KR20140015808A - Protection structure applied to cylindrical module to reduce wave energy - Google Patents

Abstract

The present invention relates to the shape of a revetment structure in a coastal zone, wherein the shape of the revetment structure is to efficiently reduce wave energy. The present invention is to provide the efficient shape of an artificial riprap considering a contact surface between the wave energy and a riprap applied to the revetment structure. A method for installing the artificial riprap is also provided. The most significant feature of the present invention is to provide the shapes of multiple wave energy reduction ripraps reducing the wave energy. In contrast with an ordinary atypical riprap, the artificial riprap of the revetment structure is shaped into a cylinder for efficiently reducing the wave energy because a cylindrical riprap having a large surface area per unit volume can largely reduce the wave energy by a contact between the same and waves. According to the present invention, the revetment structure constructed to protect a harbor or a coastal facility is capable of efficiently relieving the impact energy of the waves continuously rushing thereto, and is capable of being easily installed, maintained, and managed by the method for installing the artificial riprap.

Description

Protection structure applied to cylindrical module to reduce wave energy}

FIELD OF THE INVENTION The present invention relates to coastal zone (i) shore revetment structures. Generally, shoreline structures are built on banks of coastal shores, such as riverbanks, or on slopes such as incisions, to prevent erosion. To reduce efficiently. More specifically, the present invention relates to a revetment structure for efficiently reducing wave energy in coastal revetment structures, the shape of artificial stone applied thereto and the construction of the artificial stone.

Our country is geographically three-sided, and the sea's multipurpose use is emphasized along with economic growth and globalization. In order to keep related facilities safe in the coastal area, it is necessary to secure the stability of the waves. For this purpose, shoreline structures such as breakwaters and breakwaters are used.

In general, coastal areas are damaged by waves and lanyards, which are damaged by sand dunes, earth and sand, coastal structures collapse, gravelized beach erosion, erosion and sediment imbalance. This serious condition has been reached, and coastal coastal coastal structures have been installed to prevent such damage and protect coastal areas. The method of filling the sandstone in the Yeonak revetment structure has also been used conventionally.

On the other hand, recent changes in the strength and direction of waves, lanyards and coastal streams have occurred due to artificial structures such as breakwaters, wave breakers, and coastal roads installed in coastal areas, resulting in unexpected erosion and deposition. The situation is causing serious damage to coastal areas. Therefore, in order to prevent and protect the damage of the coastal area, researches have been made on the coastal coastal revetment structure and the filled sandstone to reduce erosion and sedimentation by installing a permeable layer such as rubble or gabion in the coastal area.

However, a large amount of rubble or sandstone is used to construct a coastal shoreline revetment structure. However, the sandstone used for the existing shoreline revetment structure is empirically applied focusing on the wear characteristics and weathering degree of the material. There is no direct consideration of the reduction of energy.

The present invention is to provide a more efficient artificial stone shape in consideration of the contact surface of the dead stone and the wave energy applied to the revetment structure. In addition, an installation method of the artificial stone is proposed.

The present invention to solve the above problems, the bottom side and the land side vertical side and the sea side hypotenuse and is formed between a plurality of shape maintaining frames and a plurality of shape maintaining frames arranged at regular intervals along the coast Disclosed is an efficient wave energy reducing revetment structure including a plurality of wave energy reducing artificial stones filled in space and efficiently reducing wave energy.

The plurality of wave energy reducing stones that effectively reduce the wave energy, which is the biggest feature of the present invention, are characterized by its shape. Unlike the typical non-standard type of sandstone of the revetment structure, the sandstone is an artificial stone, and is characterized by being cylindrical in order to effectively reduce the wave energy. This is because the shape of the thin but long cylinder has a large surface area per unit volume, resulting in a large energy reduction effect through contact with blue.

In installing the cylindrical seats as described above, the case of installing a cylindrical artificial stone standing in the filling space of the revetment structure and the case of laying down can be assumed. Due to the nature of the blue, it is preferable to install a cylindrical stone stone in the arrangement in consideration of the aspect of reducing energy in the process of repeating the flow into and out of the revetment structure.

