KR102296599B1 - Floating solar power generating apparatus - Google Patents

Abstract

As an aspect for achieving the above object, the present invention has a set buoyancy, the base floating means disposed around the surface of the water; a floor fixing means fixed to the floor under the water surface, and fixing a distance from the foundation floating means to the floor by a set distance; a base means on which a photovoltaic structure is installed, and the height is adjusted on the base floating means having a fixed position; And, a height adjustment means for adjusting the height between the base means and the base floating means so that the base means corresponds to a change in the water level of the water surface; provides a water-based solar device comprising a.

Description

Floating solar system {FLOATING SOLAR POWER GENERATING APPARATUS}

The present invention relates to a floating solar device that is easy to maintain in response to water level changes.

It should be noted that the content described in this section merely provides background information on the present invention and does not constitute the prior art.

Unlike fixed photovoltaic devices installed on land, floating photovoltaic devices are sensitive to tides, so it is very important to maintain a position to increase system efficiency.

A position maintenance system using a mooring system has been mainly used in the existing floating photovoltaic device, and many related studies have been conducted.

The problem is that the area where the floating photovoltaic device is installed is characterized by a large change in water level such as a river or a dam.

In order to solve the problem of resilience of the mooring system in such a tide difference, a weight method or an elastic body method has been devised.

The weight method can efficiently cope with changes in water depth, but the anchor point is changed due to the fatigue strength problem of the mooring rope used in the weight method or the rising and falling of the structure, so it can deviate from the operation design of the solar structure.

On the other hand, in the case of using an elastic body to respond to water level changes, there is an advantage that a relatively constant restoring force can be maintained even with a water level change, but it is true that it takes a lot of cost to manufacture and install a system with sufficient elasticity.

In particular, since the above system requires periodic inspection, it is very difficult in terms of maintenance if it is installed in a relatively deep place.

KR 10-0887723 B1

As an aspect, the present invention is to provide a floating solar device capable of maintaining a position in response to water level changes and easy maintenance.

As an aspect for achieving the above object, the present invention has a set buoyancy, the base floating means disposed around the surface of the water; a floor fixing means fixed to the floor under the water surface, and fixing a distance from the foundation floating means to the floor by a set distance; a base means on which a photovoltaic structure is installed, and the height is adjusted on the base floating means having a fixed position; and a height adjusting means disposed between the base floating means and the base means, the height of which is adjusted between the base means and the base floating means so that the base means corresponds to a change in the water level of the water surface. The base means, when the water level of the water surface rises, is raised and lowered to follow the change in the water level of the water surface by the buoyancy provided while floating on the water surface, and the height adjusting means is, the lifting and lowering of the base means through the buoyancy provided to the base means It provides a floating solar device in which the height between the base floating means and the base means is adjusted to follow.

Preferably, the base floating means is fixed to a distance set from the floor by the floor fixing means, and can be floated on the water surface or immersed in the lower side of the water surface according to a change in the water level of the water surface.

Preferably, the floor fixing means comprises: an anchor member fixed to the floor below the water surface; and a tension member for fixing a distance between the anchor member and the base floating means at a set distance.

Preferably, the base means, the base frame is installed so as to be height-adjusted on the base floating means; and a rotating frame on which a photovoltaic structure is installed and rotatably installed on the base frame.

Preferably, the height adjusting means may be configured as a height adjusting column whose height is adjusted between the base means and the base floating means through the buoyancy provided to the base means.

Preferably, the height adjustment column, the first adjustment column fixed to either side of the base floating means and the base means; and a second adjusting post fixed to either side of the base floating means and the base means, and being slidably installed with the first adjusting post.

Preferably, a plurality of height adjustment poles are spaced apart from each other between the base floating means and the base means, and the height adjustment means includes an interlocking member for interlocking the plurality of height adjustment poles to be lifted together. can

Preferably, the interlocking member may include: a first gear bar member for interlocking a plurality of first height adjusting posts disposed in a first row among the plurality of height adjusting posts to be raised and lowered together; a second gear bar member for interlocking a plurality of second height adjusting posts disposed in a second row among the plurality of height adjusting posts to be raised and lowered together; and a third gear bar member for interlocking the first gear bar member and the second gear bar member.

Preferably, the height adjusting means, the interlocking member and the interlocking member is configured to be interlocked or disconnected, and provides a separate driving force to drive the interlocking member; may further include.

Preferably, the height adjusting means may include an elastic support member that elastically behaves so that the height between the base means and the base floating means is adjusted through the buoyancy provided to the base means.

