KR101509026B1 - Water surface floating type solar photovoltaic power generator - Google Patents

Abstract

According to this invention, the solar cell module including a solar light power generation units; he upper and lower perforated around the perforated portion is formed, the piercer and the buoyancy compartments being controlled buoyancy buoyant body portion is formed toward the edge of space; The PV device provides the surface portion comprises a; and the module cooling means for ejecting water to the drilling of the buoyancy body. With this structure, there is an advantage capable of rapidly cooling the heated solar cell modules in the solar by pumping cold water from the depths of water by spraying to the piercer.

Description

TECHNICAL FIELD [0001] The present invention relates to a water surface solar power generation apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a water surface type solar photovoltaic device floating on a water surface.

Generally, a photovoltaic device generates electricity by using a solar cell that generates photovoltaic power by photoelectric effect when light is irradiated.

Such a photovoltaic power generation device is usually installed on a large area on the ground, and thus there are many restrictions on the selection of the available land.

In recent years, attempts have been made to install PV devices in rivers, reservoirs, or deep water waters to solve these problems.

As an example thereof, a photovoltaic power generation device that can be installed in a watercraft is disclosed in the publication No. 10-2012-0026924 (2012.03.20, a solar-powered photovoltaic power generation device).

However, such a conventional solar lifting type solar power generator has a problem that the solar cell module is easily overheated due to hot solar heat, which lowers the electricity production efficiency and shortens the service life due to deterioration.

In addition, there is a problem that the power generation facility including the solar cell module tends to be broken due to high waves due to strong winds or large waves in the sea, making it difficult to operate normally in waterworks.

In addition, there is a problem that the power generation support body and the buoyant body are separately manufactured and assembled to support the power generation means, resulting in poor economical efficiency and assembly productivity.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a solar cell module which can cool a superheated solar cell module, safely protect the solar cell module from high- And an object of the present invention is to provide a floating type solar power generation device.

In order to accomplish the above object, according to one aspect of the present invention, there is provided a solar-

A solar power generation facility including a solar cell module unit 110;

A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And

Module cooling means 160 for spraying water to the perforations 120a of the buoyant body 120;

.

The solar cell module unit 110 includes a plate-shaped solar cell module 111 provided at an angle to the substrate, a plurality of bolt holes 112a bent downward to the lower side of the solar cell module 111, And a coupling part 112 formed thereon.

The upper portion of the buoyant body 120 is provided with a plurality of communication holes 121a extending upward to correspond to the coupling portions 112 and to communicate with the bolt holes 112a of the coupling portion 112 in the longitudinal direction, And a flange 121 is formed.

A first cut-out portion 112b is formed on an upper surface of the coupling portion 112, a second cut-out portion 112c is formed on a lower surface thereof,

The flange portion 121 is provided with a moisture outlet 121b at a portion contacting the first cutout portion 112b and a water outlet 121c at a portion contacting the second cutout portion 112c .

According to the present invention,

A plurality of longitudinal pipes (132) vertically coupled to the plurality of transverse pipes (131), a plurality of transverse pipes (131) arranged side by side in the buoyant body (120) (130).

According to the present invention,

And a foot plate 140 installed orthogonally to the upper portions of the plurality of longitudinal pipes 132.

According to the present invention,

A pump unit 151 disposed on one side of the buoyant body 120 and a compressor unit 152 disposed on the other side of the buoyant body 120. One end of the compressor unit 152 is connected to one side of the pump unit 151, A first flow pipe 153 communicating with the buoyant space portion 120b of the buoyant body 120 and a second flow pipe 153 having one end connected to the other side of the pump portion 151 and the other end disposed in the airstream And a buoyancy adjusting means 150 having one end connected to the compressor portion 152 and the other end connected to the buoyant space portion 120b of the buoyant body 120 .

The module cooling means 160 includes a motor pump 161, a water inlet pipe 162 having one end connected to one side of the motor pump 161 and the other end disposed in the water pump, A water supply pipe 163 for connecting the other side with the buoyant body 120 and a plurality of nozzles 164-1 positioned on the perforation 120a of the buoyant body 120, And a water discharge pipe (164) communicating with the water discharge pipe (163).

