KR20100009470U - A device for solar generation of electric power on water - Google Patents

Abstract

The present invention is a photovoltaic device that is installed on the water, not on the ground, and relates to a water-based photovoltaic device having a structure that the solar power device is firmly supported on the water to generate power, and the solar panel is mounted on the buoy fixing frame. The support frame is fixed, a plurality of cylindrical buoys are fixed to the bottom of the buoy fixing frame, the lower rectangular frame and the upper rectangular frame made of rectangular pipes are fixed on the upper part of the cylindrical buoy to form a single buoy fixing frame, Cylindrical buoys are characterized in that the buoy fixing frame is supported in the water phase so that the solar power generation by the solar panel in the water can be configured.

Solar, power generation, award, buoy, buoy fixed frame

Description

A device for solar generation of electric power on water}

The present invention relates to a water-based photovoltaic device, and more particularly, a photovoltaic device installed on water rather than on the ground, and having a structure in which a photovoltaic device is firmly supported on water to generate power. It relates to a photovoltaic device.

In general, a solar battery is a photovoltaic cell that converts solar energy into electrical energy, and its application fields include electric clocks, radios, unmanned light towers, unmanned repeaters, buoy lights, satellites, and rockets. It is used. In addition, solar heating houses, fog warning lights that alert drivers when a fog is on the road, and aviation obstacles installed in structures such as transmission towers are also used as solar cell applications.

The solar cell used in this field of application is to connect the cells (Cell, 1 solar cell) and cells in series and as many times as necessary in order to make solar panels, and then to make these solar panels in series and in parallel. Use by connecting.

On the other hand, such solar cells can use the power generated directly during the day when it can receive sunlight, but since the power is not produced at night, to obtain power continuously, configure a circuit and charge the battery once in the day. Must be placed and used.

In the conventional photovoltaic device, a solar cell panel in which solar cells are connected in parallel in parallel as necessary is fixed at an angle of about 35 degrees toward the south direction. This is to produce the maximum power by making the angle of incidence of the solar light and the solar panel at a right angle in a fixed state.

However, in the case of Korea, the altitude of the sun varies from 12 degrees to 58 degrees in each season, so when the solar panel is fixed, there is a problem that power efficiency is low and efficiency is low in preparation for investment cost.

In general, for solar power generation, solar panels are installed in large quantities on the land of several kilometers, and there are many difficulties in finding a suitable installation place due to the lack of land for installing many solar panels.

The large and smooth land has a high land price, making it difficult to buy for solar power, and it is difficult to find a sunny place.

The present invention is devised to solve the above-mentioned problems, and there is an object of using an empty water surface by installing a solar panel on the water surface without the need for a large site.

And when installing the solar panel in the water, there is a purpose to provide a water-based photovoltaic device that is firmly fixed to the shaking of the water surface, and can support the solar panel with a simple structure.

The solar panel is installed in the water, but the angle of the solar panel is to be configured to change according to the movement of the sun.

The present invention is a photovoltaic device that is connected to a plurality of solar panels in order to achieve the above object, the solar panel support frame is fixed on the buoy fixing frame, a plurality of cylindrical buoys are fixed to the bottom of the buoy fixing frame The lower rectangular frame and the upper rectangular frame made of rectangular pipes are fixed to the upper part of the cylindrical buoy to form one buoy fixing frame. The buoy fixed frame is fixed to form a row as a connecting frame, and the upper part of the cylindrical buoy is inserted into a space consisting of a lower rectangular frame and an upper rectangular frame, and then the fixed frame is formed of a lower rectangular frame. Wrap cylindrical buoys across the width The solar panel support frame vertically connects the upper rectangular frame and the lower rectangular frame, but forms a longer vertical frame longer than the short vertical frame, and connects the upper ends of the plurality of long vertical frames and the short vertical frame with horizontal frames, respectively. After fixing the horizontal frame connecting the top of the long vertical frame and the horizontal frame connecting the top of the short vertical frame to each other in the vertical frame, or to fix the solar panel to the vertical frame,

