KR101602578B1 - Buoy structure for mounting solar cells - Google Patents

Abstract

The present invention relates to a buoy structure for mounting a solar cell. The buoy structure for mounting a solar cell includes; a buoy; and a solar cell mounting module including a solar cell and connected to a connection hole of the buoy by a fastener. The buoy comprises: an upper surface wherein a cross section is formed in a circle; a lower surface wherein the cross section is formed in the circle and the diameter of the lower surface is smaller than the diameter of the upper surface; a side surface extended to be rounded to be convex to the outer direction and connecting the upper surface and the lower surface; a hollow hole having a fixed diameter in the center of the upper surface and the lower surface and formed to penetrate from the upper surface to the lower surface; and the multiple connection holes formed to be concave in a radial direction along the outer circumference of the hollow hole. According to the present invention, the buoy structure for mounting a solar cell can provide a stable floating state on the water and can reduce manufacturing costs by having a simple structure by having a floating structure in which a semi-sphere body is improved by having the hollow hole. The buoy structure for mounting a solar cell can stably connect the buoys by a bracket and a connector.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a buoy structure for a solar cell,

The present invention relates to a buoy structure for connecting a solar cell, and more particularly, to a buoy structure for a solar cell, which comprises a solar battery mounted on a buoy suspended in a sea (water) having a solar cell, And more particularly, to a buoy structure for maximizing photovoltaic power generation efficiency by stably maintaining a floating state by a simple and unique structure.

Solar power is pollution-free clean energy, and various technologies that collect solar power through solar cell with various structures now and develop into electric energy are posted, and solar power can be used semi-permanently without causing pollution It is attracting attention as a future clean energy source.

Since the power generation efficiency of the solar cell is proportional to the irradiation amount of the sunlight and the irradiation time, it is preferable that the sunlight is abundant and the site is wide for smooth solar power generation.

However, when the solar cell is installed on the ground, the cost of purchasing the site is considerable, and there is a disadvantage that additional civil engineering work is required.

In order to solve this problem, various techniques and buoy structures have been developed for installing solar power generation facilities in water spaces such as rivers and seas.

The water space has a great advantage in that it does not require the purchase of land at all and the construction works are not necessary compared with the ground. On the other hand, the solar power generation facilities easily shake or sink due to waves or winds, Which is difficult to maintain.

In order to prevent this, Korean Patent No. 1111627, which is a solar cell unit, measures an intensity of a wave or the position of the sun and adjusts the floating state of a buoy according to the situation, .

According to this technique, it is recognized that the position control of the buoy can be flexibly controlled by the position of the sun, the wave direction and the wind direction, and the strength. However, this not only requires a considerable cost, Therefore, there is a problem that the buoy itself has a limitation in maintaining a stable floating state.

Accordingly, it is possible to provide a buoy or buoy to support a solar cell with less cost and a simple structure, to ensure a stable floating state of the buoy, and to easily adjust the center of gravity of a buoy, which is variable when mounting solar cells or observation equipment having various structures and shapes There is a need to develop new and advanced buoy structures that can be adjusted or varied.

SUMMARY OF THE INVENTION The present invention has been devised to overcome the problems of the prior art, and it is an object of the present invention to provide a buoy structure which has means for mounting a solar cell and provides a buoy having an improved hemispherical shape, .

Another object of the present invention is to connect a solar cell through a bracket and further connect a connector to a bracket so that a plurality of buoy structures can be stably connected by a connector.

A further object of the present invention is to provide a member capable of adjusting the center of gravity in addition to the bottom surface of the buoy, and the observation equipment can be combined with a separate support.

It is a further object of the present invention to improve the elongated structure of the hollow hole or side to adjust the center of gravity.

A further object of the present invention is to detach a member which adjusts the center of gravity through a hollow hole or side surface in a simple manner.

A further object of the invention is to ensure the durability of buoys as a double material.

