KR102007655B1 - Aquatic structure for installing solar module - Google Patents

Abstract

A water structure for installing a solar module is disclosed. The present invention, the cross-shaped block is a coupling element disposed inside the water structure; A first intermediate block that can be coupled to a side of the cross block; A second intermediate block that can be coupled to the other side of the cross block; T-shaped block that can be installed on the outermost of the water structure; And an upper cover part installed at the top of the cross block, the first intermediate block, the second intermediate block, and the T-type block assembly.

Description

AQUATIC STRUCTURE FOR INSTALLING SOLAR MODULE}

The present invention relates to a water structure for installing a solar module, more specifically, to install a variety of buoyancy body in the form of a block in order to install the water photovoltaic power plant facilities in the water, buoyancy by adjusting the internal water level by pneumatic or hydraulic The present invention relates to a water structure for installing a solar module that can be controlled.

In general, photovoltaic power generation refers to a power generation method using a principle that electric current is generated through the movement of electrons generated when light energy is injected into a solar cell composed of a semiconductor.

Since the solar power generation uses the solar energy provided indefinitely, there is no fuel cost and no pollution such as air pollution or waste generation.

However, it is pointed out that the high initial investment cost, high generation cost, and large installation area are required.

In recent years, the method of installing photovoltaic devices in rivers or lakes has been attracting attention to solve such installation area problems, and there have been successful cases of practical use, but there have been no installation attempts in the seas yet, and compared to rivers and lakes. Due to the harsh environment, many difficulties are expected.

The invention relates to an apparatus or method for installing a photovoltaic power generation facility on the surface of the water, as described in Korean Patent Application Publication No. 10-1162473, "Aquatic Photovoltaic Power Generation System with Variable Support Rope" and Korean Patent Publication No. 10-1318791. "Variable rope-supported water-based photovoltaic device", "Support structure of water-based photovoltaic device" of Korean Patent Publication No. 10-2014-0077258 and "Water-mounted photovoltaic installation" of Korean Patent Publication No. 10-2015-0006520 Power generation system "has been proposed and disclosed.

The "winning photovoltaic power generation system equipped with a variable support rope" of the Republic of Korea Patent Publication No. 10-1162473 is a water image made by installing a plurality of solar modules at equal intervals on a floating body to be floating on the surface with a predetermined size An apparatus has been proposed to maintain the support rope fixing the floating body in the solar power system at all times even when the water level is changed, and the variable rope-supported water-based solar power generation system of the Republic of Korea Patent Publication No. 10-1318791 Device "is a device that can stably support the floating body and photovoltaic power generation facilities in the water by adjusting the support rope according to the water level, but prevent the floating body from drifting by fixing the length of the supporting rope when the wind pressure above the standard occurs. Was proposed.

In addition, the "support structure of the water photovoltaic device" of the Republic of Korea Patent Publication No. 10-2014-0077258 allows the floating body to float in a state that is always stably fixed on the water surface and on the upper surface of the floating body By installing the rotor frame, it is possible to improve the power generation efficiency by maintaining the position and angle of receiving the solar light at all times, and the device has been proposed to reduce the load of the rotor frame by using the water flow. , "Water-mounted solar power generation system" of the Republic of Korea Patent Publication No. 10-2015-0006520 is to increase the strength of the bracket and buoyant material to prevent the phenomenon of floating damage caused by waves, and to install the water-mounted solar power generation system, It is possible to produce a large amount of power by connecting in parallel to form a large power generation system An apparatus has been proposed.

However, the prior art as described above has been proposed for the purpose of being installed in a calm river or lake compared to the sea, the wind speed and flow rate has a problem that does not have the durability to be installed in the sea where the generation occurs.

In addition, buoyancy structures (pontoons) are used for fishing, marine sports, and anchoring of ships. The buoyancy bodies are generally hollow and hollow, and buoyancy agents such as schiropol are inserted therein.

Hollow buoyancy bodies have the problem of losing buoyancy in case of breakage, and insertable floating structures threaten the life of fish with fine Schiropol pieces that disrupt the environment and ecosystem when damaged. There has been a problem.

In addition, as can be seen in the prior art and the types of products currently on sale, buoyancy bodies have a high production cost, small size to produce and difficult quality control due to the effect of sealing, watertightness, and quality of contents. There was a problem.