When the cylindrical artificial stone is installed upright as described above, it is preferably installed in a plurality of rows at regular intervals, and the cylindrical stone stones disposed in two adjacent rows are preferably arranged in a staggered manner without being disposed in the same column. Since artificial stones are not arranged in line with each other, they are staggered with each other, so that the inflow and outflow of blue waves flow into and out of heat, thereby reducing the energy of the blue waves more effectively.

More specifically, the bottom plate is formed in the bottom of the filling space of the frame for maintaining the shape, the bottom plate is formed with a fixed groove at a predetermined interval, the lower portion of the artificial stone in the fixed groove by the height of the fixed groove. It is fixed may be characterized in that fixed to the filling space between the shape maintaining frame.

The present invention can effectively alleviate the impact energy of blue waves continuously applied to the shoreline structure to protect the harbor or coastal facilities, and easy installation, maintenance and management by suggesting the installation method of artificial stone It can be done.

1 is an overall perspective view of a revetment structure to which the present invention is applied
Figure 2 is an enlarged view of the artificial stone applied the present invention
3 is a perspective view showing various embodiments of the present invention
Figure 4 is a conceptual diagram showing that the inflow / outflow of seawater to the artificial stone to which the present invention is applied

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

In order to reduce the wave energy, it is necessary to increase the contact surface between the shoreline structure and the wave. Therefore, the shaped stone having a larger surface area for the same volume can reduce the wave energy more effectively.

Conventional sandstones are generally used after being collected in nature, and most of them are atypical forms. In order to more effectively reduce the wave energy, the present invention discloses a particular type of artificial stone.

Applicable to artificial stone, tetrahedron, cube, octahedron, dodecahedron, icosahedron, sphere, cylinder, thin plate (thin plate) and the like, and comparing the surface area to unit volume for each of these can be seen that the cylindrical artificial stone has a large value. Table 1 below is a table comparing the surface area for the shape compared to the unit volume.

The plurality of wave energy reducing stones that effectively reduce the wave energy, which is the biggest feature of the present invention, are characterized by its shape. Unlike the typical non-standard shaped stone of the existing shore revetment structure, the stone of the present invention is artificial stone, and in order to reduce the wave energy efficiently, as shown in the above table, it is a cylinder having a wide surface area. It features. This is because the shape of the thin but long cylinder has a large surface area per unit volume, resulting in a large energy reduction effect through contact with blue. Considering the convenience of construction and aggregate used in the pre-fabrication of concrete in application to general revetment structures, the ratio of diameter and depth of the cylindrical artificial stone is preferably 1/18 to 1/22. In this experiment, the ratio was 1/20.

1 and 2 is a view of the cylindrical artificial stone filled in the revetment structure as an embodiment of the present invention. Figure 1 is an overall perspective view of an embodiment of the revetment structure to which the present invention is applied, Figure 2 is an enlarged view of an artificial stone that is an embodiment to which the present invention is applied.

As shown in FIG. 1, a plurality of shoreline structure shape maintaining frames 10 are installed having a bottom side 11, a land side vertical side 12, and a sea side hypotenuse 13 and arranged at regular intervals along the coast. The dead stone is filled in the filling space (S) formed between the plurality of revetment structure shape maintaining frame (10). Although the terms and terms such as the bottom side, the vertical side, or the hypotenuse are used according to the limitations of the drawings and the language, the feature of the present invention is applicable to any type of shoreline structure to which the sandstone is applied, and the description of the present embodiment is simply It is merely a representation of a typical shoreline structure.

In the filling space S, the plurality of wave energy reducing artificial stones 20 for efficiently reducing the wave energy applied to the present invention are disposed. As described above, the artificial stone 20 is cylindrical. The ratio of the diameter (diameter) and the thickness (depth) of the cylindrical artificial stone was applied from 1/18 to 1/22. 2 is an enlarged view of such a cylindrical artificial stone 20.

3 is a perspective view showing various embodiments of the present invention. More specifically, the above-described cylindrical artificial stone 20 may be installed in various forms in the filling space (S), which is a view showing an example. In installing the cylindrical four seats as shown in Figure 3 it can be assumed to install the cylindrical four seats and the case of laying down. Due to the nature of the wave, the arrangement of erecting cylindrical columnar stones is preferred in view of the aspect of reducing energy in the process of repeating the flow into and out of the revetment structure. According to the limitation of the term, the present specification is used in the form of tall or flat, but should be understood to indicate the direction as a whole.

