KR102496593B1 - Lightweight concrete floating body module unit and manufacturing method of floating body with strong resistance to cold and wave environment using the same - Google Patents

Abstract

According to the present invention, in the floating body module unit forming a concrete floating body, the unit body 100 made of lightweight concrete; Coupling portion 200 for coupling with the neighboring unit body (100a); and a channel 300 coupled to the coupling part 200 to bind the unit body 100 and the neighboring unit body 100a together.
According to the present invention, there is an effect of preventing damage or loss of the floating body even in a severe cold or strong wave environment.

Description

Lightweight concrete floating body module unit and manufacturing method of floating body with strong resistance to cold and wave environment using the same {Lightweight concrete floating body module unit and manufacturing method of floating body with strong resistance to cold and wave environment using the same}

The present invention relates to the field of construction, and more particularly, in manufacturing a floating body used for offshore installation of a solar panel, etc., a lightweight concrete floating body manufactured using a concrete member having strong resistance to harsh cold or wave environments. It relates to a module unit and a method of manufacturing a floating body having strong resistance to cold and wave environments using the same.

Recently, the new and renewable photovoltaic industry, which has been in the spotlight, is being converted to the construction of floating or offshore photovoltaic facilities that utilize idle water surfaces in order to reduce indiscriminate land development.

Floating design technology that can secure floating stability is important because the movement of the solar panel floating body installed on the sea surface is greatly affected by wind and weather. Moreover, most of the large-scale solar floating bodies are vulnerable to natural disasters such as severe cold or typhoons and require high maintenance costs by using plastics in consideration of workability and economic feasibility. In addition, (fine) plastic waste generated during breakage is causing serious environmental problems.

There are many prior arts for the shape of a plastic-based floating system installed on the water or the sea, but only a few of the concrete-based floating body shapes. Prior art is largely classified into three types: "design of floating bodies to improve buoyancy (1)", "production of modular floating bodies with good manufacturability and workability (2)", and "disappearance or offset of waves" There is a floating structure (3)" to be considered. In the above technology, (1) and (2) facilitate effective coupling and construction between the floating body structure design and modular unit floating body that can directly charge and insert the buoyant body (EPS block, FRP, etc.) that provides buoyancy. It is a method of manufacturing a frame-type structure, and (3) is a vibration reduction type floating structure manufacturing technology based on a plastic system for minimizing local or total shaking of the floating structure due to waves.

As such, in the prior art, a buoyancy material filling structure was used to improve only the buoyancy of the floating body, and in some motion-reducing floating body technologies, plastic-based materials that are vulnerable to severe cold and typhoons are used, which cannot guarantee the design life and maintain It is also bad for management.

Recently, in line with the government-led Green New Deal policy, the demand for and interest in offshore solar power plants, which are new and renewable energy, is increasing. It is being used. However, plastic materials can be easily damaged in natural disasters such as typhoons and at low temperatures such as in winter due to their brittle nature, which can cause serious environmental pollution. In addition, there is a limit to securing floating stability by minimizing the influence of waves in the conventional rectangular floating shape. Damaged by such a weak durability and floating shape that is not favorable to the wave environment. Because the maintenance cost due to replacement increases, it is based on a lightweight concrete material rather than plastic, and at the same time, a concrete part that can improve floating stability against waves, etc. I would like to suggest a fluid.

The present invention was derived to solve the above-mentioned problems of the conventional marine or floating floating body, and an object of the present invention is a lightweight concrete floating module unit with little damage or loss even in a harsh cold or strong wave environment and a cold and wave environment using the same It is an object of the present invention to provide a manufacturing method of a floating body having strong resistance to fire.

