KR102349219B1 - Floating structure for solar power device - Google Patents

Abstract

The present invention provides a floating structure for a photovoltaic device, in which one or more module support pontoons are connected to each other and are extended to a predetermined length, and a plurality of module support pontoons extended to a predetermined length are spaced apart from each other by a predetermined distance, to be installed to form one or more rows in an antero-posterior direction. The module support pontoon not only performs the role of a buoyant body while fixing a solar module, but also allows the fixing between the module support pontoons to be realized only with the installation of horizontal and vertical fixing members. Therefore, the configuration is simple, so the cost and effort required to install the device can be reduced.

Description

Floating structure for solar power device

The present invention relates to a floating structure installed in a floating solar power system, wherein one or more module support pontoons are connected to each other and extend to a certain length; The plurality of module support pontoons extended by a certain length are spaced apart at a certain interval to form one or more rows in the front and rear directions, and the configuration is simplified compared to the existing floating structure of solar power generation, so the cost of installation on water And it relates to a floating structure for a photovoltaic device that can save effort.

Solar energy is a representative renewable energy, and in the case of solar power generation using solar cells, it has characteristics suitable for both large-capacity and small-capacity power generation, and has the advantage of easy installation and maintenance, so it is being applied to various fields. In solar power generation, the amount of power generation is proportional to the installed area of power generation facilities under the same sunlight conditions, so securing a site for power generation facilities is of great importance.

In the case of land solar power generation, the number of cases of floating solar power generation is increasing because the construction cost increases due to the difficulty of securing a flat land with easy access to sunlight and the cost of land compensation.

Floating photovoltaic power generation, which is currently in the commercialization stage, is a power plant that installs solar power on the water surface. It is a new concept fusion and complex technology that combines water and energy. to be.

In general, the elements constituting a floating photovoltaic system are largely a photovoltaic module, a water structure for floating the photovoltaic module on the water surface, a mooring device that fixes the direction so as not to change due to the flow of wind or fluid, and a photovoltaic module array. It consists of a connection panel for processing the DC voltage and current produced, and an inverter and switchboard for converting the produced power into AC and boosting it to connect to the grid.

The floating solar power system has the following advantages. First, the land can be used efficiently. Second, in order to develop conventional photovoltaic power generation, the use of farmland or forestry inevitably causes environmental destruction, but the floating photovoltaic power generation system using the water surface does not destroy the environment. Third, it is possible to increase the power generation efficiency by improving the temperature characteristics of the photovoltaic cell whose power generation output decreases when the cell temperature rises due to the lower ambient temperature compared to the land.

Domestic Patent Publication No. 10-2020-0083133 discloses a light directing system using a floating pontoon solar power generation facility, and Domestic Patent No. 10-1160798 discloses a buffer-type floating renewable energy solar power generation facility is disclosed about. The prior literature is an integrated floating structure having structural stability of the structure, and the power generation facility unit consisting of a structure for installing a buoyancy body floating on water and a solar module is connected to one or more columns and transverse directions through a connecting device.

The individual floating structure as described above must have a strong bond between units to suit the marine environment exposed to typhoons and waves, and must be easy to install unlike on land. An object of the present invention is to provide a floating solar power generation device that is excellent in cohesion between power generation facility units and is easy to install and separate.

