KR20200133904A - Buoyancy structure for solar power apparatus constructed on the water - Google Patents

Abstract

The present invention relates to a solar power buoyancy structure on the water and, more specifically, to an improved solar power buoyancy structure on the water, which configures a body forming a buoyant body by using expanded polypropylene (EPP), thereby preventing buoyancy from being lost even when being exposed to ultraviolet rays so that structural stability can be reinforced, improving a shape not to be easily overturned even under the influence of external environments, being easily assembled and installed on a frame to easily and quickly perform initial installation and A/S, and easily separating and discharging products when the products are discarded.

Description

Buoyancy structure for solar power apparatus constructed on the water}

The present invention relates to a floating solar buoyancy structure, and more particularly, by configuring a body constituting the buoyant body using expanded polypropylene (EPP), so that the buoyancy is not lost even when exposed to ultraviolet rays, thereby enhancing structural stability, Furthermore, the shape is improved so that it is not easily conducted under the influence of the external environment, and the initial installation and A/S are easy and fast by facilitating assembly and installation on the frame, and the improved floating solar buoyancy structure enables separate discharge even when the product is discarded. About.

Solar power generation is a power generation method that directly converts sunlight into electric energy using solar cells without the aid of a generator.

Solar power generation consists of solar cells, storage batteries, and power conversion devices.

When sunlight is irradiated to a solar cell in which a P-type semiconductor and an N-type semiconductor are bonded together, holes and electrons are generated in the solar cell by the energy of the sunlight.

At this time, holes gather toward the P-type semiconductor and electrons toward the N-type semiconductor, so when a potential difference occurs, a current flows.

The advantage of photovoltaic power generation is that there is no pollution, it can generate electricity only as much as necessary in the necessary place, and maintenance is easy.

Of course, photovoltaic power generation has a disadvantage that the amount of electricity produced depends on the amount of sunlight, and the initial investment and power generation cost are high.

In particular, solar power generation has a big disadvantage that installation sites are limited because it requires a certain large-scale area on land.

Meanwhile, in recent years, efforts have been made to construct solar power generation on the water surface in order to compensate for the limited shortcomings of such installation locations. However, in order to build solar power generation on the water surface, a structure that floats the solar panel in water must be applied, and the installation position and posture of the solar panel must be maintained stably while the structure can ride the current well. There is a need for technology development to solve these issues.

In order to improve this, prior technologies such as the following [prior art literature] have been developed.

Nevertheless, in the prior art, when the buoyancy body is constructed, the outer shape is made of PE material and the inner shape is made of EPS material to receive good buoyancy, so that partial shrinkage occurs as PE is placed in a long-term UV exposure environment. There is a disadvantage that the buoyancy is reduced, making the structure safety weak.

Domestic Registration Patent No. 10-1595912 (2016-02-15), buoyancy structure for floating solar power generation Domestic Registration Patent No. 10-1787399 (2017-10-12), floating solar power generation structure

The present invention was created to solve the problems in the prior art as described above, and by configuring the body constituting the buoyancy body using expanded polypropylene (EPP), the buoyancy is not lost even when exposed to ultraviolet rays. The structural stability has been reinforced, and the shape has been improved so that it does not easily fall even under the influence of the external environment, and the initial installation and A/S are easy and fast by facilitating assembly and installation on the frame. Its main purpose is to provide a floating solar buoyancy structure.

The present invention is a means for achieving the above object, and is installed under a plurality of frames (FRMs) fixing a plurality of solar panels (CEL) so that the frame (FRM) and the solar panel (CEL) are stably in the water. In the floating solar buoyancy structure including a buoyancy body 100 for guiding to be floated, the buoyancy body 100 is molded of expanded polypropylene (EPP); The buoyancy body 100 is bound to the frame (FRM) through a long bolt (LBT); It provides a floating solar buoyancy structure, characterized in that at least one hemispherical groove is formed on the bottom surface of the buoyancy body 100 to form an air pocket therein when disposed on the water surface.

At this time, the hemispherical groove is also characterized in that the large-diameter groove 150 and the large-diameter groove 150 is formed in a plurality of small-diameter grooves 160.

In addition, it is characterized in that the guide protrusions 110 are further formed on both sides of the top surface of the buoyancy body 100 to accurately guide the assembly position when assembling to the frame FRM.

In addition, a working space 120 secured by cutting is further formed at the lower four corners of the buoyancy body 100; The long bolt (LBT) has a characteristic of being bound to the frame (FRM) through a washer (WAS) and a nut (NUT) after passing through each of the four corners of the buoyancy body (100).