In order to achieve the above object, a buoy structure for mounting a solar cell according to the present invention comprises a top surface having a circular cross section, a bottom surface having a circular cross section, a bottom surface having a smaller diameter than the top surface, A hollow hole extending from the upper surface to a lower surface and having a predetermined diameter at a central portion of the upper surface and the lower surface and extending in a radial direction along the outer circumference of the hollow hole; A buoy made by a ball; And a solar cell mounting module coupled to the solar cell module via a fastener through a fastener of the buoy, the solar cell module including a solar cell.

Further, a bracket is further connected to the fastening hole, a connector is connected to the bracket, the solar cell mounting module is mounted through a connection hole of the connector, and a plurality of buoy structures are connected by the connector .

In addition, the buoy structure further includes a center-of-gravity adjuster detachably mounted on the lower surface, the center-of-gravity adjuster being formed in a hemispherical shape extending in accordance with an elongated curve of the side surface.

According to the buoy structure for mounting a solar cell according to the present invention,

1) By a buoy structure having an improved hollow hemispherical structure and a hemispherical structure, it is possible to provide a stable floating suspension state while reducing manufacturing cost,

2) A plurality of buoys can be stably connected through a bracket and a connector,

3) It is possible to adjust the center of gravity flexibly according to various loads added to the buoy through the configuration of center of gravity according to various shapes and structures which are further detached from the buoys,

4) It is also possible to change the center of gravity by changing the inclination angle or curvature of the hollow hole or the side surface.

1 is a perspective view showing a schematic overall shape of a buoy according to the present invention;
2 is a longitudinal sectional view of a buoy according to the present invention;
3 is a longitudinal sectional view illustrating a state in which a solar cell mounting module is coupled to an upper surface of a buoy according to the present invention.
4 is a conceptual diagram showing a state where a bracket and a connector are coupled to a buoy according to the present invention;
5 is a conceptual view showing a state in which a center of gravity adjuster is additionally mounted on a bottom surface of a buoy according to the present invention.
6 is a conceptual diagram showing an alternative embodiment in which the inclination of the side or hollow hole in the buoy of the present invention is modified.
7 is a conceptual diagram showing a state in which a detachable inclination adjusting member is mounted on a buoy of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are not drawn to scale and wherein like reference numerals in the various drawings refer to like elements.

The buoy structure of the present invention basically comprises a buoy 100 and a solar cell mounting module 200 coupled with the buoy, and other additional configurations may be added.

FIG. 1 is a perspective view showing the overall shape of a buoy according to the present invention, and FIG. 2 is a longitudinal sectional view of a buoy according to the present invention.

1 and 2, the buoy 100, which is a core component of the buoy structure of the present invention, has a shape similar to a rice bowl and is suspended in the water (water) while supporting the solar cell mounting module 200 Function. The configuration of the buoy 100 is concretely analyzed to have a three-dimensional structure including an upper surface 110, a side surface 130, a lower surface 120, and a hollow hole 140.

The upper surface 110 and the lower surface 120 of the buoy 100 according to the present invention are formed such that the upper surface 110 and the lower surface 120 of the buoy 100 according to the present invention have a circular structure when viewed from above and have a flat surface, Depending on the structure and shape of the solar cell mounting module 200 to be coupled, the solar cell module 200 may be deformed into a shape that protrudes slightly outward or protrudes from a specific local site.

Particularly, the diameter of the upper surface 110 is larger than the diameter of the lower surface 120. This is because the buoy structure can not be easily moved to one side or overturned in the sea where the influence of external force such as waves or wind greatly acts, So as to provide improved buoyancy to maintain posture.

The side surface 130 of the buoy 100 refers to a side portion connecting the upper surface 110 and the lower surface 120 in a state of having a constant height. As shown in FIG. 2, the upper surface 110 and the lower surface 120 The upper surface 110 and the lower surface 120 are extended in a convexly rounded state so as to naturally and stably connect the circular upper surface 110 and the lower surface 120. In other words, A rounding taper is performed so that the width becomes narrower as it extends from the bottom surface 120 to the bottom surface.