In addition, because the buoyant body is small in size, in order to obtain sufficient buoyancy, it is necessary to fix the structure by tying several pieces together, which requires more cost and at the same time, the more fixed structure halves the cost-effectiveness with more load. There was a problem to let.

This is an important issue for the project performance, in which the price and installation cost of the structure, like the floating solar power plant, is a big variable in the operation of the power plant.

Circular buoyancy body has a problem in fixing, it takes a lot of cost and time to connect and fix the rectangular structure also connected to each other, a lot of costs are incurred during transportation.

In order to solve this problem, a block method has been devised to reduce the transport cost while fixing a block that can be assembled in the field.

1. Republic of Korea Patent No. 10-0887723 (2009.03.02) 2. Republic of Korea Patent No. 10-1687590 (2016.12.13) 3. Republic of Korea Patent No. 10-1629872 (2016.06.07)

An object of the present invention is to minimize the physical buoyancy, increase or decrease the buoyancy by air pressure or fluid pressure, to facilitate installation of heavy materials such as fishing, water-based solar power plant or wind power plant performed in the water phase To provide a structure.

Another object of the present invention is to provide a water structure for installing a solar module having a small impact on the environment without being submerged in water, and can respond appropriately to environmental changes such as typhoons or strong winds.

Still another object of the present invention is to provide a solar module installation water structure that has a unit block form, which is easy to assemble and dismantle and easy to transport, thereby greatly increasing productivity and workability.

Another object of the present invention is to provide a solar structure for installing a solar module that does not have to bear additional site costs and civil engineering costs additionally configured to float the solar collection module on the water, such as reservoir, lake or sea have.

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In order to achieve the above object, a solar module installation water structure according to the present invention, the cross-shaped block is a coupling element disposed inside the water structure; A first intermediate block that can be coupled to a side of the cross block; A second intermediate block that can be coupled to the other side of the cross block; T-shaped block that can be installed on the outermost of the water structure; And an upper cover part installed at the top of the cross block, the first intermediate block, the second intermediate block, and the T-type block assembly.

The cross-shaped block is characterized in that cross-shaped horizontal guide rails are formed on the upper and lower surfaces thereof, respectively, and vertical guide rails are formed in the centers of the four side surfaces along the vertical direction.

The first intermediate block, the first intermediate block guide rail is formed on the upper surface and the lower surface, respectively, the vertical direction in the center of both sides of the first intermediate block abutting the end of the first intermediate block guide rail Therefore, each of the first intermediate block guide member is formed.

The second intermediate block has a straight second intermediate block guide rail formed on its upper and lower surfaces, respectively, and is perpendicular to both side centers of the second intermediate block which does not contact the end of the second intermediate block guide rail. Each of the second intermediate block guide members is formed along one direction.

The T-shaped block, the upper surface and the lower surface of the T-shaped horizontal guide rails are formed, respectively, characterized in that the three T-shaped vertical guide rails are formed along the vertical direction in the center of the three sides.

On the other side of the T-shaped vertical guide rail is not formed a plurality of connecting rings are characterized in that formed in the vertical direction spaced apart.

The upper cover portion is formed on the upper surface is a cradle for fixing the solar module is fixed, the lower portion is characterized in that the cover portion guide member is formed integrally.

It characterized in that it further comprises an I-type coupling bar that can be coupled to the cross-shaped block, the first intermediate block, the second intermediate block and the T-type blocks.

The upper cover portion has a hollow space therein,

One side of the upper cover portion is characterized in that the inlet and outlet to communicate with the space portion is installed in order to introduce a fluid, such as water or air.

One side of the upper surface of the upper cover portion is characterized in that it further comprises a pump for supplying and discharging fluid such as water or air in the space.

The water structure is characterized in that the fluid level sensor, the water level sensor, the tilt sensor, the acceleration sensor or the vibration sensor is installed.

According to the present invention, by assembling and using the buoyancy body for installing the water-based photovoltaic power station in the form of a block, it is easy to assemble and dismantle, easy to transport, there is an effect that can greatly increase productivity and workability. .

In addition, according to the present invention, if damaged without being submerged in water, the impact on the environment is less, there is an effect that can respond appropriately to environmental changes, such as typhoons or strong winds.

In addition, according to the present invention, by stacking the unit blocks can be stacked to save space in the storage and there is an effect of minimizing the moving means when moving.

