KR102072553B1 - Floating Photovoltaic Equipment - Google Patents

Abstract

The present invention relates to a photovoltaic power generation apparatus installed on water. According to the present invention, disclosed is a floating photovoltaic power generation apparatus comprising: a photovoltaic panel unit including a photovoltaic panel for generating electric energy by receiving sunlight; a mount unit for supporting the photovoltaic panel unit from a lower side of the photovoltaic panel unit; and a floating unit disposed on a lower side of the mount unit to support the mount unit, and configured to float on water, wherein a gap adjustment means capable of adjusting a gap spaced apart from another floating photovoltaic power generation apparatus connected to be adjacent on the water is provided, thereby suppressing generation of an area where sunlight is not incident on the photovoltaic panel due to shadow of an adjacent photovoltaic panel. Therefore, disclosed is a technique which has an effect of suppressing deterioration of floating photovoltaic power generation efficiency by shadow of the photovoltaic panel, and improves utilization of photovoltaic energy which is pollution-free new renewable energy.

Description

Floating Photovoltaic Equipment

The present invention relates to a power generation device using solar light, and more particularly, to a water-based photovoltaic device for efficiently utilizing solar light disposed in the water phase.

In recent years, in order to solve the problem of environmental pollution caused by energy use, there is a growing interest in pollution-free and clean energy that is not environmentally friendly.

Photovoltaic is attracting attention as one of the representative pollution-free clean energy, and a lot of research on the electric energy acquisition technology using solar light is made.

Electrical energy using sunlight is usually obtained using a solar cell that receives sunlight and converts it into electrical energy. In addition, since the amount of electrical energy that can be obtained by one solar cell is limited, a large number of solar panels using a large area of a plurality of solar cells as one panel are used.

In order to secure a lot of electrical energy that can be obtained using the solar panel, it is important to distribute the solar panel over a larger area to obtain more solar energy. On the other hand, there is a problem that it is difficult to secure the terrain to install the solar panel from the geographical environment or spatial influences on the ground.

Therefore, as a method of securing the installation area, a water-based photovoltaic device is installed on the surface of a river, a lake, a reservoir, a dam, the sea, etc., which can easily secure a sufficient amount of sunshine and an open large area.

Conventionally, a plurality of water photovoltaic devices are installed in an assembly to cope with fluctuations in the water surface. In this way, when a plurality of water photovoltaic devices are installed as an assembly, the distance between neighboring solar panels is fixed, and when the altitude of the sun becomes low depending on the season or time, the shadow of the solar panels becomes long and the neighboring sun There was a problem of covering part of the light panel.

As such, when a part of the neighboring solar panels is covered by the shadow of the solar panel, there is a problem that the solar power generation efficiency is inevitably deteriorated.

Republic of Korea Patent No. 10-1543727

An object of the present invention is to solve the conventional problems as described above, the water-based solar light that can suppress the generation of a region in which sunlight is not incident on the solar panel due to the shadow of the neighboring solar panel In providing a power generation device.

According to an embodiment of the present invention for achieving the above object, a water-based photovoltaic device, the solar panel unit including a photovoltaic panel for generating electrical energy by receiving sunlight; A mount unit for supporting the solar panel unit under the solar panel unit; And a floating part disposed below the mount to support the mount and floating in the water, and being separated from other water solar devices connected adjacent to each other in the water. It may be characterized by one provided that the gap adjusting means for adjusting the interval.

Here, the floating portion, the gap adjusting means; And a pontoon body having an upper side coupled to the lower side of the mount portion and having an accommodation space for accommodating at least a portion of the gap adjusting means therein.

Further, the gap adjusting means, one end is located in the receiving space of the pontoon body, the other end is fastened to the pontoon body of the other water-based photovoltaic device neighboring to the left or right, the left and right threads are formed Spacing bar; A left and right space adjustment gear disposed in the accommodation space of the pontoon body and rotating in contact with the left and right space adjustment bar to push or pull the left and right space adjustment bar; And a left and right spacing control motor disposed in the accommodation space of the pontoon body and rotating the left and right spacing adjusting gear.