Preferably, the height adjustment means, the height between the base means and the base floating means can be adjusted through the buoyancy of the base means itself.

Preferably, the height adjustment means, the height between the base means and the base floating means can be adjusted through the buoyancy of the lifting fluid installed on the base means.

Preferably, the height adjustment means, a surface sensor for measuring the distance between the water surface and the base means; And, based on the information provided by the water surface detection sensor, a lifting and lowering drive member for elevating the base means on the base floating means; may be provided.

According to an embodiment of the present invention, it is possible to maintain a position in response to a water level change, and there is an effect that maintenance is easy.

1 is a perspective view of a floating solar device according to an embodiment of the present invention.
Figure 2a, Figure 2b is a view showing a state before and after the water solar device according to an embodiment of the present invention is the height is adjusted in response to the change in the water level of the water surface.
Figure 3a, Figure 3b is a view showing a state before and after the rotation of the base means of the floating solar device according to an embodiment of the present invention.
Figure 4a, Figure 4b is a partial enlarged view showing a state before and after the height of the floating solar device is adjusted according to an embodiment of the present invention.
Figure 5a, Figure 5b is a transverse cross-sectional view showing the state before and after the interlocking member and the interlocking drive member are interlocked in the height adjusting means of the water-based solar device according to an embodiment of the present invention.
Figure 6a, Figure 6b is a partial enlarged view showing the state before and after the height of the floating solar device is adjusted according to another embodiment of the present invention.
Figure 7a, Figure 7b is a partial enlarged view showing a state before and after the height of the floating solar device according to another embodiment of the present invention is adjusted.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiment of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art. The shapes and sizes of elements in the drawings may be exaggerated for clearer description.

Hereinafter, with reference to Figures 1 to 7b will be described in detail with respect to the floating solar device according to an embodiment of the present invention.

The water photovoltaic device according to an embodiment of the present invention may include a base floating means 100 , a floor fixing means 200 , a base means 300 , and a height adjusting means 400 .

1 to 2b, the water photovoltaic device is fixed to the base floating means 100 and the water surface (S) disposed around the periphery of the water surface (S) with a set buoyancy (S) fixed to the floor (T), the foundation A floor fixing means 200 for fixing from the floating means 100 to the floor T at a set distance, and a photovoltaic structure P are installed, and the height is adjusted on the base floating means 100 in which the position is fixed The base means 300 and the height adjusting means 400 for adjusting the height between the base means 300 and the base floating means 100 so that the base means 300 corresponds to a change in the water level of the water surface (S). ) may be included.

1 to 2b, the base floating means 100 may be fixed to the position of the water surface (S) around the periphery of the water surface (S) while being fixed to the bottom (T).

The base floating means 100 may be fixed in a floating state on the water surface S at a low water level, and fixed in a state immersed in the lower side of the water surface S at a high water level.

The self-weight of the floating solar device may be supported by the buoyancy of the base floating means 100 .

The base floating means 100 may be composed of a single plate-shaped floating frame having a set buoyancy.

Accordingly, the work space of the operator can be secured on the plate-shaped floating frame, and there is an effect that the operator can more easily perform maintenance work on the solar structure P, the height adjustment means 400, and the like.

1 to 2b, the floor fixing means 200, one side is fixed to the bottom (T) of the water surface (S), the other side may be fixed to the base floating means (100).

The floor fixing means 200 can be fixed in a state that is constantly maintained at a set distance from the floor T under the water surface S to the foundation floating means 100 .

In the low water level state and the high water level state, the distance from the bottom T to the foundation floating means 100 may be maintained the same.

When the water surface (S) is the first reference water level (S1) of the low water level state, the floor fixing means 200 can fix the base floating means 100 in a floating state on the water surface (S), and the water surface (S) When it is the second reference water level (S2) of the high water level, the floor fixing means 200 may fix the foundation floating means 100 in a state immersed in the lower side of the water surface (S).

The photovoltaic structure P installed on the base means 300 by the floor fixing means 200 may be stably fixed in the south-facing direction.

In the case of the bottom fixing means 200, the winding member winds the tension member 230 to match the reset first reference water level (S1) when the water level is lowered due to insufficient quantity, etc., and adjustment is required. The distance to the floor T may be adjusted to match the reset first reference water level S1.

At this time, the base floating means 100 is fixed at a position corresponding to the reset first reference water level S1, and if the first reference water level S1 is not reset, even if the water level of the water surface S changes, the bottom T The distance from to the base floating means 100 does not change.

