KR20220107507A - Structure for floating photovoltaics system - Google Patents

Abstract

A floating photovoltaic power generation structure, according to the present invention, comprises: a support frame part supporting a solar panel; and a bottom frame part in which the support frame part is installed on an upper portion, a floating body is installed on a lower portion, and the lower portion has an open frame structure, wherein the support frame part and the bottom frame part are made of a material in which aluminum is plated on structural carbon steel or a material in which aluminum is plated on seawater-resistant steel. Specifically, the floating photovoltaic power generation structure, according to the present invention, is capable of preventing corrosion by preventing saltwater from pooling inside by having a structure in which a first bottom frame and a second bottom frame individually have an open lower portion, furthermore, compared to a lateral load weakness of a conventionally used C channel, it is possible to increase stiffness against a bending moment caused by a lateral load, in addition, as the support frame part and the bottom frame part are made of the material in which aluminum is plated on the structural carbon steel or the material in which aluminum is plated on the seawater-resistant steel, corrosion resistance is enhanced, thereby producing an effect of preventing corrosion caused by the salt water as much as possible. The purpose of the present invention is to provide a photovoltaic power generation structure capable of preventing corrosion and having superior durability on the surface of the water.

Description

Floating photovoltaic power generation structure {STRUCTURE FOR FLOATING PHOTOVOLTAICS SYSTEM}

The present invention relates to a floating photovoltaic structure installed in an aquatic environment containing salt as a floating photovoltaic structure.

A general solar battery or solar module (hereinafter, referred to as a solar module) refers to a photovoltaic cell that converts energy irradiated from the sun into electrical energy.

These solar modules are installed in structures such as electric clocks, radios, unmanned lighthouses, unmanned repeaters, buoy lights, artificial satellites, and rockets, as well as houses for solar heating, fog warning lights that alert drivers on roads, and power transmission towers. It is used in various fields such as aviation obstacle lights, street lights, etc.

The solar module may be manufactured as a solar panel by connecting as many solar cells in series and/or in parallel as necessary, It can be used in various fields.

Solar modules have the disadvantage of being able to use directly generated power during the daytime when sunlight can be received, and not being able to generate power at night when sunlight cannot be received. Since no harmful substances such as environmental pollution are generated when electricity is generated, it is one of the eco-friendly power generation methods.

In the photovoltaic device using such a solar cell, it is preferable that the solar panels connected in series and/or in parallel as needed are installed to have a predetermined angle (eg, about 12 degrees) toward the south. This is because the efficiency of converting solar energy into electrical energy can be improved when the solar panel is at right angles to the incident angle of sunlight when the panel is fixed.

In order to mass-produce electricity by photovoltaic power generation, it is necessary to have a large space where solar panels can be installed in large quantities.

However, since it is difficult to find a large place on land and the purchase unit price is high, it is difficult to provide a suitable place for solar power generation.

In order to solve these difficulties, recently, solar panels have been installed cheaply and on a wide surface.

In general, the water photovoltaic device is composed of a buoyancy body floating on water, a frame structure coupled to the buoyancy body, a solar panel installed on the frame structure, and the like.

However, there is a problem in that the frame structure is easily corroded in a salty water environment because it is installed on the water, and the frame structure is damaged or lost due to shaking due to waves.

Republic of Korea Patent Publication No. 10-1892970

The present invention has been devised to solve the above problems, and an object of the present invention is to prevent corrosion and provide a water-based photovoltaic structure having excellent durability at the water surface.

In order to achieve the above object, the floating photovoltaic structure according to the present invention includes: a support frame part for supporting a solar panel; and a bottom frame part having a frame structure in which the support frame part is installed on the upper part, the floating body is installed on the lower part, and the lower part is open. Alternatively, it is made of a material plated with aluminum on the sea-resistant steel.