In addition, a guide groove 140 is further formed around the long bolt LBT, which is an upper surface of the buoyancy body 100, to guide and position the frame FRM.

In addition, when the frame (RFM) is of the'I' type, a pair of'U' shaped first brackets 210 is provided, and the length passing through the'I' type frame (FRM) and the first bracket 210 The bolts (LBT) are fastened to each other to fix the buoyancy body 100 in the form of enclosing the feature.

In addition, when the frame (RFM) is of the'I' type, a long bolt having a'c' shape second bracket 220 and passing through the'I' type frame (FRM) and the second bracket 220 ( LBT) has a characteristic of being fixed in a form surrounding the buoyancy body 100 by being coupled to each other.

In addition, the surface of the buoyancy body 100 is characterized by further forming an arrow mark (ARW) indicating the position where the frame (FRM) is to be assembled.

According to the present invention, the following effects can be obtained.

First, the body constituting the buoyancy body is constructed using expanded polypropylene (EPP), so that the buoyancy is not lost even when exposed to ultraviolet rays.

Second, it is structurally safe even if used for a long time, and stability can be improved.

Third, it does not fall and it is easy to assemble and install on the frame, so initial installation and A/S are easy and fast.

Fourth, it is possible to separate and discharge the product even when disposing of the product.

1 is an exemplary view of a floating solar structure to which the buoyancy structure according to the present invention is applied.
2 is an exemplary view of a buoyancy body constituting the buoyancy structure according to the present invention.
3 is a cross-sectional view taken along line AA and an enlarged view of a main part of the buoyancy structure according to the present invention.
4 is an exemplary view showing a part of the upper surface of the buoyancy body of FIG. 3 extracted.
5 to 8 are various modifications showing examples of binding of the buoyancy body according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

Prior to the description of the present invention, the following specific structure or functional descriptions are exemplified only for the purpose of describing embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms, It should not be construed as being limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can apply various changes and have various forms, specific embodiments are illustrated in the drawings and will be described in detail herein. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific type of disclosure, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present invention are included.

As shown in FIG. 1, the floating solar buoyancy structure according to the present invention is installed under a plurality of frames (FRMs) fixing a plurality of solar panels (CEL), and the frame (FRM) and the solar panel (CEL) It includes a buoyancy body 100 to guide so that it can stably float in the water.

At this time, the buoyancy body 100 is manufactured by being molded of expanded polypropylene (EPP).

Accordingly, since the buoyancy body 100 retains the characteristics of EPP as it is, even if a part of the buoyancy body 100 is damaged due to ultraviolet light exposure or external force, stable support is possible without losing buoyancy.

In particular, the buoyancy body 100 according to the present invention, as in the example of Figures 2 to 4, is formed on both sides of the upper surface to accurately guide the assembly position when assembled to the frame (FRM) (110).

In addition, initial installation by cutting and forming a working space 120 for facilitating fastening when bolting for fixing the buoyancy body 100 to the frame (FRM) at the bottom 4 corners of the buoyancy body 100 And it ensures the ease of work during maintenance.

In addition, at the four corners of the buoyancy body 100, a bolt hole 130 is formed by penetrating it up and down, and a long bolt (LBT) as described later is inserted into the bolt hole 130 and then a washer (WAS). It is stably and firmly bound to the frame (FRM) through the and nut (NUT).

In this case, a guide groove 140 may be further formed around the upper surface of the buoyancy body 100 and the bolt hole 130 to guide the frame FRM to be smoothly guided and positioned.

The guide groove 140 may vary in various forms according to the shape of the frame (FRM), and in the present invention, it is merely expressed as an exemplary shape.

In addition, it is possible to further form an arrow mark (ARW) indicating the position to be assembled as shown in Fig. 4 (a) so as to more easily find the assembly position of the frame (FRM) to facilitate assembly.

Then, it is very easy and convenient to assemble because you only need to assemble by looking at the corresponding sign, that is, the arrow engraving (ARW).

In addition, a large-diameter groove 150 concave in a hemispherical shape is formed on the lower surface of the buoyancy body 100, and a small-diameter groove 160 having the same shape but having a small diameter is built into the large-diameter groove 150. Is formed.

In this way, the reason why the large-diameter groove 150 and the small-diameter groove 160 are concave-formed is that when the buoyancy body 100 is lifted upward by wave height and wave, friction with the water surface is increased by these grooves and is simply a flat plane. In comparison, it is possible to very effectively prevent the fall.