The buoy fixing frame is fixed to form a row as a connecting frame, and the upper part of the cylindrical buoy is inserted into the space consisting of the lower rectangular frame and the upper rectangular frame, and the fixing frame is fixed so as to surround the cylindrical buoy in the width direction of the lower rectangular frame. A plurality of struts are fixed to the upper surface of the buoy fixing frame, and a solar panel support frame is rotatably fixed to the struts by an actuator, and the struts are fixed with a crossbar in the center between two longitudinal bars, and a plurality of solar panel support frames are provided. Vertical frames are fixed to the horizontal frame at regular intervals, the support bracket is fixed to one side of the horizontal frame, the hinge formed on the lower side of the support bracket and the top of the support and rotatably fixed, the sun on the lower side of the support bracket One end of the solar panel mount is fixed horizontally with the solar panel The upper end of the fixed stand and the movable stand is fixed rotatably, the square cap formed at the center of the bolt hole is fixed to the lower end of the movable stand, and the stop plate formed with the stop hole is formed on the upper surface of the lower stand of the movable stand. It is rotatably fixed to the hinge formed on the upper surface of the support, the movable stand is inserted into the hollow of the inner side of the support stationary, the stopper is composed of two protruding plate body is formed on the longitudinal upper surface of the support station, between the stopper The stop plate is moved, but the pin is inserted and fixed at the same place where the stop plate of the stop plate is located among the plurality of stop holes formed in the stopper, and the square cap is fixed to the bottom of the holding fixture, and the bottom of the bolt rod is attached to the square cap. It is rotatably fixed so that when the bolt bar is rotated, it is engaged with the bolt hole of the square cap of the movable table and rotated to move the movable table back and forth. The aqueous phase, characterized providing a photovoltaic device.

As described above, the present invention does not need to purchase expensive land because it is not installed on the ground, and because it can be installed regardless of the terrain, there is an effect that does not require a flattening operation.

Since the photovoltaic device is installed in the water, there is an effect that the efficiency decrease by geothermal heat does not occur in summer.

And the present invention can be installed easily, even if the solar power unit installed in the water, there is an effect that can firmly fix the solar power unit.

In addition, as can be seen in the embodiment of the present invention can be installed in a fixed as well as a variable type has the effect of increasing the efficiency by rotating the solar panel according to the irradiation angle of sunlight.

Referring to the configuration of the present invention in detail with reference to the accompanying drawings as follows.

The terms or words used in this specification and claims are not to be construed as being construed in a conventional or dictionary sense, and the inventors may appropriately define the concept of terms in order to best describe their own design. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention on the basis of the principle of the present invention.

The present invention is to install a photovoltaic device in which a plurality of solar panels (1) are fixed to the solar panel support frame (20, 70) to generate photovoltaic power to float on the water to generate power in the water, buoy The solar panel support frames 20 and 70 are fixed on the fixed frame 10, and a plurality of cylindrical buoys 30 are firmly supported on the bottom of the buoy fixing frame 10 to stably support the photovoltaic device on the water surface. Supporting, the solar panel support frame 20, 70 is characterized in that it is configured in a fixed or variable type, respectively.

The buoy fixing frame 10 forms a lower rectangular frame 11 and an upper rectangular frame 12 having different widthwise sizes of the frame fixed by welding such that the square pipe has a rectangular shape. At this time, the width of the lower rectangular frame 11 is formed larger than the upper rectangular frame 12 to fix the cylindrical buoy 30 to the lower rectangular frame 11, a solar panel support frame on the upper surface of the upper rectangular frame 12 Fix it.

The lower rectangular frame 11 and the upper rectangular frame 12 are integrally connected to each other and fixed to the upper portion of the cylindrical buoy 30 to form one buoy fixing frame, and a plurality of cylindrical buoys support the buoy fixing frame in the water phase. Thus, it is possible to perform photovoltaic power generation by the solar panel 1 in the water phase.

The offshore photovoltaic device of the present invention has two embodiments, the first of which is the fixed offshore photovoltaic device 100 is well illustrated in FIGS. 1 to 3.

The buoy fixing frame 10 fixed with a plurality of solar panels 1 in a row is fixed to form a row with a connecting frame 40, and is cylindrical in a space consisting of a lower rectangular frame 11 and an upper rectangular frame 12. After the upper portion of the buoy 30 is inserted, the fixed frame 13 is fixed to the lower rectangular frame 11 to surround the cylindrical buoy 30 across the width direction of the lower rectangular frame 11.

The solar panel support frame 20 vertically connects the upper rectangular frame 12 and the lower rectangular frame 11 to form a longer vertical frame 21 than the short vertical frame 22.

The upper ends of the plurality of long vertical frames 21 and the short vertical frames 22 are connected to each other by the horizontal frames 23, and the horizontal frames 23 and the short vertical frames that connect the upper ends of the long vertical frames 21 are fixed. The horizontal frame 23 connecting the upper end of the 22 is fixed to the vertical frame 24 connected to each other. The inclination occurs in the vertical frame 24 by the inclination caused by the height difference between the long vertical frame 21 and the short vertical frame 22, and achieves an ideal inclination angle of 35 degrees when the solar panel 1 is fixed.

When fixing the solar panel 1 to the vertical frame 24 is fixed with a fixed clip, generally, the shape of the fixed clip is used by selecting from the conventional clip of the structure capable of stably supporting the solar panel (1).