Here, the bottom frame portion is disposed in the front-rear direction and a plurality of first floor frames are spaced apart from each other; and a plurality of the second floor frames arranged in a lateral direction to connect a plurality of the first floor frames and a plurality of the second floor frames spaced apart from each other, wherein each of the first floor frame and the second floor frame does not contain water therein. As much as possible, it may have an omega (Ω) shape or an inverted U-shape to have an open bottom structure.

In addition, the present invention may further include a bracing for diagonally connecting the two adjacent first floor frames.

And, the present invention further includes; a connection unit configured to connect a plurality of unit structures including the support frame part and the bottom frame part, wherein the connection unit includes a first bottom frame of the unit structure on one side and the other side of the unit structure. a connecting member made of a polymer material for connecting the first floor frame of the other unit structure or connecting the second floor frame of the unit structure on one side and the second floor frame of the unit structure on the other side; and a safety configuration disposed on both sides of the connecting member to connect the first floor frame of the unit structure on one side and the first floor frame of the other unit structure on the other side, or with the second floor frame of the unit structure on one side A chain or wire rope connecting the second bottom frame of the unit structure on the other side; may be provided.

Furthermore, as an embodiment, the present invention may further include a mooring connection part connected to a mooring device extending into the water and installed at the lower center of the bottom frame part.

Specifically, the mooring connection portion may include a support bracket disposed at a lower center of the floor frame portion; two first connecting bars extending upward from the support bracket and connected to the first bottom frame; and two second connecting bars extending upwardly from the support bracket and connected to the second bottom frame to have a truss structure.

And, as another embodiment of the present invention, it is connected to a mooring device extending into the water, the upper part is installed in the lower part of the first floor frame located in the middle among the plurality of first floor frames, and the lower part is the front surface of the floating body It may further include a mooring connection unit installed on the.

The floating photovoltaic structure according to the present invention has an open structure in which the lower portions of each of the first floor frame and the second floor frame are opened, so that salt water does not accumulate therein at all to prevent corrosion, and furthermore, conventionally used Compared to the lateral load weakness of the C-channel, it has the effect of increasing the rigidity to resist the bending moment caused by the lateral load.

In addition, the present invention has the advantage of being able to provide a reinforcing force against a lateral load by forming a bracing that diagonally connects two adjacent first floor frames.

In addition, the present invention has an advantage in that the connecting member connecting the unit structures is made of a polymer material that is a flexible material, and thus can serve as a buffer for 6-DOF motion caused by an external force such as wave power or wind power.

At this time, the present invention connects the unit structures with a chain or wire rope in addition to the connecting member, so that when an accident such as breakage or separation occurs due to damage or breakage of the connecting member, the two first floor frames or the second floor frames are connected has the advantage of being able to keep

Furthermore, in the present invention, a mooring connection part having a truss structure is configured while being installed in the lower center of the bottom frame part, or a mooring connection part connecting the first floor frame and the floating body is configured, thereby reducing the bending stress received when a tensile force is applied to the mooring device. By uniformly dispersing in a plurality of members rather than being concentrated at the end of any one member, durability can be improved.

On the other hand, in the present invention, the support frame part and the bottom frame part are made of a material plated with aluminum on structural carbon steel or a material plated with aluminum on seawater resistant steel, thereby improving corrosion resistance and maximally preventing corrosion by salt water. have

1 is a view showing a floating photovoltaic structure according to the present invention.
Figure 2 is a view showing a unit structure in the floating photovoltaic structure of Figure 1.
FIG. 3 is a view showing that solar panels on the front side are removed from the unit structure of FIG. 2 .
FIG. 4 is a view showing that the solar panel is supported on the support frame part in the unit structure of FIG. 3 .
5 is an enlarged view showing A of FIG. 3 .
6 is an enlarged view showing B of FIG. 3 .
FIG. 7 is a view showing a portion connected to each other in the floating photovoltaic structure of FIG. 1 .
FIG. 8 is a view showing C of FIG. 7 .
9 is a view showing a mooring connection part according to an embodiment of the unit structure of FIG.
10 is a view showing a mooring connection part according to another embodiment of the unit structure of FIG.

