KR101890026B1 - Buoyancy frame module for solar panel - Google Patents

Abstract

The present invention provides a buoyancy module for a solar panel that further simplifies the structure of the buoyancy module and is easy to manufacture, and has high productivity and low manufacturing cost.
A buoyancy module for a solar panel according to a preferred embodiment of the present invention is a buoyancy module for a solar panel comprising a frame for supporting a solar panel and a buoyant body provided below the frame for floating the frame, A plurality of buoyant bodies disposed on the lower side in parallel with each other to generate buoyancy and to form a unidirectional frame; At least one solar panel front support rail mounted on an upper surface of the buoyant body and positioned to be perpendicular to the longitudinal direction of the buoyant body to support the front end of the solar panel; A rear support member installed on the upper surface of the buoyant member at a distance from the solar panel front support rail; And a solar panel rear support rail hung on an upper surface of the rear support member to support a rear end portion of the solar panel.

Description

Buoyancy frame module for solar panel [

The present invention relates to a buoyant body module for a solar panel, and more particularly, to a buoyant body module for a solar panel, which further simplifies the construction of the buoyancy module and is easy to manufacture and has high productivity and low manufacturing cost.

A buoyant body is essential for generating solar panels on the sea or in the water. The buoyant body is also used to float other various structures. In general, the shape of the buoyant body is a styrofoam having a cylindrical shape, and a method of covering the cylindrical styrofoam with a membrane cover and fixing the styrofoam to the structure with a tie band is used. In this case, the seawater penetrates into the cover after a lapse of time, and the strength of the cylindrical styrofoam is weakened due to the salt, so that a part of the styrofoam is separated or broken. Furthermore, there is a problem that the film cover and the cylindrical styrofoam are easily damaged by waves or strong winds.

Therefore, the waterproofing problem of the cover covering the cylindrical styrofoam should be solved first, and a method of maintaining the buoyancy by generating the second buoyancy even if the waterproofing problem occurs secondarily is required. Furthermore, the buoyant body on which the solar panel is installed is required to have a structure that is not damaged by the sudden natural environment (typhoon, strong wind, waves, etc.) of the sea.

As a background of the present invention, Korean Patent Registration No. 10-1026543 discloses a buoyant body supporting apparatus and a floating structure using the same. The present invention relates to a buoyant body supporting portion which is mounted on a sea or a lake and into which a buoyant force for providing buoyancy is inserted, brackets formed on the buoyant body supporting portion and having at least one supporting portion having an engaging hole, Characterized in that the buoyant body supporting apparatuses comprise buoyant body supporting apparatuses for connecting the buoyant body supporting brackets to each other and connecting the fixing bars of the buoyant body supporting apparatus to the buoyant body supporting apparatuses at predetermined intervals. Lt; / RTI >

However, the background technology of the electron drops the buoyancy function immediately when the flooding occurs inside the buoyant body, and the safety is low. In addition, there is no way to install the solar panels directly for solar power generation.

Another background art of the present invention is Korean Patent Registration No. 10-0880853, which discloses a buoyant body using an EPO and a pontoon using the buoyant body. The guide groove forming part is symmetrical with respect to the inner wall surface so that the plate material can be vertically inserted into the inner wall surface. And a plurality of nut holes are formed on an upper surface of the sidewall; A bolt hole is formed in a position corresponding to the nut hole along an edge of the body part, and the bolt hole is formed in the body part, A lid part provided with a groove along the bottom surface edge so as to engage with the upper end of the side wall and having a support plate upright along both side edges of the top surface; And the upper end is in contact with the bottom surface of the lid part in a state where the lower end is in contact with the bottom plate of the body part, A reinforcement plate which is repeatedly bent to increase the strength and has a concave and convex surface and in which holes are formed in various places in order to reduce the weight; A lightweight block of an EPS material fitted in the unit space; And a pressing piece protruding from at least one of a bottom plate of the body part and a bottom surface of the lid part and being pressed into the light block.

However, the latter background technology has a problem that the lightweight block is entirely filled in the unit space of the body portion, so that the foam material is used in a large amount, which raises the production cost, and it is difficult to install it directly on the solar panel.

Korean Patent Registration No. 10-1151091 Korean Registered Utility Model Registration No. 20-0438089

An object of the present invention is to provide a buoyant body module for a solar panel which further simplifies the structure of the buoyancy body module and is easy to manufacture and has high productivity and low manufacturing cost.

