KR102767854B1 - Structure of concrete floating body and its construction method - Google Patents

Abstract

The present invention aims to provide a structure of a concrete floating body and a construction method thereof.
That is, the present invention is characterized by including a watertight buoyancy body (10) provided so that the buoyancy material inside is waterproof-protected by an FRP waterproof cover (11); a reinforcing bar (30) installed spaced apart from the outer surface of the watertight buoyancy body (10); an overlay sheet part (40) provided so as to surround a portion of the outer surface of the reinforcing bar (30) and be joined to the outer surface of the watertight buoyancy body (10) in an overlaid state so as to connect the reinforcing bar (30) and the watertight buoyancy body (10); and a concrete layer (50) formed on the outside of the watertight buoyancy body (10) while accommodating the reinforcing bar (30) and the overlay sheet part (40) inside.
By utilizing the structure of the above concrete float and its construction method, the watertight buoyancy body can be protected by the FRP waterproof cover, thereby preventing buoyancy reduction due to water penetration, and the FRP waterproof cover can be used to firmly maintain the integrity between the watertight buoyancy body and reinforcing bars, which are dissimilar materials, thereby effectively suppressing cracking and separation of the concrete layer.

Description

{Structure of concrete floating body and its construction method}

The present invention relates to a structure of a concrete float and a construction method thereof. More specifically, the present invention relates to a structure of a concrete float and a construction method thereof, which can effectively improve the phenomenon of buoyancy reduction due to water penetration by sealing and waterproofing a watertight buoyancy body so that it can be applied to a port or marina where ships are anchored.

Concrete floating bodies, including pontoons, are floating structures that enable the construction of houses, various barges, water bike paths, floating bridges, floating stages, or floating solar power plants on the surface of the sea, river, or lake using objects with a specific gravity lower than that of water.

In addition, concrete floats are widely used to moor a number of small vessels, such as sports or leisure boats or yachts, while allowing people to move around. Here, concrete floats ensure stability because they have less rolling or pitching phenomena due to their own weight.

Looking at the conventional concrete floating body technology, Patent No. 10-1842554 discloses a method of manufacturing a floating body (pontoon) by arranging reinforcing bars in a form that surrounds the outer surface of a foam body and injecting concrete into the outer surface to cure it.

In addition, in another prior art, Patent No. 10-1342579, a fiber concrete pontoon was first registered, which is made of fiber concrete with reinforcing steel bars installed on the inside and filled with a buoyancy material that allows it to float on the water surface in the empty space formed inside.

However, the above-mentioned conventional technologies are technologies that form a buoyancy body inside a concrete structure so that it can float on the water surface, but since the concrete structure is formed of reinforced concrete using steel bars, there is a problem that the integrity between the concrete structure and the buoyancy body is insufficient, so that it easily cracks and separates when flowing in the sea.

In addition, when a concrete structure is damaged, the buoyancy body inside is exposed to water, and when water seeps into the buoyancy body and changes its weight, the concrete structure loses its center and tilts, which is a disadvantage.

KR 10-1842554 B1 KR 10-1342579 B1

The present invention is a new technology created to solve various problems of the above-mentioned conventional technology, and the object of the invention is to provide a structure of a concrete float and a construction method thereof, in which a watertight buoyancy body is protected by an FRP waterproof cover, thereby improving durability and highly improving watertightness, thereby preventing buoyancy reduction due to water penetration.

In addition, the purpose is to provide a structure of a concrete float and a construction method thereof that can effectively suppress cracking and separation of the concrete layer by firmly maintaining the integrity between a watertight buoyancy body and reinforcing bars made of different materials using an FRP waterproof cover.

In order to solve the above-described problem of the present invention, as a specific means, a concrete float is formed, and the watertight buoyancy body (10) is provided so that the buoyancy material inside is waterproof-protected by an FRP waterproof cover (11); a reinforcing bar (30) installed spaced apart from the outer surface of the watertight buoyancy body (10); an overlay sheet part (40) is provided so as to surround a portion of the outer surface of the reinforcing bar (30) and be overlaid, thereby connecting the reinforcing bar (30) and the watertight buoyancy body (10); and a concrete layer (50) formed on the outside of the watertight buoyancy body (10) while accommodating the reinforcing bar (30) and the overlay sheet part (40) inside.

In addition, the overlay sheet part (40) is characterized by including a cover part (41) that wraps downward from the upper part of the reinforcing bar (30), a pair of band parts (42) that extend downward from the cover part (41) and are joined to each other, and a support joint part (43) that is bent transversely at the lower part of the band part (42) and joined to the upper surface of the watertight buoyancy body (10).

