KR20200070597A - floating solar power generator - Google Patents

Abstract

The present invention relates to a marine solar power generator of a new structure which is effectively prevented from being damaged by waves or typhoons. According to the present invention, depending on a flow state of a water surface, the marine solar power generator increases power generation efficiency of a power generation unit (10) by spacing each power generation unit (10) apart from each other, fixes each power generation unit (10) to be in close contact with each other, or fixes each power generation unit (10) to a fixation stand (32) by lowering each power generation unit (10) to a seabed, thereby effectively preventing the power generation unit (10) from being damaged by the waves.

Description

Floating solar power generator

The present invention relates to a marine solar power generator of a new structure that can be effectively prevented from being damaged by waves or typhoons.

Recently, the use of photovoltaic generators that generate electricity by using eco-friendly energy, sunlight, has increased.

However, in the case of such a photovoltaic generator, since a large area is required, it is becoming a problem to provide a place to install the photovoltaic generator.

Therefore, in recent years, in order to solve this problem, a method for installing a solar power generator on the sea has been devised.

As described above, the photovoltaic generator installed on the sea is composed of a support frame provided with a buoyancy body on the lower side, and a solar panel disposed to be inclined downwardly on the upper portion of the support frame, wherein the solar panel is corroded by seawater. However, it is treated with corrosion and insulation to prevent short circuits.

However, as described above, when the photovoltaic generator is installed on the sea, there is a problem that the photovoltaic generator may be damaged by waves or the sun or be damaged when severe.

In addition, when a plurality of photovoltaic generators are installed in a large area on the sea, sunlight is blocked by the photovoltaic power generator, so that sunlight is not supplied to the bottom of the photovoltaic power generator, and a problem that may adversely affect the marine ecosystem has occurred.

Therefore, there is a need for a new method to solve this problem.

Patent No. 10-0765057,

The present invention is to solve the above problems, and an object thereof is to provide a marine solar power generator of a new structure that can be effectively prevented from being damaged by waves or typhoons.

The present invention for achieving the above object is a marine photovoltaic generator installed on the sea to generate power, a plurality of power generation units arranged to be spaced apart from each other in the front-rear direction, configured to generate power when irradiated with sunlight on the sea surface. (10), a connecting means (20) for interconnecting the power generation unit (10), and is provided on the bottom surface (1) of the seabed and connected to the power generation unit (10) to fix the position of the power generation unit (10) Fixing means (31, 32, 33), and is configured to be floating on the sea surface, the flow sensing means 40 for sensing the flow state of the sea surface, and receiving the signals of the flow sensing means 40, the power generation unit ( 10) and a connecting means (20) and a control means (50) for controlling the operation of the fixing means (31,32,33), the power generation unit (10) includes a support frame (11) and a space therein It is composed of an additionally formed cylindrical shape and an outlet 12a is formed at one side, and a buoyancy body 12 provided at a lower side of the support frame 11 and provided at the outlet 12a are provided by the control means 50. Connected to the buoyancy body 12 and the solar control panel 14 arranged to be inclined downward on the upper portion of the support frame 11, the electronic control valve 13 that is operated and controlled to open and close the outlet 12a. It includes an air supply means (15) for supplying high-pressure air to the interior of the buoyancy body (12), and a water supply pump (16) connected to the buoyancy body (12) to supply seawater to the interior of the buoyancy body (12). And, the connecting means 20 is provided to be extended in the front-rear direction and is connected to the support frame 11 of the power generation unit 10 located at the front and rear ends of the front-rear direction. The cylinder mechanism 21 and the protruding protrusions 22 and the coupling grooves 23 are provided to be mutually corresponded to the front and rear surfaces of the support frame 11 when the front and rear surfaces of the support frame 11 are in close contact with each other. , A support block 24 that is coupled back and forth to the support frame 11 in the front and back and forth by the auxiliary cylinder mechanism 25, and is provided to extend rearward to the support block 24 and drive motor 26a ) Rotated by It includes a fixing screw (26) screwed to the coupling hole (11b) provided in the support frame (11), the fixing means (31,32,33)) is provided on the bottom surface (1) of the seabed and the most A first winch 31 connected to the support frame 11 of the power generation unit 10 located in the front and rear direction, and a fixing unit 32 fixed to the bottom surface 1 of the seabed and fixed to the power generation unit 10 sinking to the seabed 32 ) And a second winch 33 which is provided on the fixture 32 and induces the power generation unit 10 sinking to the seabed to be fixed to the fixture 32, wherein the control means 50 is the cylinder When the respective power generation units 10 are arranged to be spaced apart from each other in the front-rear direction by the mechanism 21, when each sea level flows above the first flow value by receiving the signals from the flow sensing means 40 , After reducing the cylinder mechanism 21 so that each of the power generation units 10 are in close contact with each other so that the protruding protrusion 22 and the engaging groove 23 are mutually coupled, the fixing screw 26 is By driving the support frame 11 of each power generation unit 10 to be fixed to each other, and when the sea level flows above a second flow value set higher than the first flow value, the electronic control valve 13 is opened Then, by driving the pump to supply seawater to the interior of the buoyancy body 12, and simultaneously operating the first and second winches 31 and 33, the power generation unit 10 sinks to the seabed and the anchor 32 When the flow of the sea level decreases below a second flow value by receiving a signal from the flow detection means 40, the first and second winches 31 and 33 are controlled and the air supply means ( 15) by driving the air to supply air to the interior of the buoyancy body 12 so that the seawater stored in the buoyancy body 12 is discharged, so that the power generation unit 10 is floated into the sea. Is provided.