In addition, if appropriate air is trapped, a kind of vacuum pocket is formed, which increases adhesion to the water surface, making it more difficult to conduct.

In the present invention, the large-diameter groove 150 and the small-diameter groove 160 are formed to be concave upwardly in a slightly hemispherical shape in order to enjoy this effect.

In addition, in the description of FIGS. 2 to 4, an example of the frame (FRM) having a'C' shape is illustrated, but since the frame (FRM) can have cross-sections of various shapes, it is necessary to secure the ease of fastening accordingly. .

That is, in the present invention, despite the same buoyancy body 100, by changing only the bracket, it can be implemented to enable easy, fast, and convenient work by appropriately responding to the shape of the frame (FRM).

For example, FIGS. 5 and 6 illustrate a case in which the frame RFM is an'I' type, and accordingly, a pair of'U'-shaped first brackets 210 are provided, and the'I' type frame (FRM It shows that the buoyancy body 100 can be fixed to the frame (FRM) very easily and quickly by allowing the long bolts (LBT) to penetrate through each other.

In other words, by using the first bracket 210 against the change in the shape of the frame (FRM), it is possible to secure a fastening force that is very easy and convenient while being rigid.

As another example, as shown in FIGS. 7 and 8, there may be another example of bracket fastening when the frame (FRM) is an'I' type, for example, a second bracket 220 having a'c' shape is provided, If this is fastened and fixed with a long bolt (LBT), it is possible to fasten easily, conveniently and quickly, as in the example of FIGS. 5 and 6 above.

Moreover, it also secures a solid fixation stability. That is, since the bracket surrounds the buoyancy body 100, the bracket and the buoyancy body 100 are not easily separated and a close fixation relationship can be maintained.

By configuring in this way, it is possible to assemble the buoyancy body 100 easily and quickly, and furthermore, a function to prevent fall from the water surface is implemented, thereby providing structural stability.

100: buoyancy body 110: guide jaw
120: workspace 130: bolt hole
140: guide groove 150: large diameter groove
160: small-diameter groove 210: first bracket
220: second bracket

Claims (8)

Includes a buoyancy body 100 installed under a plurality of frames (FRM) fixing a plurality of solar panels (CEL) to guide the frame (FRM) and the solar panel (CEL) to stably float on the water In the floating solar buoyancy structure,
The buoyancy body 100 is molded of expanded polypropylene (EPP);
The buoyancy body 100 is bound to the frame (FRM) through a long bolt (LBT);
Floating solar buoyancy structure, characterized in that at least one hemispherical groove is formed on the bottom surface of the buoyancy body 100 to form an air pocket therein when disposed on the water surface.
The method according to claim 1,
The hemispherical groove is a floating solar buoyancy structure, characterized in that a large diameter groove 150 and a plurality of small diameter grooves 160 formed in the large diameter groove 150.
The method according to claim 1,
Floating solar buoyancy structure, characterized in that the guide protrusion 110 is further formed on both sides of the top surface of the buoyancy body 100 to accurately guide the assembly position when assembled to the frame (FRM).
The method according to claim 1,
A working space 120 secured by cutting is further formed at the lower 4 corners of the buoyancy body 100; The long bolt (LBT) is a floating solar buoyancy structure, characterized in that after passing through each of the four corners of the buoyancy body (100) and bound to a frame (FRM) through a washer (WAS) and a nut (NUT).
The method according to claim 1,
Floating solar buoyancy structure, characterized in that a guide groove 140 for guiding and positioning the frame (FRM) is further formed around the long bolt (LBT), which is the upper surface of the buoyancy body (100).
The method according to claim 1,
When the frame RFM is of the'I' type, a pair of first brackets 210 having a'U' shape are provided, and a long bolt passing through the'I' type frame (FRM) and the first bracket 210 ( LBT) is a floating solar buoyancy structure, characterized in that fixed in a form surrounding the buoyancy body (100) to be coupled to each other.
The method according to claim 1,
When the frame (RFM) is an'I' type, a long bolt (LBT) having a second bracket 220 of a'c' shape and passing through the'I' type frame (FRM) and the second bracket 220 Floating solar buoyancy structure, characterized in that fixed in a form surrounding the buoyancy body 100 by being coupled to each other.
The method according to claim 1,
On the surface of the buoyancy body 100, a floating solar buoyancy structure, characterized in that further formed with an arrow mark (ARW) indicating a position where the frame (FRM) is to be assembled.

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