In addition, it is characterized in that a plurality of the above watertight buoyancy bodies (10) are spaced apart and arranged in a single float, reinforcing bars (30) are arranged between adjacent watertight buoyancy bodies (10), and an overlay sheet part (40) is installed on the reinforcing bars (30) so that the plurality of watertight buoyancy bodies (10) are mutually connected.

And the method for constructing a concrete float according to the present invention comprises: a watertight coating step (S10) of forming a watertight buoyancy body (10) by covering a buoyancy material with an FRP waterproof cover (11) to form a watertight coating film; a formwork compartment forming step (S20) of forming a formwork compartment (21) so that concrete can be poured by wrapping the watertight buoyancy body (10) at a height higher than the watertight buoyancy body (10) with the upper part open; a watertight buoyancy body arranging step (S30) of arranging the watertight buoyancy body (10) within the formwork compartment (21); a reinforcing bar arrangement step (S40) of constructing reinforcing bars (30) within the formwork compartment (21) so as to be spaced apart from the outer surface of the watertight buoyancy body (10); It is characterized by including an overlay bonding step (S50) of overlaying an overlay sheet portion (30) formed of a glass mat with adhesive applied on a reinforcing bar (20) and bonding and fixing both ends of the overlay sheet portion (30) to the surface of a watertight buoyancy body (10); and a concrete pouring step (S60) of forming a concrete layer (50) by pouring concrete into the formwork compartment (21).

In addition, in the above-mentioned formwork compartment formation step (S20), the formwork frame (23) is installed at a height higher than the watertight buoyancy body (10) so that concrete can be poured on the outside of the watertight buoyancy body (10), and the bottom surface of the formwork compartment (21) is finished with a waterproof sheet (25).

The above watertight buoyancy body (10) is formed as a polyhedron, and the reinforcing bar arrangement step (S30) is characterized in that the reinforcing bars (30) are arranged spaced apart from each other on at least two of the outer surfaces of the watertight buoyancy body (10), and the reinforcing bars (30) are arranged spaced apart from each other in one direction, or arranged to intersect in a grid shape.

According to a specific means for solving the above-described problem, the present invention improves durability by protecting a watertight buoyancy body with an FRP waterproof cover, and also greatly improves watertightness, thereby preventing buoyancy reduction due to water penetration.

In particular, the FRP waterproof cover can effectively suppress cracking and separation of the concrete layer due to fluid loads at sea by firmly maintaining the integrity between the watertight buoyancy body and reinforcing bars, which are dissimilar materials.

Figure 1 is a configuration diagram showing the front and planar states of a floating body having a concrete and FRP joint structure provided by the present invention.
Figure 2 is a configuration diagram showing a watertight buoyancy body of a concrete floating body according to one embodiment of the present invention.
FIG. 3 is a configuration diagram showing an overlay sheet portion of a structure of a concrete floating body according to one embodiment of the present invention.
Fig. 4 is a diagram showing another embodiment of the arrangement of a watertight buoyancy body (10) within a mold frame.
Figure 5 is a flow chart schematically showing a method for constructing a concrete floating body according to one embodiment of the present invention.
Figure 6 is a diagram schematically illustrating a method for constructing a concrete floating body of the present invention.
Figure 7 is a photo used as a drawing showing the reinforcement bar placement stage.

Hereinafter, the present invention will be described in more detail with reference to specific embodiments of the attached drawings. The technical terms used in this specification are terms selected in consideration of functions in the embodiments, and the meanings of the terms may vary depending on specific embodiments of the invention. In addition, throughout the specification, when it is said that a part is "connected" to another part, this includes not only the case where it is "directly connected" but also the case where it is "indirectly connected" with another member in between. In addition, expressions indicating directions such as "up, down, front, back" used in the following description are defined based on the drawings, and the shape and position of each component are not limited by these terms.

FIG. 1 is a configuration diagram showing the front and planar states of a floating body having a concrete and FRP joint structure provided by the present invention, and FIG. 2 is a configuration diagram showing a watertight buoyancy body of a concrete floating body according to one embodiment of the present invention.

The present invention relates to a structure of a concrete float and a construction method thereof, and the structure is improved so that a watertight float is protected by an FRP waterproof cover, and a watertight float and reinforcing bars, which are different materials, are connected at multiple points by an overlay sheet portion via the FRP waterproof cover, so that the different materials can be joined to have integrity, and the watertight float (10), a formwork member (20), reinforcing bars (30), an overlay sheet portion (40), and a concrete layer (50) are included as main components, and each component is described in detail below.