According to another feature of the present invention, the support bracket 61 provided in front of the support frame 11 of the power generation unit 10 and the support bracket 61 are angle-adjustable in the vertical direction and are angled. It includes an reflector 62 that is angle-adjusted in the vertical direction by means 63, and an altitude measuring means 64 provided on one side of the solar panel 14 to measure the altitude of the sun, and the control means ( 50) receiving the signal of the altitude measurement means 64 and controlling the operation of the angle adjustment means 63 so that sunlight is reflected to the lower side of the power generation unit 10 provided in the front A solar power generator is provided.

The offshore solar power generator according to the present invention improves the power generation efficiency of the power generation unit 10 by spaced apart each power generation unit 10 according to the flow state of the water surface, or closes each power generation unit 10 to each other By fixing as much as possible, or by descending to the seabed and fixing to the anchor 32, there is an advantage that the power generation unit 10 can be effectively prevented from being damaged by waves.

1 is a side view showing a marine solar power generator according to the present invention,
Figure 2 is an enlarged side view of a marine solar power generator according to the present invention,
3 is a plan view showing a power generation unit of a marine solar power generator according to the present invention,
Figure 4 is a side view showing a power generation unit of the offshore solar power generator according to the present invention,
Figure 5 is a side cross-sectional view of the power generation unit of the offshore solar power generator according to the present invention,
6 is a circuit diagram of a marine photovoltaic generator according to the present invention,
7 to 9 is a reference diagram showing the operation of the offshore solar power generator according to the present invention,
10 is a side view showing a second embodiment of the offshore solar power generator according to the present invention,
11 is a circuit configuration diagram of a second embodiment of the offshore solar power generator according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached exemplary drawings.

1 to 9 illustrate a marine photovoltaic generator according to the present invention, which is installed on the sea and is intended to generate electricity using sunlight.

In addition, according to the present invention, the offshore solar power generator is configured to generate power when the sun is irradiated on the sea surface, and is arranged to be spaced apart from each other in the front-rear direction and the power generation unit 10. A connecting means (20) for mutual connection, and fixing means (31, 32, 33) provided on the bottom surface (1) of the seabed and connected to the power generation unit (10) to fix the position of the power generation unit (10); , It is configured to be floating on the sea surface, the flow sensing means 40 for detecting the flow state of the sea surface, and receiving the signals of the flow sensing means 40, the power generation unit 10 and the connecting means 20 and the fixing means ( 31, 32, 33)).