Domestic Registration Patent No. 10-1160798 relates to a floating solar power generation facility in which a plate-shaped solar cell module is installed on the upper part of a pontoon and is constructed floatingly on the water. As a result, a plurality of buffer bodies surrounding the pontoon or pontoon assembly on which the photovoltaic power generation module is installed are configured, and these buffer bodies and the pontoons are connected with a plurality of tension lines, but the tension lines are radially狀) It discloses a buffer-type floating renewable energy solar power generation facility that can protect the power generation facility from the collision of drifting objects by having a structure. Domestic Patent Publication No. 10-2020-0083133 has a rectangular parallelepiped shape with an empty interior, and at least one sealing opening/closing means is provided on the upper part, and a plurality of bolt through holes are formed in the upper part of both sides, and safety rods are mounted on both sides of the square. An upper connecting plate having a hole formed therein is formed to protrude horizontally, and a lower connecting plate formed in the same shape as the upper connecting plate is formed in the upper part of the front and rear to protrude horizontally, and two or more pontoons are formed to protrude at least one Disclosed is a light directing system using a floating pontoon solar power generation facility that is horizontally connected through a pontoon connecting means and includes an assembly assembly floating on the water surface. In Korean Patent No. 10-1134289, the floating photovoltaic power generation system consists of a metal frame with an open lower part and a buoyancy material inserted into the lower part of the metal frame, and a plurality of pontoons are formed to be spaced apart from each other; a vertical connection frame screwed to a first fastening hole formed in a protruding portion of the longitudinal horizontal frame of the pontoon, and configured to connect the pontoon to each other in a vertical direction to be coupled; a horizontal connection frame screwed to a second fastening hole formed in a protruding portion of the longitudinal horizontal frame of the pontoon, and configured to connect the pontoon to each other in a horizontal direction to be coupled; a support frame fixed to an upper portion for each central portion between the pontoons of the horizontal connection frame; A first photovoltaic module supported by the support frame and formed at the upper end of the support frame and the first photovoltaic module formed along the longitudinal direction of the first photovoltaic module by an upper connecting member and a lower connecting member Disclosed is a floating photovoltaic power generation system consisting of a second photovoltaic module combined with. Korean Patent Laid-Open No. 10-2019-0138167 relates to a buoyancy body and a photovoltaic power generation device installed on the water. The advantage of minimizing the use of a fixed steel structure while maintaining physical rigidity by improving the coupling structure Disclosed is a fitting type buoyancy body with this and a floating solar power generator.

The present invention is to solve the problem that, in the existing floating solar power generation facility, the bonding force between the units is strong and the installation is easy in the marine environment exposed to typhoons and waves, one or more module support pontoons are connected adjacently A plurality of module support pontoons extended by a predetermined length are spaced apart at a predetermined interval and are installed to form one or more rows in the front and rear directions, so that the existing floating structure of solar power generation An object of the present invention is to provide a floating structure for a photovoltaic device that can reduce the cost and effort required for offshore installation by simplifying the configuration.

Floating structure for a photovoltaic device according to an embodiment of the present invention is a module support pontoon is connected to one or more adjacent to extend to a certain length; The plurality of module support pontoons extending by a predetermined length may be installed and installed to form one or more rows in the front and rear directions while being spaced apart from each other by a predetermined interval.

The neighboring module support pontoons may be connected and fixed via a horizontal fixing member, and a connection between a plurality of module support pontoons extending to a certain length may be connected and fixed via a vertical fixing member.

In the module support pontoon 100, which has buoyancy on the lower surface of the module support part 110 that can support and fix the solar cell module at a certain angle on the upper surface, and a convex-shaped block body is integrally coupled to the module 100 In the above, the module support 110 is formed in a concave shape with a relatively low height of one cross-section, so that one end of the solar cell module is seated and restrained, and a locking protrusion 111 is formed on the front part, and spaced apart by a predetermined interval. A sloping jaw 112 that protrudes to a predetermined height and supports the other end of the solar cell module to have an inclined surface of a certain angle is formed to extend to the left and right surfaces, and the height of the one side cross-section is relatively low. The left and right sides of the ruler-shaped module support 110 extend and protrude from the left and right sides of the convex-shaped block body integrally coupled to the lower portion, and are combined with the left and right sides of the convex-shaped block body. The vertical fixing member accommodating part 130 having a concave structure of "┐" and "┌" is formed, and the upper surface of the vertical fixing member 300 contacts the vertical fixing member accommodating part 130 to support the module support 110 . and; The front and rear directions of the upper surface of the convex-shaped block body coupled to the lower part of the concave-shaped module support 110 having a relatively low height of one cross-section are the concave-shaped module support ( 110) It is integrally formed according to the width to form an upper plane, and on the lower surface of the convex-shaped block body, a rectangular parallelepiped protruding in the front and rear directions is formed to form the lower surface and upper part of the convex-shaped block body The horizontal fixing member accommodating part 120 having a concave structure of "┘" and "└ " is formed while the planes are combined, so that the lower surface of the horizontal fixing member 200 is made to contact the horizontal fixing member accommodating part 120 . can