The water-tight buoyancy structure is formed with a buoyancy material (foam block) called EPS (Expanded Polystyrene) that provides buoyancy on the inside, and the water-tight buoyancy body (10) according to the present invention is provided so that its exterior is waterproofed by an FRP waterproof cover (11).

Accordingly, even if seawater penetrates through cracks and damaged areas of the concrete layer (50) described later, a waterproof film is formed to prevent water from seeping into the watertight buoyancy body (10).

As an example, the watertight buoyancy body (10) may be formed by attaching a glass mat with adhesive applied to the outer surface of a foam block (12) formed of expanded polystyrene (EPS) as shown in Fig. 2 (a) to form an FRP waterproof cover (11), or by forming an FRP waterproof cover (11) in a box shape as shown in Fig. 2 (b), accommodating a foam block (12) formed of expanded polystyrene (EPS) inside, and then finishing it with a cover (11a).

In this way, the foam block (12) is protected by the FRP waterproof cover (11), thereby improving durability and preventing contact with seawater, thereby eliminating problems such as a change in center of gravity or an increase in weight that may occur when exposed to water, thereby providing stable functionality as a buoyant body.

The above watertight buoyancy body (10) has a polyhedral structure, but for convenience, it is described in the present invention as having a hexahedral structure.

The formwork member (20) according to the present invention forms a formwork compartment (21) in which the watertight buoyancy body (10) is accommodated and concrete can be poured.

As an example, as illustrated in FIG. 1, the form member (20) may include a form frame (23) formed on the four sides of the front, back, left, and right to form a form compartment (21) at a height higher than a watertight buoyancy body (10), a waterproof sheet (25) that finishes the bottom of the form compartment (21), and a horizontal bolt (24) that is inserted transversely into the form frame (23) to attach a protection belt (22) installed to absorb collision energy of the ship.

The above formwork member (20) is a space where concrete is poured to form a concrete floating body including a floating bridge. The upper part is open, and a reinforcing bar (30) may be provided in the form of a supporting frame in the lower part of the formwork compartment (21) so that a watertight buoyancy body (10) can be accommodated inside in a spaced state.

The reinforcing bar (30) according to the present invention is provided so as to be spaced apart from the outer surface of the watertight buoyancy body (10) within the formwork compartment (21).

The above reinforcing bar (30) can be formed as a metal reinforcing bar or an FRP bar made of synthetic resin material. This reinforcing bar (30) supplements the tensile strength of concrete and is installed to install an overlay sheet part (40) to be described later, and is installed spaced apart from at least two of the six sides (front, rear, left, right, top, bottom) of the watertight buoyancy body (10).

And the reinforcing bars (30) are spaced apart at a predetermined interval within the formwork compartment (21). At this time, the reinforcing bars (30) can be spaced apart in one direction side by side or arranged in a grid shape so as to intersect each other.

Figure 3 is a configuration diagram showing an overlay sheet portion of a structure of a concrete floating body. The overlay sheet portion (40) according to the present invention is provided in a state of overlaying a portion of the outer surface of the reinforcing bar (30) and connected to the bottom surface of the FRP waterproof cover (11) of the watertight buoyancy body (10), thereby connecting the reinforcing bar (30) and the FRP waterproof cover (11).

The above overlay sheet part (40) is formed of a glass mat to which an adhesive is applied, and is provided so that both ends are joined on the FRP waterproof cover (11) in an overlaid state by surrounding a portion of the outer surface of the reinforcing bar (30).

Referring to the enlarged view of Fig. 3, the overlay sheet part (40) includes a cover part (41) that wraps downward from the upper portion of the reinforcing bar (30), a pair of band parts (42) that extend downward from the cover part (41) and are joined to each other, and a support joint part (43) that is bent transversely at the lower portion of the band part (42) and joined to the outer surface of the watertight buoyancy body (10).

The above overlay sheet part (40) is attached so as to overlap in two or more layers, thereby reinforcing the bonding force between the reinforcing bar (30) and the watertight buoyancy body (10).

In this way, since the reinforcing bar (30) and the watertight buoyancy body (10) are connected at multiple points by the overlay sheet portion (40), after pouring the concrete layer (50), the integrity between the concrete layer (50) and the watertight buoyancy body (10) is firmly maintained, so that even when exposed to a flowing load at sea, cracking and separation of the concrete layer (50) can be effectively improved.

The concrete layer (50) according to the present invention is poured into the formwork compartment (21) and formed on the outside of the watertight buoyancy body (10) while containing the reinforcing bar (30) and the overlay sheet portion (40) inside.