Hereinafter, preferred embodiments will be described in detail so that those of ordinary skill in the art can easily practice the present invention with reference to the accompanying drawings. However, in describing a preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions. In addition, in this specification, terms such as 'top', 'top', 'top', 'bottom', 'bottom', 'bottom', 'side', etc. are based on the drawings, and in fact, elements or components may vary depending on the direction in which the is placed.

In addition, throughout the specification, when a part is 'connected' with another part, it is not only 'directly connected' but also 'indirectly connected' with another element interposed therebetween. include In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

1 is a view showing a floating photovoltaic structure according to the present invention, Figure 2 is a view showing a unit structure in the floating photovoltaic structure of FIG.

In addition, FIG. 3 is a view showing that the solar panels on the front side are removed from the unit structure of FIG. 2, FIG. 4 is a view showing that the solar panel is supported on the support frame part in the unit structure of FIG. 3, FIG. It is an enlarged view showing A of 3 .

Referring to the drawings, the floating photovoltaic structure according to the present invention is floating on water by a floating body (F) installed at the lower portion, and is a structure configured to support the solar panel (S) on the upper portion.

This floating photovoltaic structure includes a support frame part 100 and a bottom frame part 200 .

The support frame part 100 supports the solar panel S, and may include a vertical frame 120 and a rear support frame 130 .

At this time, the front side of the solar panel (S) is seated and fixed to the second floor frame 220 to be described later in the floor frame portion 200 is supported.

In addition, the vertical frame 120 is disposed in the longitudinal direction from the rear side opposite to the second bottom frame 220 is installed and fixed to the bottom frame portion 200, and a plurality of them are arranged to be spaced apart from each other in the lateral direction.

The rear support frame 130 is installed and fixed to the upper end of the plurality of vertical frames 120 so as to connect the plurality of vertical frames 120 , and disposed on the rear side opposite to the second bottom frame 220 , the second bottom frame (220) is placed higher.

As the rear support frame 130 configured as described above is positioned higher than the second floor frame 220 , the solar panel S is seated on the second floor frame 220 and the rear support frame 130 to be installed and fixed The structure is tilted to the south side of the city.

In addition, a work pedestal 900 is installed on the floor frame 200 so that the operator can work while stepping on it.

This work pedestal 900 is made of a pedestal frame 910 and a grating 920 (grating).

The pedestal frame 910 is arranged in the lateral direction and the two pedestal frames 910 are arranged to be spaced apart from each other, and the grating 920 is fastened to the upper portions of the two pedestal frames 910 to connect the two pedestal frames 910 .

6 is an enlarged view showing B of FIG. 3 .

Referring to the drawings, the bottom frame part 200 has a frame structure in which the support frame part 100 is installed in the upper part, the floating body F is installed in the lower part, and the lower part is open.

Specifically, the bottom frame part 200 may include a first bottom frame 210 and a second bottom frame 220 .

The first bottom frame 210 is arranged in the front-rear direction and takes a structure in which a plurality of them are spaced apart from each other.

In addition, the second floor frame 220 is arranged in the lateral direction to connect the plurality of first floor frames 210, a plurality of the structure takes a spaced apart from each other.

At this time, each of the first bottom frame 210 and the second bottom frame 220 has an omega (Ω) shape or an inverted U shape so that water is not accommodated therein as shown in FIG. 6 to form a lower open structure. have

The conventional floor frame has a rectangular closed structure in its longitudinal section. This floor frame is a structure that can pool in the inner space of the floor frame when salt water enters the floor frame due to waves or wind. Accordingly, there is a problem that an environment prone to corrosion is created and corrosion is promoted due to the salt contained in the salt water, and furthermore, when water evaporates from the salt water, the salinity increases, thereby increasing the risk of local corrosion.