1 to 2b, the base means 300 is a photovoltaic structure (P) is installed on the upper side, the height can be adjusted on the fixed base floating means (100).

The base means 300 is lifted on the base floating means 100 , and the solar structure P installed on the base means 300 may be located above the water surface (S).

The base means 300 is elevated on the foundation floating means 100 according to the change in the water level of the water surface S, and is installed on the foundation floating means 100 to be disposed on the upper side of the water surface S of the installed solar structure P. The height can be adjusted.

The base means 300 may be raised and lowered to follow the change in the water level of the water surface S by the buoyancy of the base means 300 itself or the buoyancy of components additionally installed in the base means 300 .

As an example, the base means 300 may be composed of a buoyancy body having a set buoyancy force, and specifically, the base frame 310 itself of the base unit 300 may be composed of a floating body.

As another example, the buoyancy may be provided to the base means 300 while the lifting fluid 430, which is a component having buoyancy, is additionally installed in the base means 300 .

1 to 2b, the height adjustment means 400 is a height between the base means 300 and the base floating means 100 so that the base means 300 corresponds to the change in the water level of the water surface (S). can be adjusted.

The height adjusting means 400 may be adjusted in height between the base means 300 and the base floating means 100 through the buoyancy provided to the base means 300 .

The base means 300 may be raised and lowered to follow the change in the water level of the water surface S by the buoyancy of the base means 300 itself or the buoyancy of components additionally installed in the base means 300 .

For example, when the base means 300 composed of a buoyancy body moves up and down according to a change in water level, the height adjustment means 400 may be adjusted in height to follow it.

As another example, when the base means 300 on which the lifting fluid 430 is installed as an additional buoyancy chain is lifted according to a change in water level, the height adjustment means 400 may be adjusted in height to follow it.

The height adjusting means 400 adjusts the height of the base means 300 in response to a change in the water level of the water surface (S), and the solar structure (P) installed on the base means (300) is positioned on the water surface (S). can do.

The height adjusting means 400 may connect the base floating means 100 and the base means 300 to be elevating.

The height adjustment means 400 may raise and lower the base means 300 on the base floating means 100 so that the solar structure P is disposed on the upper side of the water surface S.

At this time, the height adjusting means 400 is configured to move mainly in the vertical direction, and the movement in the forward, backward, left and right directions and the movement in the rotational direction on a plane may be limited to a minimum.

Preferably, the height adjustment means 400 may be configured to be movable only in the vertical direction.

At this time, the meaning of the height adjusting means 400 being configured to be movable only in the vertical direction is a concept including minute movement in the forward, backward, left, right, and rotational directions on a plane due to a fine tolerance between the connected components.

The photovoltaic structure (P) installed on the base means (300) by the floor fixing means (200) can be stably fixed in the south-facing direction, and the base means (300) on which the photovoltaic structure (P) is installed is flat by water flow, etc. It can be prevented that the fixed direction of the photovoltaic structure (P) is arbitrarily changed while rotating in the phase.

The floating photovoltaic device of the present invention is capable of stably maintaining the position of the photovoltaic device installed on the base means 300 in response to water level changes while the height is adjusted in a short section between the base floating means 100 and the base means 300 . It works.

In the conventional case, the length of the tension member 230 and the like is adjusted in a long section from the fixed point fixed to the floor T under the water surface S to the solar device disposed on the upper side of the water surface S, As the possibility of errors in length adjustment increases, there is a problem in that it is difficult for the photovoltaic device to stably maintain its position in response to water level changes.

The water photovoltaic device of the present invention has a photovoltaic structure (P), a height adjustment means (400), etc. that require frequent inspection, are arranged around the water, so that when the water level is lowered, the photovoltaic structure (P), etc. It can be inspected, and it can be inspected on the foundation floating means 100 with secured working space, so that the work efficiency of the operator during maintenance is improved, and the maintenance cost can be reduced.

The base floating means 100 is fixed at a distance set from the bottom T by the bottom fixing means 200, and floats on the water surface S according to the change in the water level of the water surface S or below the water surface S. can be immersed in

Referring to Figure 2a, the base floating means 100 may be fixed in a floating state on the water surface (S) at a low water level.

Referring to Figure 2b, the base floating means 100 may be fixed in a state immersed in the lower side of the water surface (S) at a high water level.