Table 2 calculates the friction area for the same porosity by comparing this cylindrical artificial stone with a conventional atypical stone. Table 3 also shows this graphically. Table 2 and Table 3 are for reference, as can be confirmed through this can confirm that the contact surface of the cylindrical artificial stone is larger than the conventional stone.

4 is a view showing a seawater path of the blue water flowing into and out of the shoreline structure. In the wave energy-reducing shore filled with cylindrical artificial stone, the cylindrical wave energy-reducing artificial stone 20 is installed in a plurality of rows at regular intervals in a horizontal arrangement, and the blue waves are arranged in two adjacent rows. The energy reducing artificial stone is preferably not in the same row but staggered with each other. Since artificial stones are not arranged in line with each other, they are staggered with each other, so when the inflow and outflow of the wave is introduced into and out of the heat, the energy of the wave can be reduced more effectively. That is, as shown in FIG. 4, the contact area between the artificial stone and the seawater can be widened by zigzag the seawater path.

Hereinafter will be described the construction of the shoreline structure to which the plurality of cylindrical artificial stone 20 is applied. A plurality of cylindrical artificial stone 20 can be constructed of concrete integrally with the bottom surface of the raft structure. In addition, the plurality of cylindrical artificial stone 20 may be modularized and manufactured separately from the bottom surface of the gap between the shape-keeping frame, and may be fixed after being separately mounted on the top of the floor.

More specifically, the bottom plate 14 is formed in the lower portion of the filling space (S) formed between the plurality of revetment structure shape maintaining frame 10, the bottom plate 14 is fixed groove at regular intervals 15 is formed, the lower portion of the blue energy reducing artificial stone is fixed to the fixed groove by the height of the fixing groove, the blue energy reducing artificial stone 20 is fixed in the filling space (S) efficient blue Energy-saving revetment can be constructed.

Although the present invention has been shown and described with reference to the preferred embodiments as described above, it is not limited to the above-described embodiments by those of ordinary skill in the art to which the present invention pertains without departing from the spirit and scope of the present invention. Various modifications and variations are possible without departing from the spirit and scope of the appended claims.

The present invention relates to a coastal coastal revetment structure and an artificial stone applied thereto, which can be applied to a seashore structure such as a breakwater and a seawall for securing stability against waves in order to safely maintain related facilities in a coastal area. It is admitted.

10: frame for maintaining the shape of the raft structure
11: base side 12: vertical side
13: seaside hypotenuse 14: bottom plate
15: fixing groove
S: filling space
20: Wave Energy Reducing Artificial Stone

Claims (4)

A frame 10 for maintaining the shape of a plurality of shoreline structures having a base 11, a land side 12, and a sea side 13;
It includes a plurality of blue energy reduction artificial stone 20 to efficiently reduce the blue energy is filled in the filling space (S) formed between the plurality of raft structure shape maintenance frame 10 and the blue energy reduction artificial The dead stone (20) is an efficient wave energy reduction type revetment structure, characterized in that the cylindrical.
The method of claim 1,
The cylindrical wave energy-reducing artificial stone 20 is installed standing in the filling space (S),
Efficient wave energy-reducing shore structure characterized in that it is installed so as to be horizontally arranged vertically in contrast to the direction of the wave.
3. The method of claim 2,
The cylindrical wave energy reduction artificial stone 20 is installed in a plurality of rows at regular intervals in a horizontal arrangement,
Efficient wave energy-reducing revetment structure, characterized in that the wave energy reducing artificial stone disposed in two adjacent rows are arranged alternately without being placed in the same column.
4. The method according to any one of claims 1 to 3,
The bottom plate 14 is formed at the lower portion of the filling space (S) formed between the plurality of revetment structure shape maintaining frame 10,
The bottom plate 14 is formed with a fixing groove 15 at a predetermined interval,
The wave energy reduction artificial stone 20 is fixed to the fixing groove 15, the wave energy reduction artificial stone 20 is an efficient wave energy reduction type relief structure, characterized in that fixed in the filling space (S).

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