In addition, since the conventional floor frame has a structure in which salt water can accumulate in the internal space even when the bottom has a closed structure as well as a rectangular closed structure in longitudinal section, there is a problem as described above.

In addition, the structural stability of the bolts are released when the square steel pipes are fitted (inserted connection) and fastened with bolts. There is a problem in that the bolts are loosened due to the gap between the sides and the bolts.

On the other hand, even in the case of using the C channel as the conventional floor frame, salt water may come out to one side again, but as compared to the lower open structure as in the present invention, it is relatively easy to cause corrosion as the salt water is not easily drained out. It is an environment and furthermore, there is a problem that it is vulnerable to lateral load due to wave force due to the structural characteristics of the C channel.

In order to solve the above-described water retention problem, bolt fastening problem, and weak lateral load problem, the present invention provides both the first bottom frame 210 and the second bottom frame 220, in an omega (Ω) shape or It has an inverted U-shape and has an open bottom structure.

That is, in the present invention, since the lower portions of each of the first and second floor frames 210 and 220 are opened, salt water does not accumulate therein, thereby preventing corrosion, and furthermore, conventionally used. Compared with the lateral load weakness of the C-channel, it is possible to increase the rigidity to resist the bending moment caused by the lateral load.

Meanwhile, the present invention may further include a bracing 300 as shown in FIG. 3 .

The bracing 300 has a structure in which two adjacent first floor frames 210 are diagonally connected.

That is, the bracing 300 is also referred to as a brace, and receives a force against a horizontal load by obliquely connecting the existing members.

In other words, in order to support the lateral load acting on the first floor frame 210 disposed in the front-rear direction in the floor frame part 200 , the structure in which the two first floor frames 210 are connected diagonally is taken.

Of course, in order to increase the bearing capacity of the first floor frame 210 against the lateral load, the size can be increased to the maximum limit, but there is a limit to this in terms of structural and cost aspects, so the bracing 300 is attached to the two first By installing it between the floor plies, it is possible to provide reinforcement for lateral loads.

FIG. 7 is a view showing a part connected to each other in the floating photovoltaic structure of FIG. 1 , and FIG. 8 is a view showing C of FIG. 7 .

Referring to the drawings, the present invention may further include a connection unit 400 .

2 is a unit structure (U), which is the most basic unit including the support frame part 100 and the bottom frame part 200 in the floating photovoltaic power generation structure according to the present invention, FIG. 1 is a plurality of units The structure (U) is shown in the front-back direction, the water photovoltaic structure connected in the lateral direction.

The connection unit 400 is configured to connect a plurality of such unit structures (U).

That is, the connection unit 400 connects the two unit structures (U) in the front-rear direction, or connects the two unit structures (U) in the lateral direction.

Specifically, the connection unit 400 includes a connection member 410 , wherein the connection member 410 is a first bottom frame 210 of a unit structure U on one side and a first of the other unit structure U on the other side. The bottom frame 210 is connected or, as shown in FIG. 8 , the second floor frame 220 of one unit structure U and the second floor frame 220 of the other unit structure U are connected.

In this case, the connecting member 410 may be made of a polymer material.

In this way, the connecting member 410 is made of a polymer material, which is a flexible material, rather than a solid material like a hinge structure when the unit structures U are connected to each other, so that the 6-DOF motion caused by external forces such as wave power or wind power is buffered. can play a role.

For reference, the connecting member 410 can directly connect the two first floor frames 210 or the two second floor frames 220, and as shown in the drawing, the connecting bracket 490 is used as a medium. can also be connected.

In addition, the connection unit 400 may further include a chain 420 or a wire rope.

The chain 420 or wire rope is disposed on both sides of the connecting member 410, the first bottom frame 210 of the unit structure (U) on one side and the first bottom frame 210 of the other unit structure (U) on the other side. or connect the second floor frame 220 of the unit structure U on one side and the second floor frame 220 of the unit structure U on the other side.

