit 500, when the wind force does not act, the solar cell module 100 is inclined to efficiently receive the sunlight, When the wind force acts on the solar cell module 100, the solar cell module 100 moves up and down with respect to one side by the wind force, thereby minimizing the wind force acting on the solar cell module 100. The lifting force of the unit frames 200 and the float 300 can be minimized by minimizing the lifting force acting on the unit frames 200 and the floats 3000 by minimizing the upward force by the wind force acting on the solar cell module 100. [ Thereby preventing breakage of the battery.

In addition, when the unit frames 200 include an aluminum material, the structural strength of the unit frame 200 is increased and the weight of the unit frame 200 is reduced. The size of the system is reduced.

10; Floating suspended structures 20; Main connection ropes
30; Auxiliary connection ropes 40; Floating structure for support
50; A solar cell module 60; Unit connection mechanisms
70; Mooring device

Claims (8)

A rectangular solar cell module for generating electricity by solar light;
Unit frames;
A flexible connection unit for flexibly connecting two adjacent unit frames among the unit frames;
Wherein the unit frame supports the solar cell module, one side of the solar cell module is rotatably fixed and the other side of the solar cell module is supported in a non-fixed state, so that the horizontal wind pressure acting on the solar cell module And a module supporting unit for adjusting the angle of the solar cell module by the module supporting unit,
The flexible connection unit includes:
A connecting wire connecting the two unit frames;
And a spring supporting the two unit frames,
Wherein the spring is a compression coil spring, the connecting wire is located inside the spring,
The module supporting unit includes:
A plurality of vertical support members fixed to the unit frame so as to be positioned at one side of the solar cell module, the vertical support members being vertically disposed;
A hinge-type clamp rotatably coupled to each upper end of the vertical support members and fixing one side of the solar cell module;
Wherein the vertical support member is provided on the unit frame so as to be positioned at an opposite side of one side of the solar cell module in which the vertical support members are located and has a height smaller than a height of the vertical support member, And an elastic supporting unit for supporting the other side of the solar cell module by an elastic force such that the other side of the solar cell module moves up and down with the hinge type clamp as an axis. delete The apparatus of claim 1, wherein a first connecting member is connected to one unit frame of the two unit frames and a second connecting member is connected to another unit frame of the two unit frames, Characterized in that one end is fixed to the first connecting member and the other end is fixed to the second connecting member and one end of the spring is supported by the first connecting member and the other end is supported by the second connecting member Solar power system. 4. The solar power generation system according to claim 3, wherein the first and second connection members each include an insertion groove into which one of the spring is inserted and a fixing portion which is provided inside the insertion groove, . delete delete 2. The solar cell module according to claim 1, wherein the elastic supporting unit comprises: a sliding member provided on the other side of the solar cell module; a rotation support member rotatably coupled to the unit frame; A guide tube having a guide slit in which the member is vertically movably inserted; first and second springs respectively inserted into the guide tube so as to be positioned on both sides of the sliding member; ≪ / RTI > A rectangular solar cell module for generating electricity by solar light;
Unit frame;
Wherein the unit frame supports the solar cell module, one side of the solar cell module is rotatably fixed and the other side of the solar cell module is supported in a non-fixed state, so that the horizontal wind pressure acting on the solar cell module And a module supporting unit for adjusting the angle of the solar cell module by the module supporting unit,
The module supporting unit includes:
A plurality of vertical support members fixed to the unit frame so as to be positioned at one side of the solar cell module, the vertical support members being vertically disposed;
A hinge-type clamp rotatably coupled to each upper end of the vertical support members and fixing one side of the solar cell module;
The vertical support members are disposed on opposite sides of one side of the solar cell module in which the vertical support members are located, the height of the vertical support members is smaller than the height of the vertical support members, And an elastic supporting unit for supporting the other side of the solar cell module by an elastic force so that the other side of the solar cell module moves up and down with the hinge type clamp as an axis.

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