A buoyancy module for a solar panel according to a preferred embodiment of the present invention is a buoyancy module for a solar panel comprising a frame for supporting a solar panel and a buoyant body provided below the frame for floating the frame, A plurality of buoyant bodies disposed on the lower side in parallel with each other to generate buoyancy and to form a unidirectional frame; At least one solar panel front support rail mounted on an upper surface of the buoyant body and positioned to be perpendicular to the longitudinal direction of the buoyant body to support the front end of the solar panel; A rear support member installed on the upper surface of the buoyant member at a distance from the solar panel front support rail; And a solar panel rear support rail hung on an upper surface of the rear support member to support a rear end portion of the solar panel.

Further, the buoyant body is formed by drawing and forming a FRP channel having a trough opened upward in the longitudinal direction, a lightweight filler inserted into the trench and disposed in the FRP channel, a plurality of lightweight fillers disposed at both ends of the FRP channel, And an end stop plate for preventing dislodgment; The lightweight filler may be selected from the group consisting of EPS blocks, rigid polyurethane foams, polystyrene foams, polyethylene foams, polypropylene foams, EVA crosslinked foams, PET resin foams, phenol foams, silicone foams, polyvinyl chloride foams, urethane foams, acrylic foams, polyimide foams , And EPDM foam.

Further, the solar panel front support rail may include a lower flange for maintaining a flat mounting posture; A leg protruding upward from the lower flange at a predetermined height; A solar panel bracket that is bent at an upper end of the leg and inclined upward at an angle; And a solar panel stop jaw extending upward from the upper end of the leg at an angle of 90 degrees with respect to the solar panel jaw.

In addition, the rear support peg has a trapezoidal hollow portion that is drawn and formed through the center thereof, and has a rail mounting portion that is inclined upward on the upper surface to mount the solar panel rear support rail, a railing member that supports the solar panel rear support rail, And a reinforcing bridge formed by being inclined at a predetermined angle.

The buoyant body further includes a cover plate provided on the upper surface of the FRP channel, and the cover plate has a sliding engagement protrusion that is bent at both sides in the width direction and coupled to the upper flange of the FRP channel.

Further, a transverse hinge connector for connection in the width direction between the buoyancy module for the solar panel is further provided at the end of the solar panel front support rail.

Further, a vertical hinge connector for longitudinal connection between the buoyancy module for the solar panel is further provided at an end of the buoyant body.

Further, the FRP channel may further include an upper flange for preventing upward displacement of the lightweight filler at the upper end and for installing the vertical hinge connection.

In addition, the rear support opening is further provided with a windshield plate to prevent wind pressure from being generated on the bottom surface of the solar cell plate.

The buoyant body module for a solar panel of the present invention is simplified in the structure and the manufacturing cost is reduced because the cylindrical buoyant body and connecting means for connecting the cylindrical buoyant body to the frame are removed as in the conventional art. In addition, the production speed is improved by drawing and forming most components such as the FRP channel and the rear support, which are the skeleton of the buoyant body, and the buoyant body provides the function of the buoyancy and the function of the lower frame at the same time.

Further, the buoyancy module for a solar panel can be connected by a hinge structure to prevent breakage due to wind, wind, and wind.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a perspective view of a buoyancy module for a basic solar panel according to the present invention in a state in which a solar panel is installed.
Figure 2 is a side view of Figure 1;
3 is an enlarged view of a portion 'A' in FIG. 2;
4 is an enlarged view of a portion 'B' in FIG. 2;
Fig. 5 is a view showing a part of the solar battery panel removed in Fig. 1 and a part of the buoyant member separated. Fig.
6 is a perspective view of a buoyancy module for a basic solar panel according to the present invention.
7 is an exploded perspective view of a buoyant body applied to the present invention.
8 is a perspective view of a transverse hinge connector according to the present invention.
Figure 9 is a perspective view of a longitudinal axle hinge connector according to the present invention;
10 is a perspective view showing a combination of four buoyancy modules for a basic solar panel according to the present invention in combination.
11 is a view showing a state of a connection portion in the horizontal axis direction in Fig.
12 is a view showing a state of a connecting portion in a vertical axis direction in FIG.
13 is a modification example of the rear support member according to the present invention and a state in which the windshield plate is installed.
Fig. 14 is a partially enlarged view of one side of Fig. 13;
15 is a perspective view of one end of a buoyant body according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 and 6, the buoyancy module 10 for a solar panel according to the embodiment of the present invention includes a plurality of buoyant bodies 20, one or more solar panel front support rails 22, a plurality of rear support openings 24 ), And a plurality of solar panel rear support rails (26).

The buoyant body (20) is used as a portion receiving buoyancy directly at sea or at the lake. At least a plurality of buoyancy bodies (20) are installed in one buoyancy module (10) for a solar panel. At this time, the neighboring buoyant members 20 and 20 are arranged side by side at regular intervals and are installed on the lower side of the buoyancy module 10 for the solar panel.