Such a chain 420 or wire rope is a safety configuration additionally disposed on both sides of the above-described connection member 410, and when an accident such as breakage or separation occurs due to damage or breakage of the connection member 410, two It has a function of continuously maintaining the connection of the first floor frame 210 or the second floor frame 220 .

9 is a view showing a mooring connection part according to an embodiment of the unit structure of FIG.

Referring to the drawings, the present invention may further include a mooring connection unit 500 .

The mooring connection part 500 is configured to be connected to a mooring device extending underwater, and is installed in the lower center of the bottom frame part 200 .

Specifically, the mooring connection part 500 may include a support bracket 510 , two first connection bars 520 , and two second connection bars 530 .

The support bracket 510 is disposed below the center of the bottom frame portion 200 .

In addition, the two first connecting bars 520 extend upward from the support bracket 510 and are connected to the first bottom frame 210 .

In addition, the two second connecting bars 530 extend upward from the support bracket 510 and are connected to the second bottom frame 220 .

As described above, the mooring connection part 500 including the support bracket 510 , the two first connection bars 520 , and the two second connection bars 530 has a truss structure.

In the prior art, if the mooring connection part is installed at the portion corresponding to the vertex of the unit structure, that is, at one end of the first floor frame or the second floor frame, when a tensile force is applied to the mooring device by an external force, the first floor frame in which the mooring connection part is installed or There is a problem in that only the second bottom frame is intensively subjected to bending stress.

In order to overcome this problem, the present invention, as described above, the mooring connection part 500 is disposed in the lower center of the bottom frame part 200 and has a truss structure, so that bending stress is applied to the second floor frame part 200 . By uniformly distributing the first floor frame 210 and the second floor frame 220, it is possible to prevent damage due to the tensile force applied to the mooring device.

10 is a view showing a mooring connection part according to another embodiment of the unit structure of FIG.

In the present invention, the mooring connection part 500 of another embodiment shown in FIG. 10 may be configured instead of the mooring connection part 500 shown in FIG. 9 .

The mooring connection unit 500 according to another embodiment is connected to a mooring device extending underwater, and the upper portion of the mooring connection unit 500 is a first floor frame 210 located in the middle among the plurality of first floor frames 210 . The lower part of the mooring connection part 500 is installed in the front of the floating body (F).

Unlike the structure in which the mooring connection part is installed at one end of the first floor frame or the second floor frame as in the prior art, the mooring connection part 500 of the present invention is disposed in the middle line portion of the unit structure, and the first floor frame 210 . By adopting an installation structure connecting the floating body F and the first floor frame 210 and the floating body F, the bending stress is distributed to the first floor frame 210 and the floating body F, thereby improving the durability of the present invention.

Meanwhile, in the present invention, the support frame part 100 and the bottom frame part 200 may be made of a material in which aluminum is plated on structural carbon steel, or a material in which aluminum is plated on sea-resistant steel.

Specifically, the support frame part 100 and the bottom frame part 200 may be made of a material in which aluminum is plated on structural carbon steel, and the rigidity can be improved by the structural carbon steel as compared to the case where the entirety is made of an aluminum material, It can also have corrosion resistance due to aluminum plating.

Furthermore, as another preferred embodiment, the support frame part 100 and the bottom frame part 200 may be made of a material plated with aluminum for sea-resistant steel. Corrosion can be prevented as much as possible by seawater-resistant steel made of excellent corrosion-resistant material.

As a result, in the present invention, since the lower portions of each of the first and second floor frames 210 and 220 are open, salt water does not accumulate therein at all, thereby preventing corrosion, and furthermore, in the prior art Compared to the lateral load weakness of channel C, it is possible to increase the rigidity to resist the bending moment caused by the lateral load.

In addition, according to the present invention, the bracing 300 connecting the two adjacent first floor frames 210 diagonally is configured, thereby providing a reinforcing force against a lateral load.