In detail, as shown in FIGS. 4 and 5, the power generation unit 10 is composed of a support frame 11 and a cylindrical portion having a space formed therein, and an outlet 12a is formed at one side. A buoyancy body 12 provided on the lower side of the support frame 11, an electronic control valve 13 provided on the outlet 12a and operated and controlled by the control means 50 to open and close the outlet 12a, , A solar panel 14 arranged to be inclined downward in front of the support frame 11, and air supply means connected to the buoyancy body 12 to supply high-pressure air to the interior of the buoyancy body 12 15 and a water supply pump 16 connected to the buoyancy body 12 to supply seawater to the inside of the buoyancy body 12.

The support frame 11 is configured to support a solar panel 14 mounted on an upper surface by combining a bar of high strength metal material in a rectangular shape extending in the lateral direction.

The buoyancy body 12 is composed of a cylindrical extending in the front-rear direction, and is provided at both ends of the lower surface of the support frame 10, so that the support frame 10 is floated to the upper side of the water surface, the strength It is composed of a metal material such as stainless steel having high corrosion resistance, and the outlet 12a is formed to extend downward on the lower side.

The air supply means (15) is provided on one side of the support frame (11), as will be described later, while the power generation unit (10) sinks to the seabed, high-pressure air into the buoyancy body (12). By supplying so that buoyancy is generated in the buoyancy body 12, the power generation unit 10 is floated to the sea.

At this time, an intake pipe 15a is provided at one side of the air supply means 15, and an auxiliary buoyancy body 15b is provided at an end of the intake pipe 15a, and as described later, the power generation unit 10 is provided. When sinking to the seabed, the end portion of the intake pipe 15a is configured to be able to suck air by floating to the top of the sea surface.

The water supply pump 16 is provided on one side of the support frame 11 and is provided with a water supply pipe 16b connected to the buoyancy body 12 and an absorption pipe 16a extending to the lower side of the water surface. Is sucked and supplied to the inside of the buoyancy body 12, so that the buoyancy of the buoyancy body 12 is removed.

The connecting means 20 is provided to extend in the front-rear direction and is connected to the support frame 11 of the power generation unit 10 located at the front-rear end of the front-rear direction. When the front and rear surfaces of the support frame 11 are in close contact with each other, the mechanism 21 and the front and rear surfaces of the support frame 11 are mutually engaged, and the protruding protrusions 22 and the coupling grooves 23 and the front It is coupled to the support frame (11) of the support block 24 which is coupled back and forth by the auxiliary cylinder mechanism (25), and is provided so as to extend backward to the support block (24) and to the driving motor (26a). It is composed of a fixing screw 26 that is rotated by screwed to the coupling hole (11b) provided in the rear support frame (11).

The cylinder mechanism 21 is hingedly coupled to both sides of the support frame 11 in the vertical direction to be rotated in the vertical direction, and supports each power generation unit 10 to flow separately in the vertical direction according to the waves.

The protruding projections 22 are protruded in the form of a pointed cone toward the rear side of the support frame 11 of the power generation unit 10 located in the front and are provided to be spaced apart from each other in the lateral direction.

The coupling groove 23 is concavely formed to correspond to the protruding projection 22 on the front of the support frame 11 of the power generation unit 10 located at the rear.

The support block 24 is formed with a through hole 24a penetrating the front and rear surfaces in the middle portion, and is slidably coupled to the front and rear surfaces of the support frame 11 in the front and rear directions.

The auxiliary cylinder mechanism 25 is provided to extend in the front-rear direction on both rear sides of the support frame 11 so that the support block 24 slides in the front-rear direction according to expansion and contraction.

The fixing screw 26 is rotatably coupled while extending rearward to the through hole 24a of the support block 24 and configured to rotate forward and backward by the driving motor 26a.

At this time, the upper and lower surfaces of the support frame 11 of the power generation unit 10 located at the rear are provided so that the bracket 11a in which the coupling hole 11b is formed corresponds to the fixing screw 26.