In particular, a lightweight concrete floating module unit that can increase the installation safety of a mounted solar panel by reducing wave energy even in a wave environment of strong energy and a method of manufacturing a floating body with strong resistance to cold and wave environments using the same is in doing

In addition, a lightweight concrete floating module unit that is easy to manufacture and can respond to various sizes of loading objects by manufacturing a floating body with a modular unit and a method of manufacturing a floating body with strong resistance to cold and wave environments using the same is in providing

In addition, a lightweight concrete floating module unit that can reduce material costs and contribute to environmental protection by manufacturing lightweight concrete constituting the main body of a floating body by mixing recycled materials such as waste striatum, waste glass bottles, and recycled aggregates, and a lightweight concrete floating body module unit using the same It is an object of the present invention to provide a manufacturing method of a floating body having strong resistance to harsh cold and wave environments.

According to one aspect of the present invention, in the floating body module unit forming a concrete floating body, the unit body 100 made of lightweight concrete; Coupling portion 200 for coupling with the neighboring unit body (100a); and a channel 300 coupled to the coupling part 200 to bind the unit body 100 and the neighboring unit body 100a together.

In this case, the coupling part 200 includes a protrusion 210 formed on one surface of the unit body 100; and a depression 220 formed on the other surface of the unit body 100 and into which the protrusion 210a of the neighboring unit body 100a is inserted.

In addition, the coupling portion 200 includes a bolt inlet 230 formed on an upper surface of the unit body 100; and a bolt 240 passed through the through hole 310 formed in the channel 300 and fastened to the bolt inlet 210 .

In addition, the unit body 100 includes a convex unit body 110 having a convex lower surface; and a concave unit body 120 having a concave lower surface.

In addition, the unit body 100 and the adjacent unit body 100a may be a floating body module unit characterized in that they are coupled in the longitudinal direction (a) of the floating body.

In addition, the convex unit body 110 and the concave unit body 120 may be coupled to each other in the width direction (b) of the floating body.

In addition, the channel 300 may be a floating body module unit characterized in that it is coupled at predetermined intervals along the longitudinal direction (a) of the floating body.

In addition, the channel 300 may be a floating body module unit characterized in that it is formed to extend along the width direction (b) of the floating body.

In addition, the unit body 100 and the adjacent unit body 100a are coupled by the bolt 240 and the channel 300, and the convex unit body 110 and the concave unit body 120 May be a floating module unit characterized in that coupled by the channel (300).

In addition, the floating module unit may further include an elastic pad 400 formed on an upper surface of the unit body 100 where the channel 300 is located.

According to another aspect of the present invention, in the manufacturing method of a floating body using a floating body module unit, connecting the unit body 100 and the neighboring unit body 100a in the longitudinal direction (a) of the floating body In addition, a first step (S100) of continuously arranging the convex unit body 110 and the concave unit body 120 in the width direction (b) of the floating body; and a second step (S200) of coupling the channel 300 to the unit body 100 using the bolt 240.

According to another aspect of the present invention, in the manufacturing method of the unit body for manufacturing the unit body 100, mixing cement, recycled aggregate, waste styrofoam, waste plastic and waste glass bottle to mix lightweight concrete (A100); there is provided a method of manufacturing a unit body comprising a.

According to the present invention, there is an effect of preventing damage or loss of the floating body even in a severe cold or strong wave environment.

According to the present invention, there is an effect of increasing the mounting safety of the mounted solar panel by reducing the blue energy even in a blue environment of strong energy.

According to the present invention, by manufacturing a floating body as a modular unit, it is easy to manufacture and has an effect of being able to respond to objects of various sizes.

According to the present invention, it is possible to reduce material costs and contribute to environmental protection by manufacturing lightweight concrete constituting the main body of a floating body by mixing recycled materials such as waste striatum, waste glass bottles, and recycled aggregate.

1 is a perspective view of a lightweight concrete floating body manufactured by a floating body module unit according to an embodiment of the present invention.
2 is a front perspective view of a floating module unit having a convex unit body according to an embodiment of the present invention.
3 is a rear perspective view of a floating module unit having a convex unit body according to an embodiment of the present invention.
4 is a front perspective view of a floating module unit having a concave unit body according to an embodiment of the present invention.
5 is a rear perspective view of a floating module unit having a concave unit body according to an embodiment of the present invention.
6 is a cross-sectional view of a floating body according to an embodiment of the present invention.
7 is a side perspective view of a module unit according to an embodiment of the present invention;
8 is comparison data of maximum vertical displacement of a floating body and a general floating body according to an embodiment of the present invention.
9 is comparative data showing the maximum pitch for each wave height of a floating body and a general floating body according to an embodiment of the present invention.