A second embodiment of the present invention is shown in Figures 4-8.

The buoy fixing frame 10 may be fixed to form a row as the connecting frame 40 as in the first embodiment, the upper portion of the cylindrical buoy 30 in the space consisting of the lower rectangular frame 11 and the upper rectangular frame 12 After the insertion, the fixing frame 13 is fixed to surround the cylindrical buoy 30 across the width direction of the lower rectangular frame 11.

The plurality of struts 60 are fixed to the upper surface of the buoy fixing frame 10, and the solar panel support frame 70 is rotatably fixed to the struts 60 by the actuator 80 to adjust the angle of the solar panel. Adjust it to receive the maximum amount of sunlight.

The strut 60 is a crossbar 62 is fixed to the center between the two vertical poles 61, the solar panel support frame 70 is a plurality of vertical frame 71 is fixed to the horizontal frame 71 at a predetermined interval. . A hinge 62-1 is formed at the center of the upper surface of the crosspiece 62 to rotatably fix the strut holder 82 of the actuator 80.

The support bracket 73 is fixed to one side of the horizontal frame 71 of the solar panel support frame 70, and is rotatable with the hinge 61-1 formed at the lower side of the support bracket 73 and the upper end of the support 60. Is fixed. Therefore, while rotating the solar panel support frame 70 around the hinge (61-1) of the upper end of the solar panel 1 and the angle of the sun can be adjusted close to the vertical.

One end of the solar panel mounting bracket 81 is fixed or integrally formed on the lower side of the support bracket 73 in the horizontal direction with the solar panel 1, and the other end of the solar panel mounting bracket 81 and the movable stand 83 are formed. The top is rotatably fixed.

Since the movable stand 83 is formed to be movable within the prop holder 82, the solar panel support frame 70 is rotated according to the movement of the movable stand 83.

A square cap 83-1 having a bolt hole formed at the center of the movable table 83 is fixed, and a bolt rod 84 engaged with the bolt hole of the square cap 83-1 is provided. A stop plate portion 83-2 having a stop hole 83-3 formed on an upper surface of the lower end of the movable table 83 is combined with a stopper 82-2 to be described later, thereby fixing it so as not to move.

The hinge 61-1 formed on one side of the central lower portion of the support stem 82 and the upper surface of the crosspiece 62 of the support 60 is rotatably fixed to each other, and the movable stand 83 is moved to the inner hollow portion of the support holder 81. It is inserted to be movable.

The stopper portion 82-2 is formed of two protruding plate bodies on the longitudinal upper surface of the support holder 82, and the stop plate portion 83-2 is moved between the stopper portions 82-2. The pins are inserted and fixed at the same time where the stop holes 83-3 of the stop plate portion 83-2 are located among the plurality of stop holes 82-3 formed in the 82-2. Between the two protruding plate bodies constituting the stopping portion 82-3, a slit is formed through which an inner hollow penetrates to move the stop plate portion 83-2.

Square cap (82-1) is fixed to the lower end of the holding bracket 82, the lower end of the bolt rod 84 to the square cap (82-1) is rotatably fixed when moving the bolt rod 84 The movable stand 83 is moved back and forth while being engaged with the bolt hole of the square cap 83-1 of the stand 83.

An operating end 84-1 is formed at the bottom of the bolt rod 84 so that it can be easily turned using a tool. The operating end 84-1 is configured to be rotatable using an angle wrench or a screwdriver.

The square cap 82-1 of the bolt rod 84 and the holding rod 82 is fixed only to rotate and not to move back and forth, and the square cap 83-1 of the movable table 83 is a bolt rod ( A thread that engages the thread of 84) is formed in the hole. Therefore, the rectangular cap (83-1) that can not be rotated in accordance with the rotation with the bolt rod 84 is to push the movable table in the front and rear direction as the rotation.

1 is a perspective view showing a fixed water photovoltaic device of the water photovoltaic device of the present invention.

Figure 2 is an enlarged view of the circular dotted line portion of Figure 1 showing the water photovoltaic device of the present invention.

Figure 3 is a side view showing a fixed water photovoltaic device of the water photovoltaic device of the present invention.

Figure 4 is a perspective view of a variable water photovoltaic device of the water photovoltaic device of the present invention.

5 is a perspective view showing a variable water photovoltaic device of the water photovoltaic device of the present invention from another direction.

Figure 6 is a view showing the operating state of the variable water photovoltaic device of the water photovoltaic device of the present invention.

Figure 7 is a side view showing a variable water photovoltaic device of the water photovoltaic device of the present invention.

8 is an exploded perspective view showing an actuator used in the variable water photovoltaic device of the water photovoltaic device of the present invention.