When the concrete layer (50) poured in this manner solidifies, it is integrally connected to the watertight buoyancy body (10) by the overlay sheet (40) and reinforcing bars (30), thereby forming a safe and sturdy floating structure.

FIG. 5 is a flow chart schematically showing a method for constructing a concrete floating body according to an embodiment of the present invention, and FIG. 6 is a diagram schematically showing a method for constructing a concrete floating body according to the present invention.

The method for constructing a concrete floating body according to the present invention includes a watertight coating step (S10), a formwork compartment forming step (S20), a watertight buoyancy body arrangement step (S30), a reinforcing bar arrangement step (S40), an overlay bonding step (S50), and a concrete pouring step (S60), and each step is described in detail below.

1. Watertight coating stage (S10)

The watertight coating step (S10) according to the present invention is a step of forming a watertight buoyancy body (10) by forming a watertight coating film to protect against seawater by covering a foam block (12) with an FRP waterproof cover (11).

As an example, the watertight buoyancy body (10) may be formed by attaching a glass mat with adhesive applied to the outer surface of a foam block (12) formed of expanded polystyrene (EPS) as shown in Fig. 2 (a) to form an FRP waterproof cover (11), or by forming an FRP waterproof cover (11) in a box shape as shown in Fig. 2 (b), accommodating a foam block (12) formed of expanded polystyrene (EPS) inside, and then finishing it with a cover (11a).

In this way, the foam block (12) is protected by the FRP waterproof cover (11), preventing damage from external force and preventing contact with seawater even if the external concrete layer (50) is damaged.

2. Forming the mold compartment (S20)

The formwork compartment forming step (S20) according to the present invention is a step of forming a formwork compartment (21) so that concrete can be poured by wrapping the formwork member (20) at a height higher than the watertight buoyancy body (10) with the upper part open.

The above-mentioned formwork member (20) is a member for forming a formwork compartment (21), and uses at least one of metal, wood, and FRP sheets. The formwork member (20) is connected to the watertight buoyancy body (10) so as to maintain its integrity by means of reinforcing bars (30) described below.

3. Watertight buoyancy body (10) placement step (S30)

A watertight buoyancy body (10) is placed within the above-formed mold compartment (21). At this time, the watertight buoyancy bodies (10) may be placed adjacently as shown in Fig. 1, or adjacent watertight buoyancy bodies (10) may be placed so as to be spaced apart from each other as shown in Fig. 4.

In case of spacing, adjacent watertight buoyancy devices (10) can be mutually connected and fastened by arranging reinforcing bars described later and then installing an overlay sheet portion (40).

Meanwhile, in order to form a concrete layer (50) at the bottom of the watertight buoyancy body (10), reinforcing bars (30) can be installed in advance in the form of a support frame on the floor before placing the watertight buoyancy body (10).

4. Reinforcement placement stage (S40)

The reinforcing bar arrangement step (S30) according to the present invention is a step of constructing reinforcing bars (30) so that they are spaced apart from each other in the formwork compartment (21) on at least two of the six sides (front, back, left, right, top, bottom) of the watertight buoyancy body (10).

It can be formed with reinforcing bars, and the reinforcing bars (30) can be arranged in a parallel manner spaced apart in one direction as in Fig. 1, or can be arranged in a grid shape so as to intersect each other as in the construction photograph of Fig. 7.

In addition, in order to space the reinforcing bars (30) apart, a plurality of supports (2) can be installed on the outer surface of the watertight buoyancy body (10) where the reinforcing bars are to be placed, as shown in FIG. 4, and the reinforcing bars (30) can be tied to the supports (2).

5. Overlay bonding step (S50)

The overlay bonding step (S40) according to the present invention is a step of overlaying the above-described overlay sheet part (30) formed with a glass mat to which an adhesive has been applied on a reinforcing bar (20), and bonding and fixing both ends of the overlay sheet part (30) to the surface of a watertight buoyancy body (10).

The above overlay sheet part (40) is formed of a glass mat to which an adhesive is applied, and is provided so that both ends are joined on the FRP waterproof cover (11) in an overlaid state by surrounding a portion of the outer surface of the reinforcing bar (30).

Referring to Fig. 4, an overlay sheet part (30) is constructed on reinforcing bars (30) spaced apart from each other on the upper and left and right sides of a watertight buoyancy body (10), so that the watertight buoyancy body (10) and the concrete layer (50) are integrally connected over at least three sides.

In this way, since the reinforcing bar (30) and the watertight buoyancy body (10) are connected at multiple points by the overlay sheet portion (40), after pouring the concrete layer (50), the integrity between the reinforcing bar (30), the concrete layer (50), and the watertight buoyancy body (10) is firmly maintained, and thus, even when exposed to a long-term fluid load at sea, the bonding strength with the concrete layer (50) can be stably maintained.