The bottom of the module support pontoon may have a concave portion concave toward the top of the bottom.
One or more module support pontoons are connected adjacent to each other in the left and right directions to form a volume of a certain length; The module support pontoons connected in the left and right directions and having a volume of a certain length are installed to form one or more rows spaced apart at a predetermined distance in the front and rear directions, and the one or more module support pontoons arranged in the left and right directions are horizontally fixed. The module support pontoon in which the member is fixed in contact with the horizontal fixing member accommodating part 120 and is spaced apart by a predetermined length in the front-rear direction to form one or more rows is supported by the vertical fixing member in contact with the vertical fixing member accommodating part 130 and a footrest may be formed in the space between the module support pontoons spaced apart by a predetermined length in the front-rear direction.

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In the present invention, the module support pontoon not only performs the role of a buoyant body while fixing the solar module, but also the fixing between the module support pontoons is possible only by installing a horizontal fixing member and a vertical fixing member. It has the effect of reducing the cost and installation effort.

1 shows a perspective view of a floating structure for a photovoltaic device of the present invention.
Figure 2 shows a side view of a floating structure for a photovoltaic device of the present invention.
3 shows a plan view of a floating structure for a photovoltaic device of the present invention.
Figure 4 shows a bottom view of the floating structure for a photovoltaic device of the present invention.
Figure 5 shows a perspective view of the module support pontoon of the present invention.
Figure 6 shows a side view of the module support pontoon of the present invention.
7 shows a rear view of the module support pontoon of the present invention.
8 is a perspective view of a floating structure for a photovoltaic device of the present invention according to the first embodiment.
9 is a side view of a floating structure for a photovoltaic device of the present invention according to the first embodiment.
10 shows a plan view of a floating structure for a photovoltaic device of the present invention according to the first embodiment.
11 shows a buffer frame according to Example 1 of the present invention.

Hereinafter, it will be described in detail with reference to the drawings related to the floating structure for a photovoltaic device of the present invention.

1 shows a perspective view of a floating structure for a photovoltaic device of the present invention, FIG. 2 shows a side view, FIG. 3 shows a plan view, and FIG. 4 shows a bottom view. Floating structure for photovoltaic device of the present invention is a module support pontoon 100 is connected to one or more adjacent to extend to a certain length; The plurality of module support pontoons extending to a predetermined length may be formed by being spaced apart from each other by a predetermined interval and by installing and coupling one or more in the front and rear array directions.

The module support pontoon is connected to one or more adjacent modules, a horizontal fixing member 200 is placed on a protruding horizontal portion of the module support pontoon, and a vertical fixing member to be described later is arranged on the horizontal member, so that the vertical fixing member is disposed on the vertical portion of the module support pontoon. is fixed and installed. The plurality of adjacently connected module support pontoons extending in a predetermined length and column form a predetermined interval in the front and rear directions, and at least one may be installed in the column direction to be fixed via the vertical fixing member 300 . In addition, the footrest 400 is installed in the space between the module support pontoons installed in the column direction to allow movement of the user.

Figure 5 shows a perspective view of the module support pontoon of the present invention, Figure 6 shows a side view, Figure 7 shows a rear view. The module support pontoon of the present invention is a structure including buoyancy, and the module support part 110 capable of supporting and fixing the solar module at a certain angle is formed on the upper part, and one end of the vertical fixing member is formed on the left and right sides of the module support pontoon. The vertical fixing member accommodating part 130 that can be mounted therethrough is formed; A horizontal fixing member is seated on the front and rear side surfaces of the module support pontoon, and a horizontal fixing member receiving part 120 that can be fixed by being pressed by the weight of the vertical member may be formed.

The bottom bottom of the module support pontoon may be made in a flat shape, and may have a concave shape toward the bottom top. In the case of a concave shape, when placed on the water surface, the module support pontoon sinks to a certain depth, and an air pocket air layer is formed in the concave portion, thereby increasing the buoyancy of the unit module support pontoon.

The module support pontoon of the present invention is a material that can contain buoyancy in the structure itself, and can be formed of FRP or polyethylene (PE) material that is easy to mold, is strong against seawater corrosion, and has excellent durability. Preferably, it can be formed of a linear low-density polyethylene material having excellent crystallinity, good rigidity or stress-cracking resistance, high tear resistance, and relatively large surface hardness, which can be formed into a molded article having excellent gloss. The interior may be formed of a hollow buoyancy body that is not filled with an empty structure or a filled buoyancy body filled with a lightweight filler.