The buoys 100 including the upper surface 110, the lower surface 120 and the side surface 130 may have various sizes. However, referring to FIGS. 1 and 2, the diameter of the upper surface 110 is The diameter of the lower surface 120 is 450 to 500 mm (480 mm), and the height of the side surface 130 is 350 to 400 mm (preferably 380 mm).

The hollow hole 140 of the present invention has a hollow having a predetermined diameter at a central portion of the upper surface 110 and extending through the lower surface 120 to the inner surface of the hollow portion 140, The present invention provides a function of concentrating the air passage or the pressure regulating function and the center of gravity to the central point of the upper surface 110 and the lower surface 120 in comparison with known floating buoys that depend only on properties, It is easy to avoid the problem of being tilted to the left or right due to various external forces.

In addition, it provides a characteristic that the inner part itself has a hollow structure and can have durability against external impacts, compared with a known buoy providing buoyancy by air pressure.

The hollow hole 140 may have various diameters depending on the volume of the buoy 100 and the shape and the load of the solar cell module 200 mounted on the top surface 110.

The buoy 100 of the present invention is basically made of a material providing buoyancy, and can be made of a single material or a double material structure.

As a single material structure, the buoy 100 of the present invention is composed of a foamable material that provides buoyancy, that is, a foamable synthetic resin material. Such a foamable synthetic resin material is, for example, such as a foamable polyurethane or expandable polystyrene.

The buoy table 100 of the present invention includes a first material portion surrounding the outer side of the side surface 130 and a peripheral portion of the upper surface 110 / , And a second material portion constituting the entire inside portion of the first material portion. At this time, the first material portion may be 5 ~ 15% of the width or thickness of the second material portion.

The first material portion may be made of high density polyethylene (HDPE) or low density polyethylene (LDPE) or a combination thereof, and the second material portion may be made of the above-described foamable synthetic resin material. Here, the first material portion serves as a cover for protecting the second material portion, and provides a durability of the entire buoy 100.

3 is a vertical cross-sectional view schematically illustrating a state in which a solar cell mounting module is coupled to an upper surface of a buoy according to the present invention.

The fastening hole 150 of the buoy 100 according to the present invention is formed as a plurality of radial holes formed along the outer periphery of the entrance of the hollow hole 140 of the upper surface 110. Through this fastening hole 150, The bracket 200 or the bracket 250 is detachably fastened through a fastener F such as a bolt / anchor. In this case, the fastener F fastened to the fastening hole 150 is formed not only in a straight shape, considering that the main material of the buoy 100 is a foamable elastic material, So that the bent end of the fastener F is fixed in the body of the buoy 100 so that the fastener F is securely fastened in the buoy 100. [

In the present invention, the solar cell mounting module 200 refers to an assembly having a solar cell 210, wherein the solar cell 210 is used for solar power generation or for driving a marine observation equipment And in the latter case, the solar cell mounting module 200 can include a marine observation device.

In addition, the solar cell module 200 includes a solar cell 210, a power generating unit (a cable for moving generated power and a charging unit may be provided) or a supporter 220 for supporting the solar cell 210, To be fastened with the fastening holes 150 formed in the upper surface 110 of the buoy through fasteners.

1 and 2, the cable flow hole 160 of the buoy 100 is radially formed along the outer periphery of the inlet of the hollow hole 140 of the upper surface 110, 150). ≪ / RTI > The cable circulation hole 160 has a function as a path through which a cable extended in a further configuration such as the solar cell mounting module 200 coupled to the top surface 110 or the observation equipment 320 that can be coupled to the bottom surface 120 .

Due to the structure and shape of such a buoy structure, it is possible to float in the sea in a more stable and durable state, and as a simpler structure, the convenience of manufacturing and maintenance can be improved, and solar cell and various observation equipment And provides usability that can be provided.