The fixing means (31, 32, 33), as shown in Figure 1, is provided on the bottom surface (1) of the seabed and connected to the support frame 11 of the power generation unit 10 located at the front and rear most 1 Winch 31, a fixed base 32 fixed to the bottom surface 1 of the seabed and settled to the seabed, and a fixed base 32 fixed to the fixed base 32 and provided to the bottom 32 of the power generation unit ( 10) is composed of a second winch (33) that guides the fixture 32 to be fixed.

The first winch 31 is composed of a plurality of the power generation unit 10 is fixed to the bottom surface 1 by the anchor bolt so as to be spaced apart in the front-rear direction compared to the fixed position, the plurality of power generation unit ( Among the 10), the wire 31a connected to the support frame 11 of the power generation unit 10 positioned at the most front and the rear is provided.

Therefore, by loosening or pulling the first winch 31 according to the change in the height of the sea level, the power generation unit 10 can be fixed to a predetermined position on the sea level, and the wire of the first winch 31 ( 31a) can be wound so that the power generation unit 10 sinks to the seabed.

The fixing unit 32 is fixed to the bottom surface 1 of the seabed so that the power generation unit 10 is positioned below the floating position, and a seating portion 32a on which the power generation unit 10 is mounted is mounted on the upper surface. Is formed.

The second winch 33 is fixedly coupled to the fixture 32, and is provided with a wire 33a connected to the lower side of the power generation unit 10 located in the middle.

Accordingly, when the power generation unit 10 is sunk to the seabed by winding the wire 31a of the first winch 31, the power generation unit 10 is wound by winding the wire 33a of the second winch 33. This can be guided to the top of the fixture (32).

2, the flow sensing means 40 is provided in the buoyancy case 41, which is composed of a spherical shape of synthetic resin material having high strength and is configured to float on the sea surface, and the buoyancy case 41. It consists of an acceleration sensor (42) for detecting that the buoyancy case (41) flows in the vertical or lateral direction by the waves on the sea level, and is fixed to the power generation unit (10) on the one side by a connection cable (43). It is fixed so that it does not drift away to the distance.

The control means 50 receives the signal from the flow sensing means 40 to measure the flow of the sea level, that is, the magnitude of the waves generated on the sea level, and according to the measured flow value of the sea level, the connecting means 20 ) And the operation of the fixing means (31,32,33).

In detail, first and second flow values are input to the control means 50.

The first flow value is set to a value at which the water surface flows when a strong wind blows and a high wave is generated.

The second flow value is set to a value higher than the first flow value, that is, a value at which the rear surface flows when a typhoon occurs.

Then, when the control means 50 receives the signal of the flow sensing means 40 and the flow value of the water surface is equal to or less than the first flow value, as shown in FIGS. 1 and 2, the connecting means 20 By extending the cylinder mechanism 21 of the power generation unit 10 to be spaced apart from each other in the front-rear direction, the power generation unit located at the rear by the shadow of the photovoltaic panel provided in each power generation unit 10 ( 10) Do not cover the photovoltaic panels.

At this time, the air is stored inside the buoyancy body 12 so that buoyancy is generated in the buoyancy body 12, so that the power generation unit 10 rises above sea level.

In addition, the support block 24, as shown in Figure 4, maintains a state slided forward by the auxiliary cylinder mechanism (25).

And, when the flow value of the water surface received by the flow sensing means 40 rises above the first flow value, the control means 50, as shown in Figure 7, shrink the cylinder mechanism 21 The front and rear surfaces of the support frame 11 of each power generation unit 10 are in close contact with each other.

At this time, the support frame 11 is guided so that the front and rear surfaces are in close contact with each other by the protruding protrusion 22 and the engaging groove 23.

And, as shown in FIG. 8, when the support frame 11 is in close contact with each other, the control means 50 extends the auxiliary cylinder mechanism 25 so that the support block 24 slides backwards. At the same time, by rotating the fixing screw 26 with the drive motor 26a, the fixing screw 26 is screwed to the coupling hole 11b of the support frame 11 located at the rear, thereby generating each power unit. Let (10) be firmly fixed to each other.

