KR102591460B1 - Concrete float with wave power damping hole - Google Patents

Abstract

The present invention provides a concrete floating body with wave attenuation holes that prevents damage to the floating body by absorbing energy by guiding wave force into the water and suppresses pitching phenomenon by the reaction.
For this purpose, the present invention is a concrete body floating on the water surface, an inlet hole formed on the side of the concrete body, an outlet hole formed on the bottom of the concrete body, and a guideway is formed between the inlet hole and the outlet hole to prevent waves hitting the side of the concrete body. It consists of a concrete floating body equipped with a wave attenuation hole that absorbs wave force by receiving water through the inlet hole and guiding it into the water through the outlet hole.
According to the above configuration, damage to the outer wall or joint of the floating body can be prevented and maintenance of the floating body is easy due to increased durability.

Description

Concrete float with wave damping hole {CONCRETE FLOAT WITH WAVE POWER DAMPING HOLE}

The present invention relates to a concrete floating body with a wave attenuation hole, and more specifically, to prevent damage to the concrete floating body by absorbing energy by guiding wave force into the water and to suppress the pitching phenomenon by the reaction. It relates to a concrete floating body with one wave attenuation hole.

In recent years, as the need for alternative spaces has increased due to restrictions on the use of land space, artificial grounds using concrete floating bodies are being built at sea.

A concrete floating body is a rectangular concrete structure with an empty interior. A sealed buoyancy space can be provided inside to ensure buoyancy so that it can safely float on the sea, or it can be filled with buoyancy material to minimize weight gain even if water seeps in. there is.

Such concrete floating bodies are used in a variety of ways, such as offshore plants, marine parks, docking facilities, floating piers, and pontoons.

Registration Patent No. 10-0977015 (announced on August 19, 2010) discloses a floating concrete body and a floating assembly using the same.

Registered Patent No. 10-1851933 (announced on April 25, 2018) discloses a concrete floating body.

Registration Patent No. 10-1092348 (announced on December 9, 2011) discloses a high-strength concrete floating body.

Meanwhile, the concrete floating body 100 is subject to various environmental external forces such as wind, waves, and currents, of which the floating body may be damaged or pitching may occur due to waves as the main environmental external force (see Figure 1).

For example, as wave force acts on the side of a concrete floating body, damage may occur at the outer wall or joint of the floating body, and a pitching phenomenon may occur where the floating body shakes back and forth, which may impair the stability of users and moored vessels.

The present invention was developed to solve the above-mentioned problems. It prevents damage to the floating body by absorbing energy by guiding wave force into the water and suppresses the pitching phenomenon by the reaction, thereby improving the stability of users and moored vessels. The goal is to provide a concrete floating body with a wave attenuation hole that can

In addition, the present invention seeks to provide a concrete floating body with a wave attenuation hole that is easy to maintain and manage performance by preventing aquatic life from sticking to the taxiway just by the inflow of inflow water.

In order to solve the above problems, the present invention provides a concrete body floating on the water surface, an inlet hole formed on one side of the concrete body, an outlet hole formed on the other side of the concrete body and located lower than the inlet hole, and an inlet hole formed between the inlet hole and the outlet hole. A furnace is formed to absorb the waves hitting the concrete body through the inlet hole and guide them underwater through the outlet hole to absorb the wave force.

The above inlet hole is partially submerged in the water surface or is located higher than the water surface.

The outlet hole is formed on the bottom between the central axis of the concrete body and the rear end of the concrete body.

The above-mentioned induction passage is configured to be equipped with a coil scraper, one end of which is tied to the inlet hole and moves back and forth along the inner wall of the induction passage by the inflow water to prevent the attachment of aquatic organisms.

In addition, the above-described induction path is configured to have a downward bending portion formed between the inlet hole and the outlet hole so that the inflow water has drop energy.

According to the present invention, by absorbing energy by guiding wave force into the water through an induction furnace, damage to the outer wall or joint of the floating body can be prevented, and maintenance of the floating body is easy by increasing durability.

In addition, the present invention has the effect of suppressing the pitching phenomenon due to the reaction when wave power is guided into the water through a taxiway, thereby ensuring the stability of users and moored vessels.

In addition, as the coil scraper is installed within the taxiway, the inflow of influent water prevents aquatic organisms from sticking to the taxiway, making performance maintenance and management easier.