The buoyant body 120 is formed with a plurality of air holes 120c formed at positions facing each other through the buoyant space portion 120b and communicating the perforation 120a with the outside .

As described above, according to the present invention, there is an advantage that the solar cell module heated by the solar heat can be rapidly cooled by pumping cold water deep from the water surface and spraying it with perforations.

In addition, it is possible to effectively protect the solar cell module and the structure by effectively preventing the impact from the high wave of the aquifer or the surge, and it is possible to operate the water tower stably.

In addition, the buoyant body can be improved as a unitary structure to simplify the structure, and economical efficiency and assembly productivity can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view illustrating a water surface type solar photovoltaic apparatus according to an embodiment of the present invention.
2 is a plan view showing an installation example (a solar cell module unit not shown in Fig. 1)
Fig. 3 is a side view showing the combined state of Fig. 1, showing the buoyant body being lowered to a certain depth, and Fig.
FIG. 4 is a side view showing the engaged state of FIG. 1, and is an operation diagram showing that the buoyant body is lifted at a predetermined height.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a description will be made in detail of a solar-on-water type photovoltaic apparatus according to an embodiment of the present invention with reference to the accompanying drawings.

Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

As shown in FIGS. 1 and 2, the water surface solar photovoltaic device according to one embodiment of the present invention includes a solar power generation facility including a solar cell module unit 110; A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And module cooling means 160 for pumping water of the aquarium into the perforations 120a of the buoyant body 120. [

Here, although only the solar cell module unit 111 is shown in the drawing as the solar power generation facility, various known facilities such as a power conversion device and a battery can be installed. The solar cell module unit 110 includes a plate-shaped solar cell module 111 provided at an angle to the substrate, a plurality of bolt holes 112a bent downward to the lower side of the solar cell module 111, And a fastening part 112 formed thereon.

The upper portion of the buoyant body 120 corresponds to the coupling portion 112 and extends upward to correspond to the coupling portion 112 and extend in the longitudinal direction to the bolt holes 112a of the coupling portion 112 And a flange 121 having a plurality of communication holes 121a communicating therewith. It is preferable that the buoyant body 120 is made of a light material that can float on the water and a plurality of air holes 120c communicating with the perforations 120a and facing each other are formed, The flow of the body 120 can be minimized. The plurality of air holes 120c are formed at positions opposed to each other through the buoyant space portion 120b so as to communicate the perforations 120a with the outside, and the buoyant body 120 Can be dispersed.

In addition, a first cut-out portion 112b is formed near the top edge side of the fastening portion 112, a second cut-out portion 112c is formed near the bottom edge side of the fastening portion 112, A moisture outlet 121b is formed in a portion in contact with the first cutout portion 112b and a water outlet 121c is formed in a portion in contact with the second cutout portion 112c. According to this construction, the moisture coming from the water surface is discharged through the moisture outlet 121b, and the water generated on the back surface of the solar cell module unit 111 flows along the plate surface and is discharged through the water outlet 121c .

The present invention is characterized in that a plurality of transverse pipes (131) arranged side by side across the buoyant body (120) and vertical buckling (welding, bolting, etc.) to the upper part of the plurality of transverse pipes And a buoyant body connecting means 130 including a plurality of longitudinal pipes 132 for supporting the body 120 more firmly. 2, each buoyant body 120 is constrained to be a single unit by a plurality of transverse pipes 131 and a plurality of longitudinal pipes 132, and a plurality of transverse pipes 131, The ends of the steel frame 132 can be more tightly bound by the steel frame structure 135 arranged in a rectangular shape. The transverse pipe 131 and the vertical pipe 132 are connected to the buoyant body 120 by a rubber packing P so that the buoyant space 120b can be completely sealed.

The module cooling means 160 includes a motor pump 161 supported on the transverse pipe 131 and a water inlet pipe 161 having one end connected to one side of the motor pump 161 and the other end connected to the water inlet A water supply pipe 163 for connecting the other side of the motor pump 161 to the buoyant body 120 and a plurality of nozzles (not shown) disposed on the perforations 120a of the buoyant body 120 And a water discharge pipe 164 having one end connected to the water supply pipe 163.