 BRIEF DESCRIPTION OF THE DRAWINGS FIG.

1 solar panel 10 buoy fixing frame

11: lower rectangular frame 12: upper rectangular frame

13: fixed frame 20: solar panel support frame

21: long vertical frame 22: short vertical frame

23: horizontal frame 30: cylindrical buoy

40: connecting frame 50: variable water state photovoltaic power generation device

60: prop 61: vertical stand

61-1: Hinge 62: Rung

62-1: hinge 70: solar panel support frame

71: horizontal frame 72: vertical frame

73: support bracket 80: actuator

81: solar panel fixing stand 82: holding fixture

82-1: Square cap 82-2: Stopping part

82-3: stop hole 83: moving table

83-1: Square cap 83-2: Stop plate

83-3: Stopping hole 84: Bolt rod

84-1: operating end 100: fixed water state photovoltaic device

Claims (4)

In the photovoltaic device is formed by connecting a plurality of solar panels, The solar panel support frame is fixed on the buoy fixing frame, and a plurality of cylindrical buoys are fixed on the bottom of the buoy fixing frame, and the lower rectangular frame and the upper rectangular frame made of rectangular pipes are fixed on the upper part of the cylindrical buoy, thereby fixing one buoy fixing frame. This is formed, a plurality of cylindrical buoys support the buoy fixed frame in the water phase, characterized in that configured to enable solar power generation by the solar panel in the water phase. According to claim 1, the buoy fixing frame 10 is fixed to form a row to the connecting frame 40, the upper portion of the cylindrical buoy 30 in the space consisting of the lower rectangular frame 11 and the upper rectangular frame 12 After being inserted, the fixed frame 13 is fixed to surround the cylindrical buoy 30 in the width direction of the lower rectangular frame 11, and the solar panel support frame 20 is the upper rectangular frame 12 and the lower rectangular frame. (11) connected vertically, but the long vertical frame 21 is formed longer than the short vertical frame 22, the plurality of long vertical frame 21 and the top of the short vertical frame 22, respectively, the horizontal frame (23) After fixing by connecting the horizontal frame 23 connecting the top of the long vertical frame 21 and the horizontal frame 23 connecting the top of the short vertical frame 22 fixed to each other by the vertical frame 24 Fixing the solar panel (1) to the vertical frame (24) Water solar-electric power generator, characterized in that. According to claim 1, the buoy fixing frame 10 is fixed to form a row to the connecting frame 40, the upper portion of the cylindrical buoy 30 in the space consisting of the lower rectangular frame 11 and the upper rectangular frame 12 After insertion, the fixing frame 13 is fixed to surround the cylindrical buoy 30 in the width direction of the lower rectangular frame 11, and a plurality of struts 60 are fixed to the upper surface of the buoy fixing frame 10. , The solar panel support frame (70) to the support (60) is characterized in that the water-powered solar power plant is rotatably fixed by the actuator (80). According to claim 3, the strut 60 is fixed to the crosspiece 62 in the center between the two longitudinal poles 61, the solar panel support frame 70 is a plurality of vertical frame 71 is a horizontal frame at regular intervals ( It is fixed to the 71, the support bracket 73 is fixed to one side of the horizontal frame 71, rotatable with the hinge (61-1) formed on the lower side of the support bracket 73 and the upper end of the support (60) It is fixed, one end of the solar panel mounting bracket 81 is fixed to the lower side of the support bracket (73) horizontally with the solar panel (1), the upper end of the solar panel mounting bracket 81 and the movable table (83) is rotatable It is fixed, the square cap (83-1) formed in the center of the bolt hole is fixed to the lower end of the movable table 83, the stop plate portion 83 is formed with a stop hole (83-3) formed on the upper surface of the lower stage of the movable table (83) -2) is formed, and the hinge (61-1) formed on the upper surface of the center and one side of the lower side of the support holder 82 is fixed to each other rotatably fixed, The movable stand 83 is movably inserted into the inner hollow portion of the 81, and a stopping portion 82-2 consisting of two protruding plate bodies is formed on the longitudinal upper surface of the holding rod 82. The stop plate portion 83-2 is moved between the 82-2 portions, and the stop plate 83- of the stop plate portion 83-2 of the plurality of stop holes 82-3 formed in the stopper portion 82-2. 3) at the same time the pin is inserted and fixed at the same time, the square cap (82-1) is fixed to the lower end of the holding bracket 82, the lower end of the bolt rod 84 to the square cap (82-1) It is rotatably fixed so that the rotation of the bolt rod 84, the water-phase photovoltaic power generation, characterized in that to move the front and rear movement of the moving table 83 while rotating in engagement with the bolt hole of the square cap (83-1) of the moving table (83). Device.

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