Further, the gap adjusting means, spaced apart from the left and right interval control bar is arranged in parallel with the left and right interval control bar, connecting the pontoon body adjacent to each other and the left and right interval assistant to assist the movement of the left and right interval control bar. It may also be another feature to include a bar.

Here, the gap adjusting means, one end is located in the receiving space of the pontoon body, the other end is fastened to the pontoon body of the other water-phase photovoltaic device neighboring the front side or the rear side, the thread is formed Front and rear spacing control bar; A front and rear gap adjustment gear disposed in the accommodation space of the pontoon body and rotating in contact with the front and rear gap adjustment bar to push or pull the front and rear gap adjustment bars; And a front and rear gap adjustment motor disposed in the accommodation space of the pontoon body, and configured to rotate the front and rear gap adjustment gears.

Further, the interval adjusting means, spaced apart from the front and rear interval control bar is arranged in parallel with the front and rear interval control bar, connecting the pontoon body adjacent to each other and assist the movement of the front and rear interval control bar. It may also be another feature to include a bar.

In addition, the mount portion is provided on the lower side of the solar panel unit, the elevation angle adjusting means for adjusting the elevation of the front of the solar panel toward the sun; A rotation body provided below the solar panel unit and providing a space in which the elevation control means is disposed and supporting the solar panel unit; And a mount body coupled to an upper side of the floating part and disposed below the rotation body to support the rotation body.

In addition, the solar panel unit may be hinged to the rotation body of the mount unit to further adjust the angle between the upper surface of the rotation body and the solar panel unit.

Further, the elevation adjustment means, one end is coupled to the rear side of the solar panel portion, has a fan-shaped arc or arch shape is formed by a predetermined length to the rotation body side, a fan-shaped gear formed on the outer surface; An elevation control gear rotating in contact with an outer surface of the fan-shaped gear having a thread; And an elevation control motor mounted on the inside of the rotation body and configured to rotate the elevation adjustment gear.

Further, the mount portion, disposed between the rotation body and the mount body, the azimuth angle adjusting means for adjusting the azimuth angle to the front of the solar panel toward the sun; It may be.

Furthermore, the azimuth adjustment means, the rotation gear coupled to the lower side of the rotation body is located inside the mount body and the thread formed on the outer peripheral surface; An azimuth adjustment gear which is in contact with an outer circumferential surface of the rotation gear in which a thread is formed and rotates the rotation gear; And an azimuth adjustment motor disposed in a mount space provided inside the mount body and rotating the azimuth adjustment gear.

In the water-based photovoltaic device according to the present invention, it is suppressed that a region in which solar light is not incident on the solar panel due to the shadow of the neighboring solar panel is suppressed. Therefore, there is an effect of suppressing the deterioration of the water-based photovoltaic efficiency by the shadow of the solar panel, and furthermore has the effect of increasing the utilization of solar energy, a new pollution-free renewable energy.

1 is a view schematically showing a side cross-section of a water photovoltaic device according to an embodiment of the present invention.
2 is a view schematically showing the plane of the water photovoltaic device according to an embodiment of the present invention.
Figure 3 is a view schematically showing a flat cross-sectional view of the floating portion in the water photovoltaic device according to an embodiment of the present invention.
4 is a view schematically showing one embodiment in which a plurality of water-based photovoltaic devices according to an embodiment of the present invention are connected.
5 is a view schematically showing another form in which a plurality of water photovoltaic devices according to an embodiment of the present invention are connected.

Hereinafter, a preferred embodiment with reference to the accompanying drawings to be described in more detail with respect to the present invention will be described.

1 is a view showing a side cross-sectional view of a side to a portion of a water photovoltaic device according to an embodiment of the present invention, Figure 2 is a schematic view of the plane of the water photovoltaic device according to an embodiment of the present invention. 3 is a view schematically showing the appearance of the flat section of the floating portion in the water photovoltaic device according to an embodiment of the present invention.