5 and 7, the buoyant body 20 includes an FRP channel 201 having a trough 201b having a rectangular cross-section which is drawn and formed upward by a fiber reinforced plastic (FRP) A lightweight filler 202 inserted into the FRP channel 201 inserted in the FRP channel 201b and an end stopper plate 203 disposed at both ends of the FRP channel 201 to prevent the light filler 202 from escaping in the longitudinal direction .

The FRP channel 201 may further include upper flanges 201a and 201a for preventing upward displacement of the lightweight filler material 202 and for installing the vertical axis hinge connection port 32 at the upper end. In addition, L-shaped reinforcing angles 204 may be additionally disposed at both side ends of the trough 201b to reinforce the installation of the end stopper plate 203 and may be fixed to the FRP channel 201. [ Here, the FRP channel 201 can be manufactured by increasing the wall thickness at the portion where the longitudinal hinge connector 32 will be fixed, that is, the upper side wall.

The lightweight filler 202 may be an EPS block, a rigid polyurethane foam, a polystyrene foam, a polyethylene foam, a polypropylene foam, an EVA crosslinked foam, a PET resin foam, a phenolic foam, a silicone foam, a polyvinyl chloride foam, a urethane foam, A foamed material, a foamed material, a foamed material, a foamed material, and a foamed material.

The lightweight filler 202 is assembled in the FRP channel 201 so that the buoyant body 20 can receive the buoyancy force of the buoyancy module 10 for the solar panel and at the same time the buoyancy module 10 So that there is no need to construct a separate frame and a cylindrical buoyant body as in the prior art, thereby simplifying the structure and greatly reducing the overall manufacturing cost.

The buoyant body 20 may further include a cover plate 205 installed on the upper surface of the FRP channel 201. When the cover plate 205 is installed, seawater is prevented from entering the inside of the FRP channel 201, so that the life of the lightweight filler 202 can be improved. At this time, the cover plate 205 may be further formed on both sides in the width direction as shown in FIG. 15 and formed with sliding engagement tabs 205a and 205a to be coupled to the upper flanges 201a and 201a of the FRP channel 201. [

One or more solar panel front support rails 22 are mounted on the upper surface of the buoyant body 20 to be positioned in a direction perpendicular to the longitudinal direction of the buoyant body 20 to support the front end of the solar panel 5.

2 and 4, the solar panel front support rail 22 includes a lower flange 221 for maintaining a flat attitude, a leg 222 protruding upwards at a predetermined height from the lower flange 221, Which is bent upward at an upper end of the solar panel holding jaw 224 and extends upward from the upper end of the leg 222 at an angle of 90 degrees with the solar panel holding jaw 223, ).

The rear support member 24 is fixedly mounted on the upper surface of the buoyant member 20 at a certain distance from the solar panel front support rail 22.

As shown in FIGS. 2 and 3, the rear support 24 has a trapezoidal hollow portion 241 formed by drawing and passing through the center. Since the rear support tool 24 is manufactured by drawing and forming, the workpiece can be easily cut by the width of the buoyant body 20, thereby improving productivity and strength. The rear pedestal 24 is provided with a rail mounting portion 242 inclined upwards on the upper surface and a rail bracket 243 for straddling the solar panel rear supporting rail 26 to seat the solar panel rear supporting rail 26 . As shown in FIGS. 13 and 14, the rear support 24 may further include a reinforcing bridge 244 formed to be inclined to the trapezoidal hollow portion 241.

In addition, a windshield 50 may be installed on the rear support 24 to prevent wind pressure from being generated on the bottom surface of the solar cell 5, as shown in FIGS. At this time, the windshield plate 50 can be coupled to the rear support member 24 by being supported by a pair of parallel square channels 52 between the rear support member 24 and the rear surface. For example, a bolt and a nut (not shown) are used to fix the windshield 50 to the rear support 24. Therefore, the windshield plate 50 can be prevented from breaking or dropping due to strong winds or gusts by preventing strong winds or gusts from reaching the bottom surface of the solar panel 5.

The solar panel rear support rail 26 is stuck on the upper surface of the rear support member 24 to support the rear end of the solar panel 5. In this embodiment, the solar panel rear support rail 26 has an H-shaped cross section, but is not limited to this cross sectional shape.

A transverse axis hinge connector 30 having a hinge hole 30a as shown in Fig. 8 is additionally provided at the end of the solar panel front support rail 22 for widthwise connection between the buoyancy module 10 and 10 for the solar panel . At this time, the transverse hinge connectors 30 may be installed to face the ends of the solar panel front support rails 22 in pairs as shown in FIG.

9 and 12, a longitudinally extending hinge connector 32 having a hinge hole 32a is further installed at the end of the buoyant body 20 for longitudinal connection between the buoyancy module 10 and 10 for the solar panel. . At this time, the longitudinally-extending hinge connectors 32 may be installed to face the upper end side of the buoyant body 20 as a pair.