An embodiment of a lightweight concrete floating body module unit according to the present invention and a method of manufacturing a floating body having strong resistance to cold and wave environments using the same will be described in detail with reference to the accompanying drawings, which will be described with reference to the accompanying drawings Therefore, the same or corresponding components are given the same reference numerals, and overlapping descriptions thereof will be omitted.

In addition, terms such as first and second used below are only identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are not limited by terms such as first and second. no.

In addition, coupling does not mean only the case of direct physical contact between each component in the contact relationship between each component, but another configuration intervenes between each component so that the component is in the other configuration. It should be used as a concept that encompasses even the case of contact with each other.

The present invention relates to a concrete floating body that is suspended on water and supports a solar panel or the like. The concrete floating body according to the present invention is a modular structure formed by combining a plurality of module units.

In detail, a module unit according to an embodiment of the present invention will be described.

The module unit according to an embodiment of the present invention is coupled to the unit body 100 made of lightweight concrete, the coupling part 200 for coupling with the neighboring unit body 100a, and the coupling part 200 to the unit body ( 100) and a channel 300 for binding neighboring unit bodies 100a (FIG. 1).

The unit body 100 and the adjacent unit body 100a have the same configuration. However, for convenience, the term "neighboring" is used to distinguish continuously connected locations.

The unit body 100 may be formed by lightweight concrete. The lightweight concrete forming the unit body 100 according to the present invention may be manufactured by mixing recycled aggregate, waste Styrofoam 1, waste plastic and waste glass bottles together with cement to lower specific gravity.

Accordingly, it is possible to form a body of a floating body with high resistance to waves or harsh environments, and contribute to environmental protection by constructing a solar power generation facility that creates new and renewable energy using recycled materials.

The coupling part 200 is a configuration for coupling unit bodies 100 continuous in the longitudinal direction (a) of the floating body to each other, and includes a protrusion 210 formed on one surface of the unit body 100 and a unit body 100. It is formed on the other side and includes a recessed portion 220 into which the protruding portion 210a of the neighboring unit body 100a is inserted.

In addition, the coupling part 200 passes through the bolt inlet 230 formed on the upper surface of the unit body 100 and the through hole 310 formed in the channel 300, and the bolt 240 fastened to the bolt inlet 210 is further inserted. can include

The bolt inlet 230 is formed at both ends of the upper surface of the unit body 100, and one channel 300 can be coupled to the bolt inlet 230a formed in the neighboring unit body 100a by a bolt 240. .

The unit body 100 of the module unit according to an embodiment of the present invention may include a convex unit body 110 having a convex lower surface and a concave unit body 120 having a concave lower surface.

Accordingly, as shown in FIG. 6, the two types of unit bodies 100 are alternately coupled in the width direction b of the floating body to form one floating body.

In this case, the lower surface of the floating body has a shape in which a convex part and a concave part are continuous, and resistance to waves can be increased.

Referring to FIGS. 8 and 9, it can be seen that, compared to a floating body with a flat lower surface, a floating body having a convex portion and a concave portion repeatedly has a smaller vertical behavior and a smaller maximum pitch value, so that the influence of waves is less. .

Accordingly, damage or breakage of the floating body itself due to waves can be prevented, and damage or damage to a solar panel mounted on the floating body can be minimized.

In order to form such a structure, the unit body 100 of the module unit according to an embodiment of the present invention and the unit body 100a adjacent to it are coupled in the longitudinal direction (a) of the floating body, and the convex unit body 110 and The concave unit body 120 is coupled in the width direction b of the floating body (FIG. 7).

The plurality of unit bodies 100 continuously arranged in the longitudinal direction (a) and the width direction (b) of the above-described floating body may be coupled by the coupling part 200 and the channel 300.

The channels 300 according to the present invention may be coupled at predetermined intervals along the longitudinal direction (a) of the floating body.