6. Concrete pouring stage (S60)

The concrete pouring step (S50) according to the present invention is a step of pouring concrete into the formwork compartment (21) to form a concrete layer (50).

Since the concrete is poured while the reinforcing bar (30) and the watertight buoyancy body (10) are bonded by the above overlay sheet portion (40), the concrete layer (50) is formed, so that the integrity between the watertight buoyancy body (10), the formwork member (20), the reinforcing bar (30), and the concrete layer (50) which are made of different materials is improved, so that the phenomenon of the concrete layer (50) being separated by an external force can be eliminated, and the concrete layer (40) and the watertight buoyancy body (10) are bonded integrally.

After pouring, the concrete is cured and the formwork member (20) is removed, thereby completing the concrete floating body according to the present invention.

As described above, the detailed description of the present invention has described the most preferred embodiment of the present invention, but various modifications may be made within the scope that does not depart from the technical scope of the present invention. Therefore, the protection scope of the present invention should not be limited to the above-described embodiment, but should be recognized as the protection scope extending to the technologies of the patent claims described below and equivalent technical means from these technologies.

10: Watertight buoyancy body
11: FRP waterproof cover 11a: Cover 12: Foam block
20: Formwork
21: Formwork compartment 22: Guardrail 23: Formwork frame
24: Horizontal bolt 25: Waterproof sheet
30: Reinforcement
40: Overlay sheet part
41: Cover part 42: Band part 43: Support joint part
50: Concrete layer

Claims (7)

In the structure of a concrete floating body in which a plurality of watertight buoyancy bodies (10) are spaced apart and provided with waterproof protection of the buoyancy material inside by an FRP waterproof cover (11),
Reinforcing bars (30) installed spaced apart on at least two of the six sides of a watertight buoyancy body (10) and also arranged between adjacent watertight buoyancy bodies (10);
An overlay sheet part (40) formed with a glass mat coated with adhesive and connected to the outer surface of a watertight buoyancy body (10) in an overlaid state by surrounding a portion of the outer surface of the reinforcing bar (30) to connect the reinforcing bar (30) and the watertight buoyancy body (10); and
Includes a concrete layer (50) formed on the outside of a watertight buoyancy body (10) with the reinforcing bar (30) and the overlay sheet portion (40) accommodated inside;
The above overlay sheet part (40) is
A cover part (41) that wraps downward from the upper part of the reinforcing bar (30),
A pair of band parts (42) extending downward from the cover part (41) and connected to each other,
A structure of a concrete floating body characterized by including a support joint (43) that is bent transversely at the lower part of a band portion (42) and joined to the upper surface of a watertight buoyancy body (10).
delete delete A watertight coating step (S10) for forming a watertight buoyancy body (10) by covering the buoyancy material with an FRP waterproof cover (11) to form a watertight coating film;
A formwork compartment formation step (S20) for forming a formwork compartment (21) so that concrete can be poured by wrapping the watertight buoyancy body (10) at a height higher than the watertight buoyancy body (10) with the upper part open;
A step (S30) of arranging watertight buoyancy bodies (10) so that they are spaced apart from each other within a mold compartment (21);
A reinforcing bar arrangement step (S40) in which reinforcing bars (30) are installed between adjacent watertight buoyancy bodies (10) while being spaced apart from at least two of the six sides of the watertight buoyancy bodies (10) within the formwork compartment (21);
An overlay sheet part (40) formed by a glass mat with adhesive applied is overlaid on a reinforcing bar (30) and both ends of the overlay sheet part (40) are bonded and fixed to the surface of a watertight buoyancy body (10) in an overlay bonding step (S50); and
Includes a concrete pouring step (S60) of pouring concrete into the above-mentioned formwork compartment (21) to form a concrete layer (50);
The above overlay sheet part (40) is
A cover part (41) that wraps downward from the upper part of the reinforcing bar (30),
A pair of band parts (42) extending downward from the cover part (41) and connected to each other,
It is formed to consist of a support joint (43) that is bent transversely at the lower part of the band (42) and joined to the upper surface of the watertight buoyancy body (10).
In the above mold compartment formation step (S20),
A method for constructing a concrete floating body, characterized in that a formwork frame (23) is installed at a higher height than a watertight buoyancy body (10) so that concrete can be poured on the outside of the watertight buoyancy body (10), and the bottom surface of the formwork compartment (21) is finished with a waterproof sheet (25).
delete delete delete