1 is an illustration for explaining the background technology of the present invention;
Figure 2 is an illustration showing the structure of a concrete floating body with a wave attenuation hole according to the present invention,
Figure 3 is a cross-sectional view showing the structure of a concrete floating body with a wave attenuation hole according to the present invention;
Figure 4 is an illustration of a coil scraper installed on a concrete floating body equipped with a wave attenuation hole according to the present invention;
Figure 5 is an illustration of a coil scraper installed on a concrete floating body equipped with a wave attenuation hole according to the present invention;
Figure 6 is another cross-sectional view showing the structure of a concrete floating body with a wave attenuation hole according to the present invention;
Figure 7 is another cross-sectional view showing the structure of a concrete floating body with a wave attenuation hole according to the present invention.

Terms or words used in this specification and claims should not be construed as limited to their common or dictionary meanings, and the inventor may appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

Therefore, since the configuration described in this specification is only one of the most preferred embodiments of the present invention and does not represent the entire technical idea of the present invention, various equivalents and modifications that can replace them are available at the time of filing this application. You must understand that it can happen.

Hereinafter, a preferred embodiment of a concrete floating body with a wave attenuation hole according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to Figure 2, the embodiment according to the present invention includes a concrete body 100 floating on the water, an inlet hole 10 formed on one side of the concrete body 100, and an inflow hole formed on the other side of the concrete body 100. An outlet hole (20) located lower than the ball (10) and a guideway (30) are formed between the inlet hole (10) and the outlet hole (20) to direct waves hitting the concrete body (100) into the inlet hole (10). It consists of a concrete floating body that absorbs wave force by receiving the inflow into the water through the outlet hole (20).

In the above configuration, the concrete body 100 is a concrete structure with an empty interior, and a sealed buoyancy space is installed therein so that it can float on the water surface.

Therefore, part of the concrete body 100 is submerged below the water surface and the rest is exposed above the water surface and is affected by waves.

Of course, the present invention does not specifically limit the material, shape, or structure of the main body 100.

In addition, one side of the concrete body 100 is defined as the side where waves hit, and the other side refers to the remaining side excluding one side.

For example, assuming that the concrete body 100 is a hexahedron and a wave hits the front, the other side of the concrete body 100 may be any one of the back, left, right, and bottom sides of the body.

The upper surface of the concrete body 100 is excluded from the other side because the outlet hole 20 must be formed at a lower position than the inlet hole 10.

According to the above configuration, when a wave hits one side of the concrete body 100, some of it flows into the concrete body 100 through the inlet hole 10, and the inflow water flows into the concrete body 100 along the guideway 30. It is guided into the water through the outflow hole 20 formed on the bottom and the energy is dissipated.

That is, wave force is induced into the water through a wave attenuation hole formed in the concrete body 100 and composed of an inlet hole 10, an induction path 30, and an outlet hole 20, and the energy is attenuated (absorbed). ), it is possible to prevent damage to the outer wall of the concrete body 100 or the connection portion for connecting the main body 100 to each other due to wave force.

Here, the induction path 30 may be formed integrally with the inner wall, etc. when manufacturing the concrete body 100, or may be made of a synthetic resin pipe or metal pipe and installed within the concrete body 100.

Next, the inlet hole 10 is configured to be partially submerged in the water surface or positioned higher than the water surface.

Therefore, waves hitting one side of the concrete body 100 can be easily introduced through the inlet hole 10 and guided underwater as described above to absorb wave power.

Next, referring to FIG. 3, the outlet hole 20 is formed on the bottom between the central axis of the concrete body 100 and the rear end of the concrete body 100.

According to the above configuration, when waves continuously hit one side of the concrete body 100, a pitching phenomenon occurs in which the concrete body 100 shakes back and forth, and the outflow hole 20 is connected to the central axis of the concrete body 100. (100) By being located on the bottom between the rear ends, a force acts upward from the rear of the concrete body 100 in reaction to the discharge pressure of the inflow water discharged through the outlet hole 20, thereby suppressing the pitching phenomenon.

Next, referring to 4 and 5, one end of the induction passage 30 is bound to the inlet hole 10 and moves back and forth along the inner wall of the induction passage 30 by the inflow water to prevent the attachment of aquatic organisms. A coil scraper 40 is configured.

The concrete body 100 is implemented to be able to float on the sea, with part of it exposed above the water and the rest submerged in the water.