1 to 3, the water photovoltaic device according to an embodiment of the present invention includes a floating portion provided with a solar panel portion, a mount portion and the gap adjusting means.

The solar panel unit 100 is made of a solar panel that receives the sunlight to generate electrical energy, preferably further comprises a solar panel frame that is coupled to the solar panel to support.

The solar panel is composed of one solar panel including one or a plurality of solar cells to generate electrical energy by receiving solar heat or sunlight.

The solar panel frame is coupled to the mount unit 200 to be described later, the solar panel is coupled to the solar panel frame can be said to be supported by the solar panel frame.

The mount unit 200 supports the solar panel unit 100 under the solar panel unit 100.

The mount unit 200 preferably includes an elevation control means, a rotation body 220 and a mount body 210, and more preferably further includes an azimuth adjustment means.

Elevation control means is provided on the lower side of the solar panel unit (100). Then, the front surface of the solar panel of the solar panel unit 100 adjusts the elevation angle toward the sun.

Here, the elevation may be expressed as the angle of the height between the horizontal plane or the horizontal plane and the line where the solar panel faces the sun.

Such elevation control means may include a fan-shaped gear 260, an elevation control gear 250 and an elevation control motor 240, as shown in FIG.

One end of the fan gear 260 is coupled to the rear side of the solar panel unit (100). As shown in FIG. 1, the fan gear 260 has a fan or arc shape having a fan shape and is formed to have a predetermined length toward the rotation body 220. And the screw thread is formed on the outer surface of the fan-shaped gear 260, by contact with the elevation control gear 250 is able to move in engagement.

The elevation control gear 250 rotates in contact with the outer surface of the fan-shaped gear 260 is threaded. That is, the screw thread formed on the outer circumferential surface of the elevation control gear 250 meshes with the thread thread formed on the outer surface of the fan gear 260 so that the fan gear 260 also rotates at a predetermined angle by rotation of the depletion control gear.

Elevation control motor 240 is fixedly mounted on the inside of the rotation body (220). Then, the elevation control gear 250 is rotated by receiving electric energy. As shown in FIG. 2, it is also preferable that the elevation control gear 250 is directly connected to the rotation shaft of the elevation adjustment motor 240 so that the elevation adjustment gear 250 is rotated by the elevation adjustment motor 240.

The rotation body 220 is provided below the solar panel unit 100 as referenced in FIGS. 1 and 2. And, it provides a space in which the elevation adjustment means is arranged to support the solar panel unit 100.

Then, the solar panel unit 100 is hinged 230 to the rotation body 220 of the mount unit 200, as shown in Figure 1, the upper side of the rotation body 220 and the solar panel unit ( It is desirable to be able to adjust the angle between 100).

In addition, as shown in FIG. 1, it is also preferable that a support cushion 223 that can be supported while being in contact with a portion of the solar panel unit 100 is provided on the upper portion of the rotation body 220. When the solar panel unit 100 is laid in parallel with the upper side of the rotation body 220, the support cushion 223 comes into contact with a portion of the solar panel unit 100.

Therefore, since the support cushion 223 supports a portion of the solar panel unit 100 when laying down the solar panel unit 100 for safety in a strong windy environment, the solar panel unit 100 may be shaken by strong winds, thereby preventing the risk of breakage. Do.

As shown in FIGS. 1 and 2, the mount body 210 is coupled to the upper side of the floating part 300 and disposed below the rotation body 220 to support the rotation body 220. Therefore, the mount body 210 is supported by the rotation body 220, it can be stably rotated by the azimuth adjustment means.

The azimuth adjustment means is disposed between the rotation body 220 and the mount body 210. The front of the solar panel adjusts the azimuth angle to the sun.

Such azimuth adjustment means preferably includes a rotation gear 560, azimuth adjustment gear 550 and azimuth adjustment motor 540 as referenced in the drawings.