In addition, according to the present invention, according to the present invention, the water structure to which the air pressure regulating lifting method is applied has an effect of effectively operating a heavy object such as a solar power plant or a wind power plant installed in the water.

In addition, according to the present invention, it is possible to reduce the enormous site cost and civil engineering cost according to the large-scale solar module construction, and to obtain environmentally friendly energy from sunlight without using environmental pollution by using the surface of the reservoir, lake or sea There is a characteristic. In addition, by concentrating and using solar energy, it is possible to reduce the burden on the consumer by minimizing the consumption of solar cells whose prices are soaring, and in terms of application, there is an effect of overcoming the spatial constraints of lack of installation place.

In addition, the construction and construction is very economical due to the light weight and simplicity of the facility, and it becomes an infinite array expansion according to site conditions, and it is easy to follow-up management and maintenance during operation.

1 is an exploded perspective view of a water structure for installing a solar module according to the present invention.
2 is a perspective view of the combination of FIG.
3 is an exploded view showing unit blocks of the solar module installation water structure according to the present invention in detail.
4 is a coupling diagram of FIG. 3.
5 is a perspective view showing a state in which the water structure for solar module installation according to the present invention is coupled.
Figure 6 is a perspective view showing a state in which a solar module is installed on the water structure for solar module installation according to the present invention.
7 is a cross-sectional view of FIG. 6.
FIG. 8 is an enlarged view of a portion of FIG. 7 in an enlarged manner.
9 is a view showing an example in which the solar module is installed on the water structure according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the water structure for installing a solar module according to the present invention.

As unit blocks for coupling the unit blocks described in the present invention, the structure is formed while being connected to each other in the coupling form of the guide member and the guide rail. Therefore, the water phase structure in the present invention is produced by the combination of these unit blocks, the installation height and width is that it can be variously modified and changed.

As shown in Figures 1 to 3, the water structure for installing the solar module according to the present invention is large, cross-shaped block 40, the first intermediate block 30 that can be coupled to the side of the cross-shaped block (40) , The second intermediate block 20 which may be coupled to the other side of the cross block 40, the T-shaped block 60 which may be installed at the outermost portion of the water structure, and the cross block, the first intermediate block, It includes a top cover portion 10 which is installed on the top of the second intermediate block and T-shaped block combination.

In addition, the cross-shaped block 40, the first intermediate block 30, the second intermediate block 20 and the T-type block 60, after selectively coupling as needed, if necessary, the first coupling bars for secondary coupling (50) can also be used.

The I-type coupling bar 50 functions as a guide member for coupling the respective blocks, and has a structure that can be inserted into and coupled to each guide rail to be described below.

The cross block 40 is a unit block of a rectangular parallelepiped which is disposed inside the water structure and can be combined with any of the above-mentioned blocks, and a cross-shaped horizontal guide rail 41 is formed on each of the upper and lower surfaces thereof. In the centers of the four side surfaces, vertical guide rails 43 are formed in the vertical directions, respectively.

The first intermediate block 30 is a unit block of a rectangular parallelepiped, and the first intermediate block guide rails 33 are formed on upper and lower surfaces thereof, respectively, and end portions of the first intermediate block guide rails 33 are formed. First intermediate block guide members 35 are formed at both centers of both side surfaces of the first intermediate block 30 which are in contact with each other.

For example, the first intermediate block 30 is a rectangular parallelepiped having a shape of one side longer than the length of the other side, the first intermediate block guide member 35 is formed at the side of the side of the short side length The first intermediate block guide rail 33 is preferably formed on the upper and lower surfaces of the first intermediate block 30 in parallel with the long side.

The second intermediate block 20 is a unit block of a rectangular parallelepiped, and a straight second intermediate block guide rail 23 is formed on the upper and lower surfaces thereof, respectively, and an end of the second intermediate block guide rail 33 is formed. Second middle block guide members 25 are formed in the centers of both sides of the second middle block 20 which are not in contact with each other in the vertical direction.

For example, the second intermediate block 20 is a rectangular parallelepiped having a shape of one side longer than the length of the other side, the second intermediate block guide member 25 is formed at the side center of the side of the shorter side length The second intermediate block guide rails 23 are preferably formed on the upper and lower surfaces of the second intermediate block 20 in parallel with shorter sides.