The basic floating means 100 maintains a floating state on the water surface S at the first reference water level S1 in the low water level state, and the second reference water level in the high water level in which the water level is raised from the first reference water level S1. It is possible to maintain a state immersed in the lower side of the water surface (S) in (S2).

The base floating means 100 may be fixed in a state in which the distance from the floor T under the water surface S is kept constant.

Therefore, the base floating means 100 maintains a floating state on the water surface (S) at the first reference water level (S1), but at the second reference water level (S2) where the water level is increased from the first reference water level (S1) It is possible to maintain a state immersed in the lower side of the water surface (S).

The base floating means 100 has a set buoyancy, and supports at least a portion of the self-weight of the floating solar device of the present invention by buoyancy in a state floating on the water surface (S) or immersed in the lower side of the water surface (S). can

1 and 2b, the floor fixing means 200, the anchor member 210 fixed to the floor T under the water surface S, and the anchor member 210 and the base floating means ( 100) may be provided with a tension member 230 for fixing the distance between the set distance.

Anchor member 210 may be fixed to the floor (T) under the water surface (S).

The tension member 230 connects the anchor member 210 and the base floating means 100 in a tensioned state, and between the anchor member 210 and the base floating means 100 may be fixed at a set distance. .

The tension member 230 may be composed of a rope or a wire, which is a linear member, and thus may be applied to a relatively large depth of water.

2a and 2b, the tension member 230 is installed in the vertical direction, the anchor member 210 and the foundation floating means 100 installed on the floor T under the water surface S in a straight line. By connecting the base floating means 100 can be fixed.

The floor fixing means 200 may include a plurality of anchor members 210 and a plurality of tension members 230 .

For example, the floor fixing means 200 may fix the four corner portions of the base floating means 100 to the floor T via the tension member 230 and the anchor member 210 .

The tension member 230 is the anchor member 210 installed on the floor T in a state in which the base floating means 100 is suspended on the water surface S when the water surface S is the low water level, the first reference water level S1. can be fixed.

The floor fixing means 200 may further include a winding member for winding the tension member 230 to reset the distance from the floor T to the base floating means 100 .

At this time, the base floating means 100 is fixed to the reset distance from the bottom (T) to the foundation floating means 100, even if the water level of the water surface (S) changes from the bottom (T) to the foundation floating means (100) distance does not change.

Of course, unlike the present invention, a method of installing a steel column directly supporting the entire self-weight of the floating solar device from the floor (T) to the water can be considered.

However, in this case, there was a problem that the installation cost of a fixed structure such as a steel column may increase as the installation of the fixed structure becomes excessive.

The floating photovoltaic device of the present invention does not need to install a fixed structure such as a steel column for supporting the entire self-weight by using the anchor member 210 and the tension member 230, thereby reducing the construction cost while being installed on the base means 300. There is an effect that the solar structure P can be stably fixed in the south-facing direction.

Of course, unlike the present invention, according to the change of the water level of the water surface (S), the length of the tension member 230 connecting between the foundation floating means 100 and the anchor member 210 fixed to the floor T is controlled. method can be considered.

In this case, the length is controlled in the installation section of the tension member 230 having a relatively long length. In the process of controlling the length of the tension member 230, the tension member 230 is bent by the water flow to adjust the length. When an error occurs, there is a problem that the solar structure P cannot be stably fixed in the south-facing direction.

In addition, as tension is continuously applied to the equipment for controlling the length of the tension member 230 , there is a problem in that frequent damage to the equipment may occur.

And, when it is installed in a relatively deep place, the section controlling the length of the tension member 230 is relatively long, and there is a problem that may cause great difficulties in terms of maintenance, and the tension member 230 installed in the water has a problem. There is a problem that the maintenance work of the operator due to the underwater work of the operator may become difficult because the case of having to check underwater may become frequent.

On the other hand, referring to Figure 2a, the water photovoltaic device of the present invention is located on the water surface at the first reference water level (S1) of the low water level state, the inspection work can be performed on the water surface, so the inspection operation can be relatively easy and , it is possible to work on the base floating means 100 having a certain area, there is an effect that the work can be made easier.

Referring to FIGS. 3A and 3B , the base means 300 is a base frame 310 that is installed so as to be height-adjusted on the base floating means 100 , and a photovoltaic structure P is installed, and the installed sunlight The structure P may include a rotation frame 330 that is rotatably installed on the base frame 310 so as to follow the sun.

The base frame 310 is installed on the base floating means 100 via the height adjustment means 400 , and may be lifted up and down on the foundation floating means 100 through the buoyancy provided to the base frame 310 .