The floating structure for a photovoltaic device of the present invention may be formed integrally with a solar cell module. Accordingly, the present invention has the advantage of easier assembly and production by simplifying the constituent parts compared to the conventional structure in which the solar cell module support part and the buoyancy body are respectively formed and fixed.

The module support unit 110 has a locking protrusion 111 formed on the front part so that one end of the solar cell module (not shown) can be seated and restrained and fixed, and protruding at a predetermined height from the rear part, so that one end of the solar cell module is a locking jaw It may be made of an inclined jaw 112 for supporting the solar cell module so as to form an inclination angle at a predetermined angle when it is caught and fixed.

The solar cell module referred to in the present invention may include a power generation device using a solar cell that generates electricity by the photoelectric effect when it receives sunlight as a technology for directly converting solar light as an energy source, which is commonly known. The solar power generation system may be composed of a module composed of a solar cell, a storage battery, and a power conversion device.

A solar cell generates photovoltaic power due to the photoelectric effect when a contact surface of a metal and a semiconductor or a PN junction of a semiconductor is irradiated with light, and may include crystalline silicon, amorphous silicon, compound semiconductor, or the like. Accordingly, a connection panel for collecting and outputting each of the DC power output from the solar module and an inverter for converting the DC power output from the connection panel into AC power may be further included. In addition, the edge of the solar cell module may include a frame to be fixedly coupled to the module support.

The solar cell module is fixed at a predetermined inclination to the module support part. This is to prevent snow or dust from being loaded on the solar cell module exposed to nature, and as a result, to prevent a decrease in the output of the solar cell module in advance.

The vertical fixing member accommodating part is for fixing one or more module support pontoons at regular intervals in the column direction through the vertical fixing member. is formed

On the front side, the cross-sectional structure of the module support pontoon is formed with protrusions left and right on the upper part and L-shaped concave parts on the lower part to form a structure protruding back and forth. Accordingly, the vertical fixing member may be installed such that the upper surface is mounted on the L-shaped protrusion and penetrates the L-shaped concave portion. When the module support pontoon is installed adjacently, a groove structure through which the vertical fixing member extended in the concave structure can pass is formed.

The transverse fixing member accommodating part has a L-shaped protrusion structure formed on the front and rear lower portions of the module support pontoon, so that the horizontal fixing member is seated on the upper side of the protruding structure, so that one or more module support pontoons can be connected to each other. In this case, it is appropriate that the upper portion of the protruding structure is formed in an area in which the horizontal fixing member receiving part is easily seated. In addition, since the vertical fixing member is seated and fixed on the upper part of the seated horizontal fixing member, the mutual coupling force between the module support pontoons can be improved by installing the vertical fixing member intersecting on the upper part of one or more horizontal fixing members.

In the present invention, the module support pontoon not only functions as a buoyant body while fixing the solar module, but also allows fixing between the module support pontoons only by installing a horizontal fixing member and a vertical fixing member. There is an effect that can reduce the cost and installation effort.

8 is a perspective view of a floating structure for a photovoltaic device of the present invention according to Example 1, FIG. 9 is a side view, and FIG. 10 is a plan view. Floating structure for photovoltaic device according to the first embodiment of the present invention is a module support pontoon is connected to one or more adjacent to extend to a certain length; The plurality of module support pontoons extending by a predetermined length are spaced apart from each other and installed to form one or more rows in the front and rear directions; The neighboring module support pontoons are connected and fixed via a horizontal fixing member, and a connection between a plurality of module support pontoons extending to a certain length is connected and fixed via a vertical fixing member to form an expanded floating structure; A buffer frame 500 may be installed at the edge of the expanded floating structure.

11 shows a buffer frame according to Example 1 of the present invention. The buffer frame according to the first embodiment of the present invention is a front and rear narrow structure with a larger width, and a flat cross-sectional structure has a trapezoidal shape, and a slope is formed on either side of the left or right side.

A transverse member receiving groove 501 that can accommodate a horizontal fixing member is formed on the front and side surfaces of the buffer frame, and a protruding frame 502 that can be mounted on the vertical fixing member is formed on the other side of the side where the slope of the buffer frame is formed. can be formed.