As shown in FIG. 10, the buoyancy module 10 for a solar panel has a transverse axis hinge connection 30 in the width direction and a longitudinal hinge connection port 32 in the longitudinal direction. Thus, The buoyancy module 10 for a plurality of solar panels can be hinge-connected by connecting the hinge pins 40 and 42 (or bolts) to the hinge holes 30a and the hinge holes 32a without restriction.

Accordingly, even if a wave occurs in the sea, the buoyancy module 10 for a plurality of solar panels can be independently managed in a rolling and motional motion.

As described above, the buoyant body module 10 for a solar panel configured as described above is simplified in structure and reduced in manufacturing cost by eliminating the cylindrical buoyant body and connecting means for connecting the cylindrical buoyant body to the frame. The production speed is improved by drawing and forming most of the components such as the FRP channel 201 which is the skeleton of the buoyant body 20 and the rear support 24 and the buoyancy body 20 functions as a buoyant force, Functionality. ≪ / RTI >

In addition, the connection between the buoyancy modules 10 for the solar panel can be structured as a hinge to prevent breakage due to wind, wind, and wind.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

20: Buoyancy
202: Lightweight filler
203; End swimmer
22: Solar panel front support rail
24: Rear base
26: Solar panel rear support rail
30: transverse hinge connector
32: vertical axis hinge connector
50: windshield plate

Claims (9)

A buoyant body module for a solar panel comprising a frame for supporting a solar panel and a buoyant body provided at a lower portion of the frame for floating the frame,
A plurality of buoyant bodies (20) arranged on the lower side in parallel with each other at regular intervals to generate buoyancy and to form a unidirectional frame;
One or more solar panel front support rails (22) mounted on the upper surface of the buoyant body (20) and positioned to be orthogonal to the longitudinal direction of the buoyant body (20) to support the front end of the solar panel (5);
A rear support hole (24) formed on the upper surface of the buoyant body (20) at a certain distance from the solar panel front support rail (22);
And a solar panel rear support rail (26) straddling the upper surface of the rear support member (24) to support a rear end portion of the solar panel (5)
Wherein the rear base (24) is provided with a windshield (50) to prevent wind pressure from being generated on a bottom surface of the solar cell (5). The method according to claim 1,
The buoyant body (20)
A lightweight filler 202 inserted into the trench 201b and disposed in the FRP channel 201, a FRP channel 201 inserted into the trench 201b and having a trough 201b that is drawn out and opened upward in the longitudinal direction, And an end swing plate (203) disposed at both ends of the lightweight filler (202) to prevent the light filler (202) from falling in the longitudinal direction;
The lightweight filler material 202 may be selected from the group consisting of EPS blocks, rigid polyurethane foams, polystyrene foams, polyethylene foams, polypropylene foams, EVA crosslinked foams, PET resin foams, phenol foams, silicone foams, polyvinyl chloride foams, urethane foams, Polyimide foam, EPDM foam, and the like. The method according to claim 1,
The solar panel front support rails (22)
A lower flange 221 for maintaining a flat inclined posture;
A leg 222 protruding upward at a predetermined height from the lower flange 221;
A solar panel latch boss 223 bent at an upper end of the leg 222 and inclined upward at a predetermined angle;
And a solar panel stand jaw (224) extending upwardly from an upper end of the leg (222) at an angle of 90 degrees with respect to the solar panel hangup (223). The method according to claim 1,
The rear support (24)
A rail mounting portion 242 having an upwardly inclined upper surface and a solar panel rear support rail 26 for receiving the solar panel rear support rail 26 and having a trapezoidal hollow portion 241 penetrated at the center thereof, And a reinforcing bridge (244) formed by inclining to the rail-jaw holder (243) and the trapezoidal hollow portion (241). 3. The method of claim 2,
The buoyant body 20 further includes a cover plate 205 provided on the upper surface of the FRP channel 201. The cover plate 205 is bent at both sides in the width direction to cover the upper flanges 201a and 201a of the FRP channel 201 (205a, 205a) to be coupled to the light emitting diode (LED). The method according to claim 1,
And a transverse hinge connector (30) for widthwise connection between the buoyancy module (10) and the solar panel buoyancy module (10) is further provided at an end of the solar panel front support rail (22) . The method according to claim 1,
And a longitudinal axis hinge connection (32) for longitudinal connection between the buoyancy module (10) and the solar panel buoyancy module (10) is further provided at the end of the buoyancy body (20). 3. The method of claim 2,
Wherein the FRP channel 201 further includes upper flanges 201a and 201a for preventing upward displacement of the lightweight filler material 202 and for installing the vertical axis hinge connection 32. [ module. delete

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