The rotating frame 330 may be rotatably installed in the circumferential direction from the upper side of the base frame 310 through a driving force of a frame rotating member (not shown).

Accordingly, the solar structure P installed on the rotation frame 330 can follow the position of the sun while rotating along the movement trajectory of the sun.

The base frame 310 and the rotating frame 330 may be configured in a circular plate shape, and the rotating frame 330 may be rotated in a state disposed in a groove formed on the upper surface of the base frame 310 .

For example, although not shown, the frame rotating member (not shown) includes an arc-shaped rack gear (not shown) formed in the circumferential direction of the rotating frame 330 , and an arc-shaped rack gear (not shown) fixed to the base frame 310 . City) may be configured to include a rotational drive motor (not shown) formed with a pinion gear (not shown).

4a and 4b, the height adjustment means 400, the height between the base means 300 and the base floating means 100 through the buoyancy provided to the base means 300 is adjusted. It may be composed of a height adjustment column (410).

The height adjustment column 410 may be connected to a plurality of adjustment columns slidably.

One end of the height adjustment column 410 may be connected to the base means 300 , and the other end may be fixed to the base floating means 100 .

The height adjustment column 410 may be adjusted in height between the base floating means 100 and the base means 300 .

The height adjustment column 410 can be adjusted in height as the base means 300 rises and falls according to a change in the water level of the water surface (S).

The height adjustment column 410 can be adjusted in height as the base means 300 is raised and lowered on the fixed base floating means 100 through the buoyancy provided to the base means 300 according to the change in the water level of the water surface (S). .

When the water level of the water surface (S) rises, the basic floating means (100) is immersed under the water surface (S) and sequentially the base means (300) floats on the water surface (S), and the buoyancy provided to the base means (300) As the distance between the base floating means 100 and the base means 300 increases through the medium, the height of the height adjustment column 410 may be increased.

When the water level of the water surface (S) is lowered, the base means (300) floating on the water surface (S) is descended, and as the distance between the base floating means (100) and the base means (300) is narrowed, the height adjustment pillar (410) ) can be lowered.

A plurality of height adjustment columns 410 may be spaced apart between the base means 300 and the base floating means 100 .

As an example, referring to FIGS. 1 and 2B , the base means 300 and the base floating means 100 may be configured in a square plate shape, and each height adjustment pole 410 around the four corners of the square plate shape. This can be placed

Of course, when the size of the base means 300 and the base floating means 100 is increased, the height adjustment column 410 may be additionally disposed between the two corners of the square plate shape.

4A and 4B, the height adjustment column 410 is a first adjustment column 411 fixed to either side of the base floating means 100 and the base means 300, and the base floating means ( 100) and the base means 300, which is fixed to the other side, and may include a second adjustment column 412 that is slidably installed with the first adjustment column 411.

A rack gear (G) is installed on one side of the first adjusting post 411 and the second adjusting post 412, and the other side of the first adjusting post 411 and the second adjusting post 412 is meshed with the rack ear. A pinion gear (H) may be installed.

As an example, the first adjusting post 411 has an upper side fixed to the lower side of the base means 300, and the second adjusting post 412 has a lower side fixed to the upper side of the base floating means 100 and a first adjusting post ( 411) may be installed to slide.

The first adjusting post 411 may be provided with a rack gear G, and the second adjusting post 412 may be provided with a pinion gear H meshing with the rack ear.

When the base means 300 is raised and lowered, the first adjusting post 411 fixed to the base means 300 moves up and down together, and the pinion gear (H) meshed with the rack gear (G) is rotated while the first adjusting post ( 411) can be stably raised and lowered on the second adjustment column (412).

5a and 5b, between the base floating means 100 and the base means 300, a plurality of height adjustment pillars 410 are spaced apart disposed, the height adjustment means 400, An interlocking member 450 for interlocking the plurality of height adjustment pillars 410 to be lifted together may be further provided.

Referring to FIGS. 5A and 5B , the interlocking member 450 interlocks the plurality of first height adjusting posts 410-1 disposed in the first row among the plurality of height adjusting posts 410 to be lifted together. The first gear bar member 451 and the second gear bar member 452 interlocking the plurality of second height adjusting posts 410-2 disposed in the second row among the plurality of height adjusting posts 410 to be raised and lowered together ) and a third gear bar member 453 for interlocking the first gear bar member 451 and the second gear bar member 452 .