In this way, when each power generation unit 10 is fixed to each other by the cylinder mechanism 21 and the fixing screw 26, the entire power generation unit 10 is fixed as one structure, thereby improving the strength against waves. On the other hand, part of the light irradiated to the photovoltaic panel 14 located at the rear by the photovoltaic panel 14 of the photovoltaic power generation unit 10 is obscured, thereby reducing the power generation efficiency of the photovoltaic generator.

Then, when the flow value of the water surface received by the flow detection means 40 rises above the second flow value, the control means 50 opens the electromagnetic control valve 13, and the water supply pump 16 ) To supply seawater to the inside of the buoyancy body 12, thereby removing the buoyancy generated by the buoyancy body 12 and operating the first and second winches 31 and 33, As shown in FIG. 9, the power generation unit 10 is damaged by waves by allowing the mutually fixed power generation unit 10 to sink to the seabed and secured to the seating portion 32a of the fixture 32. prevent.

At this time, when a wave is generated by a typhoon or the like, the surface water of the seawater flows very violently, while the degree of seawater flow decreases toward the seabed, so that the power generation unit 10 is fixed to the bottom surface 1 of the seabed. When fixed to the fixture 32, it is possible to minimize damage to the power generation unit 10 by waves.

Then, the control means 50 receives the signal of the flow sensing means 40, when the flow value of the sea level falls below the second flow value, the wires of the first and second winches (31,33) Loosen (31a, 33a), and operate the air supply means (15) to supply air to the inside of the buoyancy body (12), so that the seawater inside the buoyancy body (12) is discharged to the outside through the outlet (12a) By doing so, buoyancy is generated in the buoyancy body 12.

Therefore, the buoyancy of the buoyancy body 12 causes the power generation unit 10 to rise above the water surface.

In addition, the control means 50 receives the signal of the flow detection means 40, when the flow value of the sea level is lower than the first flow value, by controlling the operation of the connecting means 20, each The power generation unit 10 is separated from the initial state.

The marine photovoltaic generator configured as described above is spaced apart from each power generation unit 10 to improve power generation efficiency of the power generation unit 10 according to the flow state of the water surface, or so that each power generation unit 10 is in close contact with each other. By fixing or descending to the seabed and fixing it to the anchor 32, there is an advantage that the power generation unit 10 can be effectively prevented from being damaged by waves.

10 and 11 show another embodiment according to the present invention, the support bracket 61 provided in front of the support frame 11 of the power generation unit 10, and the support bracket 61 up and down It is coupled to the angle adjustable in the direction, and is provided on one side of the reflector 62 and the angle adjustment in the vertical direction by the angle adjustment means 63, the altitude measurement means provided on one side of the solar panel (14) ( 64) is further provided.

The reflector 62 is rotatably coupled to the support bracket 61 by hinge shafts provided to extend laterally on both sides.

The angle adjustment means 63 is fixed to one side of the upper surface of the solar panel 14 and is connected to the hinge axis of the reflector 62 to use a drive motor that rotates the reflector 62 in the vertical direction according to driving. .

The altitude measurement means 64 measures the altitude of the sun by measuring the angle at which the sun is irradiated, and since various types of things have been developed and used, detailed descriptions thereof will be omitted.

Then, the control means 50 receives the signal of the altitude measurement means 64 and controls the operation of the angle adjustment means 63 so that sunlight is reflected to the lower side of the power generation unit 10 provided in the front. do.

That is, in the state in which the power generation units 10 are spaced apart from each other in the front-rear direction, the light irradiated from the sunlight is blocked by the solar panel 14, at this time, the lower side of each power generation unit 10 Shadow is generated.

And, by the shadow generated as described above, adverse effects may be generated in the marine organisms under each power generation unit 10.

However, when the sunlight is reflected by the reflector 62 to the lower side of the power generation unit 10 provided in the front, a shadow is not generated on the lower side of the power generation unit 10, so that the lower side of the power generation unit 10 It is possible to minimize the occurrence of adverse effects on marine life.