The rotation gear 560 is coupled to the lower side of the rotation body 220 and positioned inside the mount body 210. Since the rotation gear 560 is coupled to the rotation body 220, the rotation body 220 also rotates together when the rotation gear 560 rotates. And the outer peripheral surface of the rotation gear 560 is preferably formed with a thread that can be engaged with the azimuth adjustment gear 550.

The azimuth adjustment gear 550 abuts on the outer circumferential surface of the rotation gear 560 in which a thread is formed. Then, the azimuth adjustment gear 550 rotates to rotate the rotation gear 560.

The azimuth adjustment motor 540 is disposed in a mount space provided inside the mount body 210 as referenced in the drawing. Then, the azimuth adjustment gear 550 is rotated by receiving electric energy. Although the azimuth adjustment gear 550 is illustrated in the drawings directly connected to the rotation axis of the azimuth adjustment motor 540 by way of example, but not limited to this form, the rotational force by the rotation of the azimuth adjustment motor 540 rotation gear ( 560 is enough to be able to rotate the rotation body 220.

The floating unit 300 is disposed below the mount unit 200 to support the mount unit 200 and is provided to be floating in the water, and is connected to other water solar power generation apparatuses adjacent to each other in the water. It is preferable that the gap adjusting means is provided to adjust the spaced apart).

The floating part 300 preferably includes a gap adjusting means and a pontoon body 310.

Here, the pontoon body 310 is coupled to the lower side of the mount 200, the upper side, as shown in Figure 3, it is preferable that the receiving space is provided to accommodate at least some of the gap adjusting means inside. The pontoon body 310 illustrated in FIG. 3 is formed to include a bottom (bottom) and four walls, and is illustrated in a form in which an accommodation space is provided.

The space adjusting means may include a left and right space adjusting bar 340, a left and right space adjusting gear 330, and a left and right space adjusting motor 320, and preferably further includes a left and right space auxiliary bar 350. It may be.

In addition, the interval adjusting means may be made to include a front and rear interval control bar 440, a front right interval control gear and the front and rear interval control motor, preferably further includes a front and rear interval assistant bar 450.

The left and right interval control bar 340 is located in the receiving space in the pontoon body 310, one end is pontoon body of the other water photovoltaic device 10 adjacent to the left or right side as shown in FIG. Is fastened to 310. And a thread is formed on one side of the left and right interval control bar 340.

The left and right spacing adjusting gear 330 is disposed in the receiving space of the pontoon body 310 and rotates in contact with the left and right spacing adjusting bar 340 to push or pull the left and right spacing adjusting bar 340. That is, the thread of the left and right interval adjusting gear 330 is engaged with the thread of the left and right interval adjusting bar 340 to rotate the left and right interval adjusting bar 340. Since the other end of the left and right interval control bar 340 is fastened to the pontoon body 310 of the other water photovoltaic device 10 adjacent to each other, the left and right interval control bar 340 is adjacent to each other as the movement moves. The spacing of the device 10 is adjusted.

Left and right interval control motor 320 is disposed in the receiving space of the pontoon body 310. And rotates the left and right interval control gear 330 by receiving electrical energy. As shown in FIG. 3, the left and right space adjustment gear 330 is directly connected to the rotation axis of the left and right space adjustment motor 320, and the left and right space adjustment gear 330 is rotated as the rotation axis of the left and right space adjustment motor 320 rotates. ) Will also rotate.

The left and right interval assistant bar 350 is spaced apart from the left and right interval control bar 340 is disposed in parallel with the left and right interval control bar 340, connecting the neighboring pontoon body 310 and the left and right interval control bar 340 ) To assist the movement.

If the left and right interval assistant bar 350 is provided, it is preferable because the linear movement of the left and right interval adjustment bar 340 helps to be made in parallel stably.