4 is a conceptual view showing a state where a bracket and a connector are coupled to a buoy according to the present invention.

The solar cell module 200 may be directly coupled to the top surface 110 of the buoy as shown in FIG. 3, but the brackets 250 or the brackets 250 and the connectors 280 To the buoy 100 via a combination of the two.

Referring to FIG. 4A, it can be seen that the bracket 250 is coupled through the fastening hole 150 of the upper surface 110.

The bracket 250 of the present invention may have various shapes such as an L shape, a U shape, and a U shape in a state of having a plurality of connection holes, and may be connected to the solar cell module 200 for convenience It is possible for the member 260 to be further coupled.

That is, the above-described solar cell mounting module 200 can be coupled through the connection hole of the bracket 250, thereby adjusting the mounting angle and arrangement of the solar cell mounting module 200, ) And the solar cell mounting module 200 can be ensured with ease of attachment and detachment.

4 (b), the buoy 100 of the present invention may be connected in a plurality of linearly or L-shaped aligned states by the connector 280 connected to the bracket 250 Do.

Specifically, the connector 280 is additionally connected to the connection hole of the bracket 250 connected to the buoy 100 through a fastener, and may have various shapes such as an angular pipe / circular pipe and an H beam.

In addition, the connector 280 may include a plurality of connection holes so that the solar cell module 200 can be coupled.

When the plurality of buoys 100 are connected by the connector 280, it is possible to support the solar cell module 200 or the observation equipment having a relatively large volume, and a plurality of buoys 100 can be installed in one set set to provide a scalability that allows the buoy 100 to be utilized for a variety of purposes.

5 is a conceptual diagram showing a state in which a center of gravity adjusting unit is additionally mounted on a lower surface of a buoy according to the present invention.

The center-of-gravity control unit 300 of the present invention further includes a center-of-gravity adjusting unit 300 for adjusting the volume of the buoy 100 and the shape of the solar cell mounting module 200 mounted on the buoy 100, Detachably mounted to the buoy 100 to provide the function of regulating the buoyant center of gravity that is deformed by the load of the solar cell mounting module 200 additionally provided on the buoy 100.

That is, the center-of-gravity adjuster 300 is basically formed of a cut-out sphere having a curved lower surface 120 having the same curvature as that of the side surface 120 or a curve corresponding thereto.

In addition, the center-of-gravity regulator 300 may be formed with a plurality of connection holes through which the additional observation equipment 320 or the support may be connected.

As shown in FIG. 5, the center-of-gravity adjuster 300 may be connected to the buoy 100 through a fastener by passing through the fastener through the lower surface 120 as in the upper surface 110, It is also possible to form the threads 121 and 310 on the side surface around the bottom surface 120 and the outer peripheral surface of the center-of-gravity adjuster 300 in the buoy 100 so as to be easily detached by thread engagement.

Fig. 6 is a conceptual view showing a modified embodiment in which the inclination of the side or hollow hole in the buoy of the present invention is modified. Fig.

6 (a) and 6 (b) are modification of the extended state of the hollow hole 140. The hollow hole 140 is not extended from the upper surface 110 to the lower surface 120 with the same diameter, 6 (a) shows a tapered state in which the diameters of the upper and lower portions are narrowed as the upper portion extends from the upper portion to the lower portion. FIG. 6 (b) That is, the diameter of the lower portion is increased as it extends from the lower portion to the upper portion.

6 (a) and 6 (b), the position of the center of gravity of the buoy 100 is shifted upward or downward relative to the hollow hole 140 shown in FIGS. The position of the center of gravity which is deformed in accordance with the load or the shape of the solar cell mounting module 200 mounted on the buoy 100 can be determined in a simple and intuitive manner It provides convenience functions that can be adjusted.