In addition, the T-shaped block 60 is a unit block of a rectangular parallelepiped, and T-shaped horizontal guide rails 61 are formed on the upper and lower surfaces thereof, respectively, and the T-shaped blocks 60 are respectively formed along the vertical direction at the centers of the three sides. The mold vertical guide rail 63 is formed. In addition, a plurality of connection rings 67 are formed on the other side of the T-shaped vertical guide rail, which are spaced apart along the vertical direction.

The connecting rings 67 may be used to insert a long rod to reinforce the bonding force when the unit blocks are combined to complete the water structure, or may be used to connect a coupling string or a rope. In addition, by inserting the steel structure to the connecting ring 67 and the steel structure can be integrally integrated by welding or welding to fix the steel structure may be firmly coupled.

Each of the guide rail and each of the guide members has a corresponding shape for coupling to each other. In the state where each of the guide members is inserted into the guide rails, the guide rails and the guide members do not escape to the outside except the direction of travel of the rails. It is preferable to have.

6 to 8, the upper cover part 10 is integrally formed with a cover part guide member 15 at a lower portion thereof, and is inserted into the respective guide rails and inserted into the respective guide rails. It can be combined.

On the upper surface of the upper cover portion 10, a cradle 19 for fixing the solar module 100 is formed separately, the interior of the upper cover portion 10 is an empty space 18 Is formed.

The cradle 19 may be configured in various ways to correspond to the installation structure of the solar module 100.

One side of the upper surface of the upper cover portion 10 is provided with a pump 70 for supplying and discharging fluid such as water or air to the space portion 18.

In addition, an inlet 71 and an outlet 73 for introducing a fluid such as water or air are provided at one side of the upper cover part 10. The inlet 71 and the outlet 73 are in communication with the space 18, it is connected to the pump 70.

In addition, a predetermined position of the upper cover portion 10 may be provided with a variety of sensors that can detect the water level of the water structure or to detect whether the safety abnormality. The various sensors may be a fluid volume sensor, a level sensor, a tilt sensor, an acceleration sensor, or vibration sensors.

For example, when the level detected by the water level sensor is low, the pump 70 is operated to introduce fluid into the space 18 through the inlet 71, and when the detected level is high, the space The fluid can be removed from the portion 18.

In addition, by adjusting the filling amount of the fluid, such as water or air filled in the upper cover portion 10, it is possible to adjust the height of the entire water structure. In addition, if necessary, by adjusting the fluid filling amount of each of the plurality of upper cover portion 10 by adjusting the height of each of the upper cover portion, it is also possible to adjust the inclination of the entire water structure.

The material of the unit block is preferably a non-metal or metal such as plastic that can maintain the watertight.

4 and 5 will be described in detail with respect to the assembling method of the block combination type water structure according to the present invention.

1. Combination of the cross block 40 and the first intermediate block 30

The first intermediate block guide member 35 is inserted into the vertical guide rail 43 of the cross block 40 to connect the cross block 40 and the first middle block 30. Subsequently, the cross-shaped block 40 is inserted into the first middle block 30 by inserting the vertical guide rail 43 of the cross block 40 into the first middle block guide member 35 of the first middle block 30. Connect. The cross block 40 and the first intermediate block 30 may be properly connected according to the size of the water phase structure.

2. The combination of the cross block 40 and the second intermediate block 20

In the state in which the cross block 40 and the first intermediate block 30 are coupled, the second structure may be expanded to the side using the second intermediate block 20.

That is, the second middle block guide member 25 is inserted into the vertical guide rail 43 of the cross block 40 to connect the cross block 40 and the second middle block 20. Subsequently, the cross-shaped block 40 is inserted into the second intermediate block 20 by inserting the vertical guide rail 43 of the cross block 40 into the second middle block guide member 25 of the second middle block 20. Connect. The cross block 40 and the second intermediate block 20 may be properly connected according to the size of the water phase structure.

3. Combination of T-shaped block 60 and the first intermediate block 30 or the second intermediate block 20

The T-shaped block 60 forms the outermost part of the water phase structure, and may be used in combination with the first intermediate block 30 or the second intermediate block 20 that is finally installed.

That is, when the T-shaped block 60 is coupled to the first intermediate block 30, the first intermediate block (T) is formed on the T-shaped vertical guide rail 63 formed on one side of the T-shaped block 60. By inserting the first intermediate block guide member 35 of 30, it can be coupled.