The plurality of first height adjusting posts 410 - 1 may be disposed in a first row on the left side, and the plurality of second height adjusting posts 410 - 2 may be disposed on the right side of the second row.

The plurality of first height adjustment columns 410-1 and the plurality of second height adjustment columns 410-2 may be connected to be height-adjusted between the base means 300 and the base floating means 100 .

The first gear bar member 451 may be connected to each of the plurality of first height adjusting posts 410-1 disposed in the first row, and may be raised and lowered by interlocking the plurality of first height adjusting posts 410-1. .

The second gear bar member 452 may be connected to a plurality of second height adjusting posts 410-2 disposed in the second row, respectively, and may be raised and lowered by interlocking the plurality of second height adjusting posts 410-2. .

The third gear bar member 453 is respectively connected to the first gear bar member 451 and the second gear bar member 452 , and interlocks the first gear bar member 451 and the second gear bar member 452 . can do it

When the third gear bar member 453 rotates, the first gear bar member 451 and the second gear bar member 452 rotate at the same time while the plurality of first height adjustment posts 410-1 and the plurality of second heights are rotated. The adjustment column 410-2 may be raised and lowered at the same time.

The first gear bar member 451 includes a first pinion gear 451-1 and a first pinion gear 451 which are respectively meshed with the rack gear G formed on the plurality of first height adjustment posts 410-1. 1) is formed at one end of the first gear shaft 451-2 and the first gear shaft 451-2 to which the third gear bar member 453 is of the third gear bar member 453, the 3-1 barbell gear 453-1 ) and may be provided with a first barbell gear 451-3 meshed with.

The second gear bar member 452 includes a second pinion gear 452-1 and a second pinion gear 452 which are respectively meshed with the rack gears G formed on the plurality of second height adjustment posts 410-2. 1) is formed at one end of the second gear shaft 452-2 and the second gear shaft 452-2 to which the third gear bar member 453 is of the third gear bar member 453, the 3-2 barbell gear 453-2 ) and may be provided with a second barbell gear 452-3 meshed with.

The third gear bar member 453 includes a 3-1 first barbell gear 453-1 meshing with the first barbell gear 451-3 and a 3-2 second meshing with the second barbell gear 452-3. A barbell gear 453-2 and a third gear shaft 453-3 on which the 3-1 barbell gear 453-1 and the 3-2 barbell gear 453-2 are installed may be provided.

The first gear shaft 451-2, the second gear shaft 452-2, and the third gear shaft 453-3 may be rotatably fixed to the bearing block (I).

For example, referring to FIGS. 5A and 5B , the base means 300 and the base floating means 100 may be configured in a rectangular plate shape.

At this time, the two first height adjustment pillars 410 - 1 may be disposed to be spaced apart from each other while forming a first row in the front and rear directions around the left edge of the square plate shape.

Two second height adjustment pillars 410-2 around the right edge of the square plate shape may be disposed to be spaced apart while forming a second row in the front-rear direction.

Of course, when the size of the base means 300 and the base floating means 100 increases, at least one or more first 1.5 height adjustment columns (not shown) may be additionally disposed between the two corners of the rectangular plate shape.

At this time, a 1.5 gear bar member (not shown) for interlocking a plurality of height control pillars arranged in a row between the first row and the second row among the plurality of height control pillars 410 to be raised and lowered together may be provided. have.

The 1.5 gear bar member (not shown) may be installed to interlock with the third gear bar member 453 .

1.5 The gear bar member (not shown) is installed to interlock with the third gear bar member 453 through meshing between the barbell gears in a manner corresponding to the first gear bar member 451 or the second gear bar member 452 . can be

When the third gear bar member 453 rotates, the first gear bar member 451, the 1.5 gear bar member, and the second gear bar member 452 rotate at the same time while the plurality of height adjustment posts 410 are simultaneously rotated. can be elevated

5A and 5B , the height adjustment means 400 is configured to be interlocked with or disconnected from the interlocking member 450 , and provides a separate driving force to drive the interlocking member 450 . It may further include an interlocking drive member 460.

The interlocking member 450 may be driven by a separate driving force of the interlocking driving member 460 , and when the interlocking member 450 is driven, the plurality of height adjustment pillars 410 may be integrally lifted and lowered.

The interlocking driving member 460 may be configured to be interlocked with the interlocking member 450 or to be interlocked with each other.

The interlocking drive member 460 may be installed so as to move forward and backward in the direction of the interlocking member 450 .