Accordingly, the buffer frame of the present invention can be fixed by seating the horizontal fixing member installed in the floating structure through the horizontal member receiving groove into the receiving groove, and the vertical fixing member installed in the floating structure is mounted on the protruding frame of the buffer frame. so that it can be fixed.

The buffer frame according to Embodiment 1 of the present invention is installed at the edge of the floating structure, and it is appropriate to install the inclined frame toward the sea. This is to reduce the occurrence of rolling pitching of the floating structure by dissipating the waves of the ocean colliding with the floating structure, and to maintain the durability of the structure itself and the bonding force between the module support pontoon.

By providing a floating structure for a photovoltaic device that is easy to install by simplifying the configuration of the present invention and strengthened the bonding force between unit facilities, it is possible to reduce production costs as well as to facilitate installation and separation at sea. By saving labor and time, it helps to increase the profits of related industrial people, and thus has industrial application.

100: module support pontoon 110: module support part
111: jamming jaw 112: inclined jaw
120: horizontal fixing member receiving portion 130: vertical fixing member receiving portion
200: horizontal fixing member 300: vertical fixing member
400: footrest 500: buffer frame
501: horizontal member receiving groove 502: projecting frame

Claims (5)

In the module support pontoon 100, which has buoyancy on the lower surface of the module support part 110 that can support and fix the solar cell module at a certain angle on the upper surface, and a convex-shaped block body is integrally coupled to the module 100 in
The module support unit 110 is formed in a concave shape with a relatively low cross-section height on one side, and a locking protrusion 111 is formed on the front part so that one end of the solar cell module is seated and restrained, and the rear part is spaced apart from each other by a predetermined interval. The inclined jaws 112 protruding to a certain height to support the other end of the solar cell module to have an inclined surface of a certain angle are extended to the left and right surfaces,
The left and right sides of the concave-shaped module support 110 having a relatively low height of one cross-section extend and protrude from the left and right sides of the convex-shaped block body integrally coupled to the lower portion. A vertical fixing member receiving portion 130 having a concave structure of “┐” and “┌” is formed while being combined with the left and right sides of the block body in the shape of a 凸), and the upper surface of the vertical fixing member 300 is a vertical fixing member receiving portion (130) to support the module support unit (110);
The front and rear directions of the upper surface of the convex-shaped block body coupled to the lower part of the concave-shaped module support 110 having a relatively low height of one cross-section are concave-shaped module support parts ( 110) It is integrally formed according to the width to form an upper plane,
On the lower surface of the convex block, a rectangular parallelepiped protruding in the front and rear directions is formed, and the concave structure of "┘" and "└ " is created by combining the lower surface and upper plane of the convex block. The formed horizontal fixing member accommodating part 120 is formed, and the lower surface of the horizontal fixing member 200 is a floating structure for a photovoltaic device, characterized in that it is made to contact the horizontal fixing member accommodating part 120 . delete The module support pontoon 100 of claim 1 is connected to one or more adjacent to each other in the left and right direction to form a volume of a certain length; The module support pontoons connected in the left and right directions and having a volume of a certain length are installed to form one or more rows by being spaced apart at regular intervals in the front and rear directions,
The one or more module support pontoons arranged in the left and right direction are fixed by a horizontal fixing member in contact with the horizontal fixing member accommodating part 120, and the module support pontoons in which one or more rows are formed by being spaced apart by a predetermined length in the front-rear direction are vertically fixed The member is supported in contact with the vertical fixing member receiving portion 130;
A floating structure for a solar power device, characterized in that a scaffold is formed in the space between the module support pontoons spaced apart by a predetermined length in the front and rear directions The method according to claim 3, wherein the buffer frame of the buoyancy body having a certain buoyancy is formed at the four corners of the module support pontoon which is formed by being coupled in the front-rear direction and the left-right direction, and the buffer frame is a right angle of the front and rear narrow structure of which the width increases in front and rear. A trapezoidal shape, a horizontal member receiving groove 501 is formed on the front and side surfaces of the buffer frame so that the horizontal fixing member can be accommodated. Floating structure for photovoltaic device, characterized in that it is formed delete

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