Front and rear interval control bar 440 is located in one side of the receiving space of the pontoon body 310. Then, the other end is fastened to the pontoon body 310 of the other water photovoltaic device 10 adjacent to the front side or the rear side. It is preferable that a thread is formed on one side of the front and rear interval adjusting bar 440.

The front and rear interval adjustment gear 430 is disposed in the accommodation space of the pontoon body 310. Then, the front and rear interval adjustment bar 440 rotates in contact with the front and rear interval adjustment bar 440 to push or pull.

The thread of the front and rear interval adjusting gear 430 is engaged with the thread of the front and rear interval adjusting bar 440 to rotate, so that the front and rear interval adjusting bar 440 moves. Since the other end of the front and rear interval control bar 440 is fastened to the pontoon body 310 of another adjacent water photovoltaic device 10, the front and rear interval control bar 440 is adjacent to each other as the movement moves. The spacing of the device 10 is adjusted.

Front and rear interval control motor 420 is disposed in the receiving space of the pontoon body 310. Then, the electric energy is supplied to rotate the front and rear interval adjusting gear 430. 3, the front and rear interval adjustment gear 430 is preferably directly connected to the rotation axis of the front and rear interval adjustment motor 420, and as the rotation axis of the front and rear interval adjustment motor 420 rotates, 430 is also rotated.

The front and rear interval assistant bar 450 is spaced apart from the front and rear interval control bar 440 by a predetermined interval and arranged in parallel with the front and rear interval control bar 440, connecting the neighboring pontoon body 310 and the front and rear interval control bar ( 440 assists movement.

If the front and rear interval assistant bar 450 is provided, it is preferable because the linear movement of the front and rear interval control bar 440 can be made to be stably parallel.

Such a water-based photovoltaic device 10 is preferable because the distance from the adjacent water-based photovoltaic device 10 can be adjusted.

4 is a view schematically showing a form in which a plurality of water-based photovoltaic devices according to an embodiment of the present invention are connected, and FIG. 5 schematically shows another form in which a plurality of water-based photovoltaic devices according to an embodiment of the present invention are connected. The figure shown.

As shown in FIG. 4 or 5, the plurality of water photovoltaic devices 10 may be connected to the plurality of water photovoltaic devices 10 so as to be adjacent to each other in front, rear, left and right directions.

In the afternoon before and after about noon when the sun's altitude is high, the shadow formed by the solar panel facing the sun is shortened. Therefore, it can be adjusted so that the interval between the adjacent water-based photovoltaic device 10 is narrow.

When the sun's altitude is low, such as at sunrise or sunset, the shadows cast by the solar panels are long. Therefore, as shown in FIG. 5, the distance between the plurality of water photovoltaic devices 10 may be extended so that the shadow of the solar panel does not cast on the neighboring solar panel. Therefore, an area where sunlight cannot be incident on a neighboring solar panel is not generated due to the shadow of the solar panel.

As described above, the water-based photovoltaic device 10 according to the embodiment of the present invention is suppressed from generating an area where solar light is not incident on the photovoltaic panel due to the shadow of the neighboring photovoltaic panels installed in the water surface. . Therefore, there is an effect of suppressing the deterioration of the water-based photovoltaic power generation efficiency by the shadow of the solar panel, and further has the advantage that the utilization of the photovoltaic energy, a new pollution-free renewable energy.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments have only been described with reference to a preferred embodiment of the present invention, the present invention has been described above. It should not be understood to be limited only to the embodiments, and the scope of the present invention should be understood by the claims and equivalent concepts described below.