The interlocking driving member 460 may include a driving pinion gear 461 and an interlocking driving motor 463 rotating the driving pinion gear 461 .

The interlocking driving member 460 may be advanced to the interlocking member 450 to be interlocked with the interlocking member 450 , and the interlocking to the interlocking member 450 may be disconnected while moving backward.

Specifically, when the interlocking drive member 460 is advanced to the interlocking member 450, the driving pinion gear 461 of the interlocking drive member 460 is formed on the third gear bar of the interlocking member 450. The third pinion gear ( 453-4) and the interlocking drive member 460 and the interlocking member 450 may be interlocked.

When the interlocking drive member 460 is moved backward from the interlocking member 450, the driving pinion gear 461 is disengaged from the third pinion gear 453-4, and the interlocking drive member 460 and the interlocking member 450. interlocking may be broken.

6A and 6B, the height adjustment means 400 is such that the height between the base means 300 and the base floating means 100 is adjusted through the buoyancy provided to the base means 300 as a medium. An elastic support 470 that elastically behaves may be provided.

When the base means 300 goes up and down while following the change in the water level of the water surface S, the elastic support 470 elastically behaves between the base floating means 100 and the base means 300 to adjust the length, and accordingly The height between the base means 300 and the base floating means 100 may be adjusted.

The elastic support 470 includes a coil spring 471 fixed to the upper surface of the base floating means 100 and the lower surface of the base means 300, respectively, and a housing pillar 473 for accommodating the coil spring 471 to surround it. can do.

The housing pillar 473 is fixed to the upper surface of the base floating means 100 , and a coil spring 471 may be accommodated therein.

When the base means 300 rises by following the change in the water level due to the rise in the water level of the water surface S, the coil spring 471 may extend to the outside of the housing column 473 .

When the base means 300 rises by following the water level change due to the drop of the water level of the water surface (S), the coil spring 471 may be accommodated in the housing column 473, and the upper end of the housing column 473 is lowered. It is possible to support the lower surface of one base means (300).

At this time, the coil spring 471 moves in the vertical direction while at least the lower region is accommodated in the housing pillar 473 , and movement other than the vertical direction can be minimized.

Although not shown, the elastic support 470 may be composed of only the coil spring 471 fixed to the upper surface of the base floating means 100 and the lower surface of the base means 300, respectively.

The height adjusting means 400 may be adjusted in height between the base means 300 and the base floating means 100 through the buoyancy provided to the base means 300 .

The base means 300 may be raised and lowered to follow the change in the water level of the water surface S by the buoyancy of the base means 300 itself or the buoyancy of components additionally installed in the base means 300 .

As an example, the height adjusting means 400 may be adjusted in height between the base means 300 and the base floating means 100 through the buoyancy of the base means 300 itself.

The base means 300 may itself be composed of a buoyant body.

When the base means 300 composed of a buoyancy body moves up and down according to a change in water level, the height adjustment means 400 may adjust the height between the base means 300 and the base floating means 100 to follow it.

In another example, the height adjustment means 400 is the height between the base means 300 and the base floating means 100 through the buoyancy of the lifting fluid 430 installed in the base means 300 is adjusted. can be

The lifting fluid 430 may be installed on the lower side of the base means 300 to provide buoyancy.

Additionally, when the base means 300 on which the buoyancy chain elevating fluid 430 is installed is elevating according to the water level change, the height adjusting means 400 follows the height between the base means 300 and the base floating means 100. can be adjusted.

7A and 7B, the height adjustment means 400 is a surface (S) detection sensor 480 for measuring the distance between the water surface (S) and the base means 300, and the water surface (S) Based on the information provided by the detection sensor 480, the base means 300 on the base floating means 100 may be provided with a lift driving member 490 for elevating.

The lifting driving member 490 raises and lowers the base means 300 based on the information about the distance between the water surface S and the base means 300 received from the water surface (S) detection sensor 480 to elevate the base means ( The photovoltaic structure (P) installed in 300) may be disposed to be located above the water surface (S).

For example, the lift driving member 490 may be composed of a hydraulic cylinder, a pneumatic cylinder, or the like.

A control member for receiving information from the water surface (S) detection sensor 480 and controlling the operation of the hydraulic cylinder and the like may be installed in the lift driving member 490 .

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and variations are possible within the scope without departing from the technical spirit of the present invention described in the claims. It will be apparent to those of ordinary skill in the art.