In addition, when the T-shaped block 60 is coupled to the second intermediate block 20, the second intermediate block (T) in the T-shaped vertical guide rail 63 formed on one side of the T-shaped block 60 By inserting the second middle block guide member 25 of 20), it can be coupled.

4. Coupling of the upper cover part 10

By inserting the cover part guide member 15 formed at the bottom of the upper cover part 10 into the horizontal guide rails, a complete water structure covering the upper cover part 10 can be completed.

Thus, a plurality of cross-shaped block 40, the first intermediate block 30, the second intermediate block 20 and the T-shaped block 60 is combined to form a water structure, each horizontal guide to reinforce the coupling force The I-type coupling bar 50 can be inserted into the rail.

After combining the unit blocks in this way to complete the water structure, as shown in Figures 6 to 8, the solar module can be installed on the holder 19 of the upper cover portion 10.

In this state, by detecting the flow of the water, the state, the wind, vibration, collision, and the like from the various sensors installed in the water structure in the control unit, by adjusting the amount of fluid in the upper cover portion 10, You can control the height or the slope.

For example, when the water level detected by the water level sensor is low, the pump 70 is operated to introduce the fluid into the space 18 through the inlet 71, and when the detected water level is high, the space portion It is possible to remove the fluid from (18).

As described above, the preferred embodiments of the present invention have been described, and the fact that the present invention can be embodied in other specific forms in addition to the above-described embodiments without departing from the spirit or scope thereof has ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

10: upper cover part 15: cover part guide member
20: second intermediate block 23: second intermediate block guide rail
25: second intermediate block guide member 30: first intermediate block
33: first intermediate block guide rail 35: first intermediate block guide member
40: cross block 41: horizontal guide rail
43: vertical guide rail 50: I-type coupling bar
60: T block 61: T horizontal guide rail
63: T vertical guide rail 67: Hook

Claims (11)

In the water structure for solar module installation,
As a coupling element disposed inside the water phase structure, a cross block that is a unit block of a rectangular parallelepiped;
A first intermediate block that can be coupled to a side of the cross block;
A second intermediate block that can be coupled to the other side of the cross block;
T-shaped block that can be installed on the outermost of the water structure; And
And an upper cover part installed at the top of the cross block, the first intermediate block, the second intermediate block, and the T-shaped block assembly.
The cross-shaped block has cross-shaped horizontal guide rails formed on the upper and lower surfaces thereof, respectively, and vertical guide rails are formed in the centers of the four sides of the cross-shaped blocks, respectively.
The first intermediate block has a straight first intermediate block guide rail is formed on the upper surface and the lower surface, respectively,
The second intermediate block has a straight second intermediate block guide rail is formed on the upper surface and the lower surface, respectively,
The T-shaped block is a water structure for installing a solar module, characterized in that the T-shaped horizontal guide rail is formed on the upper and lower surfaces, respectively. delete The method of claim 1,
The first intermediate block,
The first intermediate block guide member of claim 1, characterized in that the first intermediate block guide member is formed in the vertical direction in the center of both sides of the first intermediate block in contact with the end of the first intermediate block guide rail. The method of claim 1,
The second intermediate block,
The second intermediate block guide member of claim 2, characterized in that the second intermediate block guide member is formed along the vertical direction in the center of both sides of the second intermediate block that does not contact the end of the second intermediate block guide rail. The method of claim 1,
The T-shaped block,
The three sides of the center of the solar module installation, characterized in that the T-shaped vertical guide rail is formed in the vertical direction, respectively. The method of claim 5,
On the other side of the T-shaped vertical guide rail is not formed a plurality of connection rings are formed in the water module for solar module installation, characterized in that formed in the vertical direction. The method according to any one of claims 1 and 3 to 6,
The upper cover portion is formed on the upper surface of the cradle for fixing the solar module is formed, the lower surface portion for installing the solar module, characterized in that the cover portion guide member is formed integrally. The method according to any one of claims 1 and 3 to 6,
A water module for installing a solar module, characterized in that it further comprises an I-type coupling bar that can be coupled to the cross block, the first intermediate block, the second intermediate block and the T-type blocks. The method according to any one of claims 1 and 3 to 6,
The upper cover portion has a hollow space therein,
On one side of the upper cover portion, inlet and outlet communicating with the space portion for introducing a fluid, such as water or air, solar module installation water structure characterized in that the installation.
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