Therefore, aquatic organisms such as barnacles, clams, and mussels adhere to the surface of the concrete body 100, and aquatic organisms also adhere to the guideway 30.

In this case, the width of the taxiway 30 narrows and friction increases, which has the effect of reducing the inflow amount and slowing the flow rate, thereby reducing the ability to absorb wave force.

According to the above configuration, the coil scraper 40 is preferably implemented as a spirally wound spring member.

For example, one end of the coil scraper 40 is bound to the inlet hole 10 and the other end is an unrestricted free end, so that it expands and contracts toward the outlet hole 20 according to the flow of inflow water. Preferably, the other end of the coil scraper 40 may be extended to the outside of the outlet hole 20.

In another example, one end of the coil scraper 40 is bound to the inlet hole 10 side and the other end is bound to the outlet hole 20 side, so that the coil gap (pitch) between both ends of the coil scraper 40 is determined according to the flow of inflow water. ) contracts and expands.

Therefore, the coil scraper 40 extends along the inflow water introduced into the induction path 30 and scratches the inner wall of the induction path 30, and when the flow rate of the inflow water slows, it contracts due to elastic force and scrapes the inner wall of the induction path 30 in the opposite direction. gets scratched.

That is, the coil scraper 40 can prevent aquatic organisms from sticking to the induction passage 30 by repeatedly scraping the inner wall of the induction passage 30 due to the inflow of inflow water. Of course, the inner wall of the induction furnace 30 may be coated with paint to prevent attachment of aquatic organisms.

In addition, the induction path 30 is manufactured in various shapes within the concrete body 100 so that the inflow water has drop energy. The basic configuration includes an inflow hole 10 and an outlet hole having height differences as described above. It is formed between (20).

In detail, as shown in FIG. 6, when the inlet hole 10 is formed on the front of the concrete body 100 where the waves hit, and the outlet hole 20 is formed on the back of the body, the guideway 30 is the inlet hole. It may be installed at a downward slope between the inlet hole 10 and the outlet hole 20 so that the influent water flowing into (10) can be discharged to the outside of the concrete body 100.

On the other hand, referring to FIGS. 3 and 7, the induction path 30 is designed so that the inflow water has drop energy between the inflow hole 10 and the outlet hole 20 when the inflow water passes through the concrete body 100 and is discharged to the outside. A downward bending portion 31 may be further formed.

That is, in the present invention, the waves hitting the concrete body 100 are introduced into the wave attenuation hole, for example, the inlet hole 10, and are guided to the outside of the concrete body 100 through the induction path 30 and the outlet hole 20. The energy generated by the wave force is absorbed into the water without floating around within the concrete body 100, preventing damage to the floating body and suppressing the pitching phenomenon through the reaction.

The above description is an embodiment of the present invention and does not limit the present invention, and various modifications may be made within the scope of the claims.

10: Inlet hole
20: Outflow hole
30: Taxiway
31: downward bending part
40: Coil scraper
100: concrete body

Claims (5)

A concrete body designed to float on the water,
An inlet hole formed on one side of the concrete body,
An outlet hole formed on the other side of the concrete body and located lower than the inlet hole,
A guideway formed between the inlet hole and the outlet hole for receiving waves hitting the concrete body into the inlet hole and guiding them into the water through the outlet hole to absorb the wave force,
A concrete floating body with a wave attenuation hole, which is embedded in the guideway and is extended by the inflow of water flowing into the guideway, and is provided with a coil scraper to prevent the attachment of aquatic organisms by scraping the inner wall of the guideway. . According to clause 1,
A concrete floating body with a wave attenuation hole, wherein the inlet hole is partially submerged in the water surface or located higher than the water surface. According to clause 1,
The outflow hole is a concrete floating body with a wave attenuation hole, characterized in that the outlet hole is formed on the bottom surface between the central axis of the concrete body and the rear end of the concrete body. According to clause 1,
The coil scraper is wound in a spiral shape, one end is bound to the inlet hole, and is extended by the inflow water flowing into the guideway, and is provided with a wave attenuation hole, characterized in that it is installed to be movable back and forth along the inner wall of the guideway. Concrete floating body. According to clause 1,
The induction path is a concrete floating body with a wave attenuation hole, characterized in that a downward bending portion is formed between the inlet hole and the outlet hole so that the inflow water has drop energy.