At this time, the other end of the water inflow pipe 162 is installed deeply from the water surface so that cold water can flow.

2, the water supply pipe 163 may be used as a means for connecting the plurality of buoyant bodies 120 to each other. In this case, Is connected to another water supply pipe (163). The middle portion of the water discharge pipe 164 is located on the perforations 120a of the buoyant body 120 and both sides thereof are positioned on the buoyant space portion 120b of the buoyant body 120. [ In addition, connectors (C) for fastening the water supply pipes (163) may be installed at both ends of the water discharge pipe (164).

In addition, the present invention may further include a footrest 140 that is vertically installed on top of the plurality of longitudinal pipes 132 and can be moved by a user.

3, the present invention may include a pump unit 151 disposed on one foot plate 140 of the buoyant body 120 and a pump unit 151 disposed on the other foot plate 140 of the buoyant body 120. [ A first flow pipe 153 having one end connected to one side of the pump unit 151 and the other end communicating with the buoyant space 120b of the buoyant body 120, A second flow pipe 154 having one end connected to the other end of the pump unit 151 and the other end disposed in the airstream and a second flow pipe 154 having one end connected to the compressor unit 152 and the other end connected to the buoyant space And a buoyancy regulating means 150 composed of an air outflow inlet 155 communicating with the outlet 120b.

The buoyancy body 120 is connected to the buoyancy adjusting means 150 so that the buoyancy adjusting means 150 can be detachably connected to the buoyancy body 120. [ C) can be installed in pairs. The other end of the first flow pipe 153 is preferably disposed at a lower portion of the buoyant space 120b of the buoyant body 120 The first flow pipe 153 may be installed as a separate member in a state of being connected to the connector C at all times. In addition, the first and second valves 153-1 and 155-1, which can be opened and closed respectively, are installed in the first flow pipe 153 and the air flow inlet 155, respectively.

Hereinafter, the operation of the inventive sleeping-type solar photovoltaic apparatus described above with reference to FIGS. 3 and 4 will be described.

As shown in FIG. 3, when the wave is severe, water is injected into the buoyancy space 120b of the buoyant body 120 to lower the buoyancy.

The first channel pipe 153 and the air outlet pipe 155 are connected to the connector C of each buoyant body 120 to connect the pump unit 151 and the compressor unit 152 to the buoyant body 120 .

When the first valve 153-1 is closed and the second valve 155-1 is opened and the user operates the pump unit 151 for a predetermined period of time, The water flows into the buoyant space portion 120b of the buoyant body 120 through the first flow pipe 153 gradually and the buoyant body 120 is lowered.

At this time, the air entering the buoyant space 120b of the buoyant body 120 flows into the air outflow inlet 155 and is discharged to the outside through the opened second valve 155-1, The inside can flow smoothly while keeping the proper pressure. When the buoyant member 120 is lowered, the user stops the pump unit 151 and closes the second valve 155-1.

4, the user may connect the first channel pipe 153 and the air pipe 153 to the connector C of each buoyant body 120. In this case, The second valve 155-1 is closed and the first valve 153-1 is closed by connecting the pump unit 151 and the compressor unit 152 to the buoyant body 120 by connecting the inlet and outlet pipes 155, And operates the compressor unit 152 in an opened state. Accordingly, the air introduced through the air inflow inlet 155 flows into the buoyancy space portion 120b with a strong pressure, and the water in the inside flows through the first flow pipe 153 to the first valve 153-1 . At the same time, when the buoyant member 120 floats in the direction of the arrow shown in the drawing, the user stops the compressor unit 152 and closes the first valve 153-1.

As shown in FIGS. 3 and 4, the motor pump 161 is driven by the time period during which the solar cell module 111 is overheated and the period set by the season, apart from the lifting / lowering of the buoyant body 120, Is controlled.