10. Power generation unit 20. Connection means
31,32,33. Fixing means 40. Flow sensing means
50. Control means

Claims (2)

In the offshore solar power generator installed on the sea to generate power,
A plurality of power generation units 10 that are configured to generate power when the sun is irradiated onto the sea surface and are spaced apart from each other in the front-rear direction
Connection means (20) for interconnecting the power generation unit (10),
Fixing means (31,32,33) provided on the bottom surface 1 of the seabed and connected to the power generation unit 10 to fix the position of the power generation unit 10,
It is configured to be floating on the sea surface and the flow sensing means 40 for detecting the flow state of the sea surface,
It includes a control means 50 for receiving the signal of the flow sensing means 40 and controlling the operation of the power generation unit 10 and the connecting means 20 and the fixing means (31,32,33),
The power generation unit 10 is
Support frame (11),
Consists of a cylindrical shape with a space formed therein, and an outlet 12a is formed on one side, and a buoyancy body 12 provided below the support frame 11,
An electronic control valve 13 provided on the outlet 12a and operated and controlled by the control means 50 to open and close the outlet 12a,
A solar panel 14 arranged to be inclined downward in front of the support frame 11,
The air supply means 15 is connected to the buoyancy body 12 to supply high-pressure air to the interior of the buoyancy body 12,
It is connected to the buoyancy body 12 and includes a water supply pump 16 for supplying seawater to the interior of the buoyancy body 12,
The connecting means 20
It is provided to extend in the front-rear direction, and the front and rear ends are connected to the support frame 11 of the power generation unit 10 located in the front-rear direction, and the cylinder mechanism 21 for mutually spaced apart or close to each other according to the expansion and contraction,
Protruding projections 22 and engaging grooves 23 are provided so as to correspond to the front and rear surfaces of the support frame 11, and when the front and rear surfaces of the support frame 11 are in close contact with each other,
A support block (24) that is coupled back and forth to the support frame (11) in the front and back and forth by an auxiliary cylinder mechanism (25),
It is provided to extend rearward to the support block 24 and includes a fixing screw 26 which is rotated by a driving motor 26a and screwed to a coupling hole 11b provided in the rear support frame 11,
The fixing means (31,32,33) is
The first winch 31 is provided on the bottom surface (1) of the seabed and connected to the support frame (11) of the power generation unit (10) located at the front and rear,
And fixed to the bottom surface (1) of the seabed and the power generation unit 10 sinking to the seabed is fixed (32),
It includes a second winch (33) that is provided on the fixture 32 and guides the power generation unit (10) sinking to the seabed to be fixed to the fixture (32),
The control means 50 receives the signal of the flow sensing means 40 in a state in which the respective power generation units 10 are spaced apart from each other in the front-rear direction by the cylinder mechanism 21, so that each sea level is When the flow exceeds the first flow value, the cylinder mechanism 21 is reduced so that each of the power generation units 10 are brought into close contact with each other in the front-rear direction so that the protruding protrusion 22 and the coupling groove 23 are mutually coupled. Then, by driving the fixing screws 26 so that the support frame 11 of each power generation unit 10 is fixed to each other, and when the sea level flows more than the second flow value set higher than the first flow value, The power generation unit 10 is operated by opening the electronic control valve 13 and driving the pump to supply seawater to the inside of the buoyancy body 12 and operating the first and second winches 31 and 33 at the same time. The first and second winches (31,33) are settled to the seabed to be fixed to the anchor 32, and when the flow of the sea level drops below a second flow value by receiving a signal from the flow sensing means 40 At the same time, the air supply means 15 is driven to supply air to the inside of the buoyancy body 12 so that the seawater stored in the buoyancy body 12 is discharged, so that the power generation unit 10 is floated to the sea. Offshore solar power generator, characterized in that.
According to claim 1,
A support bracket 61 provided in front of the support frame 11 of the power generation unit 10,
The support bracket 61 is coupled to the angle adjustable in the vertical direction and the reflector 62 is angle-adjusted in the vertical direction by the angle adjusting means 63,
The support frame 11 includes an altitude measurement means 64 for measuring the altitude of the sun,
The control means 50 receives the signal of the altitude measurement means 64 and controls the operation of the angle adjustment means 63 so that sunlight is reflected to the lower side of the power generation unit 10 provided in the front. Characterized by offshore solar power generator.

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