In addition, in the present invention, since the connecting member 410 connecting the unit structures U is made of a flexible polymer material, it is possible to perform a buffering role for 6-DOF motion caused by an external force such as wave power or wind power.

At this time, in the present invention, in addition to the connecting member 410, by connecting the unit structures with the chain 420 or wire rope, when an accident such as breakage or separation occurs due to damage or breakage of the connecting member 410, the two first The connection of the bottom frame 210 or the second bottom frame 220 may be continuously maintained.

Furthermore, according to the present invention, the mooring connection part 500 is configured with a truss structure while being installed in the lower center of the bottom frame part 200, or the mooring connection part 500 connects the first floor frame 210 and the floating body F. ), the durability can be improved by uniformly distributing the bending stress received when the tensile force is applied to the mooring device to a plurality of members rather than being concentrated on the end of any one member.

On the other hand, in the present invention, the support frame part 100 and the bottom frame part 200 are made of a material plated with aluminum on structural carbon steel or a material plated with aluminum on seawater resistant steel, thereby improving corrosion resistance and corrosion by salt water. can be prevented as much as possible.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will realize that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. You will understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

F : Floating body S : Solar panel
100: support frame part 120: vertical frame
130: rear support frame
200: floor frame part 210: first floor frame
220: second floor frame 300: bracing
400: connection unit 410: connection member
420: chain 490: connection bracket
500: mooring connection part 510: support bracket
520: first connecting bar 530: second connecting bar
900: work pedestal 910: pedestal frame
920: grating U: unit structure

Claims (7)

a support frame part for supporting the solar panel; and
The support frame part is installed on the upper part, the floating body is installed on the lower part, and the bottom frame part has a frame structure in which the lower part is open; includes;
The support frame part and the bottom frame part, water photovoltaic structure, characterized in that made of a material plated with aluminum on structural carbon steel, or a material plated with aluminum on sea-resistant steel.
According to claim 1,
The bottom frame part,
a first floor frame disposed in the front-rear direction and spaced apart from each other in plurality; and
It is disposed in the lateral direction to connect a plurality of the first floor frame, and a plurality of the second floor frames spaced apart from each other;
Each of the first floor frame and the second floor frame is made of an omega (Ω) shape or an inverted U-shape so that water is not accommodated therein, and a floating photovoltaic structure, characterized in that it has a lower open structure.
3. The method of claim 2,
Bracing for diagonally connecting the two adjacent first floor frames;
Floating photovoltaic structure, characterized in that it further comprises.
3. The method of claim 2,
It further includes; a connection unit configured to connect a plurality of unit structures including the support frame part and the bottom frame part;
The connection unit is
Connecting the first floor frame of the unit structure on one side and the first floor frame of the other unit structure on the other side, or connecting the second floor frame of the unit structure on one side and the second floor frame of the unit structure on the other side, , a connecting member made of a polymer material; and
It is disposed on both sides of the connecting member as a safety configuration to connect the first floor frame of the unit structure on one side and the first floor frame of the other unit structure on the other side, or the second floor frame and the other side of the unit structure on one side a chain or wire rope connecting the second bottom frame of the unit structure;
Floating photovoltaic structure comprising a.
3. The method of claim 2,
a mooring connection part connected to a mooring device extending into the water and installed in the lower center of the bottom frame part;
Floating photovoltaic structure, characterized in that it further comprises.
6. The method of claim 5,
The mooring connection part,
a support bracket disposed below the center of the bottom frame part;
two first connecting bars extending upward from the support bracket and connected to the first bottom frame; and
two second connecting bars extending upward from the support bracket and connected to the second bottom frame;
Floating photovoltaic structure, characterized in that it is provided with a truss structure.
3. The method of claim 2,
a mooring connection part connected to a mooring device extending into the water, the upper part being installed under the first floor frame located in the middle among the plurality of first floor frames, and the lower part being installed in the front of the floating body;
Floating photovoltaic structure, characterized in that it further comprises.

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