The water of the cold water is pumped through the water inlet pipe 162 and the water supply pipe 163 in accordance with the operation of the motor pump 161 so that a part of the cold water is pumped through the nozzles 164-1 of the water discharge pipe 164, The water is sprayed to the rear surface of the module 111 and the inner wall of the perforation 120a and then falls to the water phase and the remaining water is discharged to the adjacent water discharge pipe 164 through the water supply pipe 163 connecting the buoyancy bodies 120, And is directly distributed to the rear surface of another solar cell module 111 through the nozzles 164-1.

According to the present invention, the solar cell module heated by the solar heat can be rapidly cooled by pumping cold water deep from the water surface and spraying the solar cell module with perforations.

In addition, it is possible to effectively protect the solar cell module and the structure by effectively preventing the impact from the high wave of the aquifer or the surge, and it is possible to operate the water tower stably.

In addition, the buoyant body can be improved as a unitary structure to simplify the structure, and economical efficiency and assembly productivity can be improved.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that various changes and modifications may be made without departing from the scope of the present invention.

Claims (9)

A solar power generation facility including a solar cell module unit 110;
A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And
Module cooling means 160 for spraying water to the perforations 120a of the buoyant body 120;
≪ / RTI >
The solar cell module unit (110)
And a fastening part 112 bent downward downward from the edge of the solar cell module 111 and having a plurality of bolt holes 112a formed in the longitudinal direction thereof Wherein the solar battery is a solar-powered solar power generator. delete The buoyant body (120) according to claim 1,
And a plurality of communication holes 121a extending upward to correspond to the coupling portions 112 and communicating with the bolt holes 112a of the coupling portion 112 in the longitudinal direction are provided Wherein the solar battery is a solar-powered solar power generator. The method of claim 3,
A first cut-out portion 112b is formed on an upper surface of the coupling portion 112, a second cut-out portion 112c is formed on a lower surface thereof,
The flange portion 121 is provided with a moisture outlet 121b at a portion contacting the first cutout portion 112b and a water outlet 121c at a portion contacting the second cutout portion 112c Wherein the solar battery is a solar-powered solar power generator. The method according to claim 1,
A plurality of longitudinal pipes (132) vertically coupled to the plurality of transverse pipes (131), a plurality of transverse pipes (131) arranged side by side in the buoyant body (120) (130) connected to the ground. 6. The method of claim 5,
Further comprising a footrest (140) installed orthogonally to an upper portion of the plurality of longitudinal pipes (132). A solar power generation facility including a solar cell module unit 110;
A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And
And module cooling means (160) for ejecting water into the perforations (120a) of the buoyant body (120)
A pump unit 151 disposed on one side of the buoyant body 120 and a compressor unit 152 disposed on the other side of the buoyant body 120. One end of the compressor unit 152 is connected to one side of the pump unit 151, A first flow pipe 153 communicating with the buoyant space portion 120b of the buoyant body 120 and a second flow pipe 153 having one end connected to the other side of the pump portion 151 and the other end disposed in the airstream And a buoyancy adjusting means 150 having one end connected to the compressor portion 152 and the other end connected to the buoyant space portion 120b of the buoyant body 120 Wherein said solar cell is connected to said ground. A solar power generation facility including a solar cell module unit 110;
A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And
And module cooling means (160) for ejecting water into the perforations (120a) of the buoyant body (120)
The module cooling means (160)
A water inflow pipe 162 whose one end is connected to one side of the motor pump 161 and the other end is disposed in the water pump, and the other side of the motor pump 161 and the buoyant body 120 And a plurality of nozzles 164-1 disposed on the perforations 120a of the buoyant body 120 and having one end communicating with the water supply pipe 163, (164). ≪ / RTI > A solar power generation facility including a solar cell module unit 110;
A perforation 120a is formed in which the solar cell module unit 110 is seated and supported at an upper end portion inclined at an angle and the upper and lower portions are perforated at the center thereof and a buoyancy- A buoyant body 120 having a space 120b formed therein; And
And module cooling means (160) for ejecting water into the perforations (120a) of the buoyant body (120)
In the buoyant body 120,
And a plurality of air holes (120c) formed in positions opposed to each other through the buoyant space part (120b) and communicating the perforation (120a) with the outside.

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