100: solar panel unit
200: mount unit
210: mount body 220: rotation body
240: elevation control motor 250: elevation adjustment gear
260: fan gear
300: rich man,
310: pontoon body 320: left and right spacing motor
330: left and right space adjusting gear 340: left and right space adjusting bar
350: left and right interval bar
420: front and rear gap adjustment motor 430: front and rear gap adjustment gear
440: before and after interval control bar 450: before and after interval assistant bar
540: azimuth adjustment motor 550: azimuth adjustment gear
560: rotation gear

Claims (11)

A solar panel unit including a solar panel that receives sunlight and generates electrical energy;
A mount unit for supporting the solar panel unit under the solar panel unit; And
Is arranged on the lower side of the mount portion to support the mount, floating portion provided to be floating in the water; including a water-based photovoltaic device,
A spacing control means is provided to adjust the spacing apart from other water photovoltaic devices connected adjacent to each other in the water surface.
The floating portion,
The gap adjusting means; And
And a pontoon body having an upper side coupled to the lower side of the mount and having an accommodation space for accommodating at least some of the gap adjusting means therein.
The gap adjusting means,
One side end is located in the receiving space of the pontoon body, the other end is fastened to the pontoon body of the other water-based photovoltaic device adjacent to the left or right side, the left and right spacing bar is formed;
A left and right space adjustment gear disposed in the accommodation space of the pontoon body and rotating in contact with the left and right space adjustment bar to push or pull the left and right space adjustment bar; And
It is disposed in the receiving space of the pontoon body, the left and right spacing control motor for rotating the left and right spacing control gear; a water-based photovoltaic device comprising a.
delete delete The method of claim 1,
The gap adjusting means,
Spaced apart from the left and right interval control bar is arranged in parallel with the left and right interval control bar, connecting the pontoon body adjacent to each other and the left and right spacing assistant bar to assist the movement of the left and right spacing bar; Water photovoltaic device.
The method of claim 1,
The gap adjusting means,
A front and rear interval adjusting bar having one end positioned in the accommodation space of the pontoon body, the other end being fastened to the pontoon body of the other water-based photovoltaic device adjacent to the front side or the rear side, and having a screw thread formed therein;
A front and rear gap adjustment gear disposed in the accommodation space of the pontoon body and rotating in contact with the front and rear gap adjustment bar to push or pull the front and rear gap adjustment bars; And
And a front and rear gap adjustment motor disposed in the accommodation space of the pontoon body, and configured to rotate the front and rear gap adjustment gears.
The method of claim 5,
The gap adjusting means,
Spaced apart from the front and rear interval control bar is arranged in parallel with the front and rear interval control bar, connecting the pontoon body adjacent to each other and the front and rear interval assistant bar to assist the movement of the front and rear interval control bar; Water photovoltaic device.


The method according to claim 4 or 6,
The mount unit,
An elevation control means provided at a lower side of the solar panel unit and configured to adjust an elevation at which the front surface of the solar panel faces the sun;
A rotation body provided below the solar panel unit and providing a space in which the elevation control means is disposed and supporting the solar panel unit; And
And a mount body coupled to an upper side of the floating part and disposed below the rotation body to support the rotation body.
The method of claim 7, wherein
The solar panel unit is hinged to the rotation body of the mount unit is characterized in that the angle between the upper side of the rotation body and the solar panel unit can be adjusted.
In claim 8
The elevation control means,
One end is coupled to the rear side of the solar panel portion, has a fan-shaped arc or arch shape is formed by the predetermined length to the rotation body side, the fan-shaped gear formed on the outer surface;
Elevation adjustment gear that rotates in contact with the outer surface of the fan-shaped gear is formed; And
And an elevation control motor mounted on the inside of the rotation body and configured to rotate the elevation control gear.
The method of claim 9,
The mount unit,
An azimuth angle adjusting means disposed between the rotation body and the mount body, and configured to adjust an azimuth angle of which the front side of the solar panel faces the sun.
The method of claim 10,
The azimuth adjustment means,
A rotation gear coupled to a lower side of the rotation body and positioned inside the mount body and having a thread formed on an outer circumferential surface thereof;
An azimuth adjustment gear which is in contact with an outer circumferential surface of the rotation gear in which a thread is formed and rotates the rotation gear; And
And an azimuth adjustment motor disposed in the mount space provided inside the mount body and rotating the azimuth adjustment gear.

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