In addition, the channel 300 may be formed to extend along the width direction (b) of the floating body.

Accordingly, the unit body 100 and the adjacent unit body 100a are coupled by the bolt 240 and the channel 300, and the convex unit body 110 and the concave unit body 120 are connected to the channel 300. can be combined by (Fig. 7).

The module unit according to the present invention may further include an elastic pad 400 formed on the upper surface of the unit body 100 where the channel 300 is located.

Accordingly, it has an effect of preventing abrasion of the upper surface of the channel 300 and the unit body 100 formed of a metal material, and increasing the bonding force between the channel 300 and the unit body 100.

Hereinafter, a method for manufacturing a floating body according to the present invention will be described.

A manufacturing method of a floating body according to an embodiment of the present invention connects a unit body 100 and a neighboring unit body 100a in the longitudinal direction (a) of the floating body, and also connects the convex unit body 110 and the concave unit body 110 to each other. A first step of continuously arranging the mold unit bodies 120 in the width direction (b) of the floating body (S100) and a second step of coupling the channels 300 to the unit bodies 100 using bolts 240. (S200) may be included.

Since the above has only been described with respect to some of the preferred embodiments that can be implemented by the present invention, as noted, the scope of the present invention should not be construed as being limited to the above embodiments, and the scope of the present invention described above It will be said that the technical idea and the technical idea together with the root are all included in the scope of the present invention.

100: unit body
200: coupling part
300: channel
400: elastic pad

Claims (12)

In the floating body module unit forming a concrete floating body,
A unit body 100 made of lightweight concrete;
Coupling portion 200 for coupling with the neighboring unit body (100a); and
A channel 300 coupled to the coupling part 200 to bind the unit body 100 and the neighboring unit body 100a; includes,
The coupling part 200 is
a protrusion 210 formed on one surface of the unit body 100; and
A depression 220 formed on the other surface of the unit body 100 and into which the protrusion 210a of the neighboring unit body 100a is inserted,
The unit body 100 is
When the convex unit body 110 is convex; and
A concave unit body 120 having a concave lower surface; includes,
The floating body module unit, characterized in that the convex unit body (110) and the concave unit body (120) are coupled alternately in the width direction (b) of the floating body.
According to claim 1,
The coupling part 200 is
A bolt inlet 230 formed on an upper surface of the unit body 100; and
A bolt 240 passed through the through hole 310 formed in the channel 300 and fastened to the bolt inlet 230;
A floating body module unit further comprising.
delete delete According to claim 2,
The floating body module unit, characterized in that the unit body (100) and the adjacent unit body (100a) are coupled in the longitudinal direction (a) of the floating body.
delete According to claim 5,
The floating body module unit, characterized in that the channels (300) are coupled at predetermined intervals along the longitudinal direction (a) of the floating body.
According to claim 7,
The floating body module unit, characterized in that the channel (300) is formed to extend along the width direction (b) of the floating body.
According to claim 8,
The unit body 100 and the neighboring unit body 100a are coupled by the bolt 240 and the channel 300,
The floating module unit, characterized in that the convex unit body (110) and the concave unit body (120) are coupled by the channel (300).
According to claim 9,
An elastic pad 400 formed on the upper surface of the unit body 100 where the channel 300 is located;
A floating body module unit further comprising.
In the manufacturing method of a floating body using the floating body module unit of claim 10,
The unit body 100 and the adjacent unit body 100a are connected in the longitudinal direction (a) of the floating body, and the convex unit body 110 and the concave unit body 120 are connected to each other in the floating body. A first step (S100) of continuously arranging in the width direction (b); and
A second step (S200) of coupling the channel 300 to the unit body 100 using the bolt 240;
A method of manufacturing a floating body, characterized in that it comprises.
In the manufacturing method of the unit body for manufacturing the unit body 100 of claim 1,
Blending lightweight concrete by mixing cement, recycled aggregate, waste Styrofoam, waste plastic, and waste glass bottles (A100);
A method of manufacturing a unit body comprising the.

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