6 (c) is a modification of the rounding extension line on the side, and is constituted by the first curvature portion 131 and the second curvature portion 132 about the inflection point 133. In FIG.

The first and second curvature portions 131 and 132 are curved with respect to the inflection point 133 so that the center of gravity of the buoy 100 can be moved upward or downward from its original position .

6, it is possible to change the position of the center of gravity while changing the shape of the buoy 100 so that the appropriate one of these embodiments is selected according to the loads of the various additional structures mounted on the buoy 100 To be applied.

7 is a conceptual diagram showing a state in which a detachable inclination adjusting member is mounted on a buoy of the present invention.

As described above, since the center of gravity of the buoy 100 can be changed or adjusted by treating the extension line of the hollow hole 140 or the side surface 130 differently from the inclination, the inclination adjusting member 350 shown in Fig. Is a slice having a sloped surface or a rounded surface on one side and can be attached to and detached from the hollow hole 140 and the side surface 130 through the connection hole 351 via the fastener F. [ Correspondingly, at least one connection hole is additionally formed in one side of the hollow hole 140 or the side surface 130. [

The slope adjusting member 350 is additionally attached to the hollow hole 140 or the side surface 130 to adjust the center of gravity of the buoy by the load of the solar cell mounting module 200, It provides a center-of-gravity control function that prevents it from swaying easily as the center of gravity sinks upward.

In addition, the inclination or curvature of the inclined surface or the rounded surface of the inclination adjusting member 350 may be variously configured, and one of the inclined surfaces and the inclined surfaces may be coupled to the corresponding portion of the buoy according to the situation.

As described above, the construction and operation of the buoy structure for solar cell connection according to the present invention are described in the above description and drawings, but the present invention is not limited to the above description and drawings, It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit of the invention.

100: Buoy 110: Upper surface
120: lower 121: threaded
130: side surface 131: first curvature portion
132: second curvature portion 133: inflection point
140: hollow hole 150: fastening hole
160: Cable distribution hole 200: Solar cell mounting module
210: Solar cell 220: Supporter
250: bracket 260: connecting member
280: connector 300: center of gravity adjuster
310: Thread 320: Observation equipment
350: inclination adjusting member 351: connecting hole

Claims (7)

A buoy structure for mounting a solar cell,
A lower surface having a circular cross section and a smaller diameter than the upper surface, a side surface connecting the upper surface and the lower surface while being convexly rounded in an outward direction, and a side surface connecting the upper surface and the lower surface, A buoy having a hollow hole formed therethrough having a predetermined diameter from the upper surface to the lower surface thereof and a fastening hole formed in a plurality of holes radially formed along the outer circumference of the hollow hole;
A solar cell mounting module coupled with the fastener through the fastener through the fastener and having a solar cell;
And a slope adjusting member detachably mounted on one side of the hollow hole and the side face through a plurality of connecting holes through a fastener, the slope having one of an inclined face and a rounded face, Wherein the buoy structure for mounting the solar cell is a buoy structure. The method according to claim 1,
A bracket is further connected to the fastening hole,
A connector is connected to the bracket and the solar cell mounting module is mounted through a connection hole of the connector,
And a plurality of buoy structures are connected by the connector. The method according to claim 1,
The buoy structure may include:
Further comprising a center-of-gravity regulator formed in a hemispherical shape extending in accordance with an elongated curvature of the side surface, the center-of-gravity regulator being detachably mounted on the lower surface of the buoy structure. The method according to claim 1,
The buoy,
Characterized in that it comprises a first material part made of any one material of HDPE and LDPE and a second material part made of a foamable synthetic resin material constituting the inside of the first material part, Buoy structure. The method according to claim 1,
The hollow hole
Wherein the buoyant structure is tapered in any one of a shape of upper and lower beams and a shape of upper and lower beams. The method according to claim 1,
The side surface,
Wherein the buoy structure is extended to be rounded with different curves around the inflection point of one side. delete

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