100: base floating means 200: floor fixing means
210: anchor member 230: tension member
300: base means 310: base frame
330: rotating frame 400: height adjustment means
410: height adjustment column 410-1: first height adjustment column
410-2: second height adjustment column 411: first adjustment column
412: second control column 430: lifting fluid
450: interlocking member 451: first gear bar member
451-1: first pinion gear 451-2: first gear shaft
451-3: first barbell gear 452: second gear bar member
452-1: second pinion gear 452-2: second gear shaft
452-3: second barbell gear 453: third gear bar member
453-1: 3-1 Babel Gear 453-2: 3-2 Babel Gear
453-3: third gear shaft 453-4: third pinion gear
460: interlocking drive member 461: drive pinion gear
463: interlocking drive motor 470: elastic support
471: coil spring 473: housing column
480: sleep detection sensor 490: elevating drive member
G: rack gear H: pinion gear
I: Bearing block P: Solar structure
S: surface S1: first reference water level
S2: second reference water level T: bottom

Claims (13)

Basic floating means disposed around the surface of the water with a set buoyancy;
a floor fixing means fixed to the floor under the water surface, and fixing a distance from the foundation floating means to the floor by a set distance;
a base means on which a photovoltaic structure is installed, and the height is adjusted on the base floating means having a fixed position; and,
a height adjusting means disposed between the base floating means and the base means, the height of which is adjusted between the base means and the base floating means so that the base means corresponds to a change in the water level of the water surface;
The base means,
When the water level of the water surface rises, it is raised and lowered to follow the water level change of the water surface by the buoyancy provided while floating on the water surface,
The height adjustment means,
Floating solar device in which the height between the base floating means and the base means is adjusted to follow the elevation of the base means through the buoyancy provided to the base means.
According to claim 1, wherein the base floating means,
Floating solar device, characterized in that fixed to a distance set from the floor by the floor fixing means, floating on the water surface according to the change in the water level of the water surface or immersed in the lower side of the water surface.
According to claim 2, wherein the floor fixing means,
An anchor member fixed to the floor below the water surface; and,
Floating photovoltaic device comprising a; a tension member for fixing between the anchor member and the base floating means at a set distance.
According to claim 1, wherein the base means,
a base frame installed to be height-adjusted on the base floating means; and,
Floating photovoltaic device comprising a; a photovoltaic structure is installed, the rotating frame is rotatably installed on the base frame.
According to claim 1, wherein the height adjustment means,
Floating photovoltaic device consisting of a height adjustment column whose height is adjusted between the base means and the base floating means through the buoyancy provided to the base means.
According to claim 5, The height adjustment column,
a first adjusting column fixed to either side of the base floating means and the base means; and,
Floating photovoltaic device comprising a; fixed to any other side of the base floating means and the base means, and a second adjustment column slidably installed with the first adjustment column.
6. The method of claim 5,
A plurality of height adjustment columns are spaced apart between the base floating means and the base means,
The height adjustment means,
Floating photovoltaic device further comprising a; interlocking member for interlocking the plurality of height adjustment pillars to be lifted together.
The method of claim 7, wherein the interlocking member,
a first gear bar member for interlocking a plurality of first height adjusting posts disposed in a first row among the plurality of height adjusting posts to be raised and lowered together;
a second gear bar member for interlocking a plurality of second height adjusting posts disposed in a second row among the plurality of height adjusting posts to be raised and lowered together; and,
Water photovoltaic device having; a third gear bar member for interlocking the first gear bar member and the second gear bar member.
According to claim 7, wherein the height adjustment means,
Floating photovoltaic device further comprising a; configured to enable interlocking or disconnection of the interlocking member with the interlocking member, and providing a separate driving force to drive the interlocking member.
According to claim 1, wherein the height adjustment means,
Floating photovoltaic device having an elastic support that elastically behaves so that the height between the base means and the base floating means is adjusted through the buoyancy provided to the base means.
The method according to any one of claims 1 to 10, wherein the height adjustment means,
Floating solar device, characterized in that the height between the base means and the base floating means is adjusted through the buoyancy of the base means itself.
The method according to any one of claims 1 to 10, wherein the height adjustment means,
Floating solar device, characterized in that the height between the base means and the base floating means is adjusted through the buoyancy of the lifting fluid installed on the base means.
According to claim 1, wherein the height adjustment means,
a sleep sensor for measuring the distance between the water surface and the base means; and,
Floating photovoltaic device comprising a; elevating drive member for elevating the base means on the base floating means based on the information provided by the water surface detection sensor.

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