KR101548103B1 - A Multi Armourstone and Breakwater Construction Method thereby - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a covering material used in the construction of a breakwater and a method of constructing a breakwater using the same. The present invention provides, as an embodiment, a structure for use in the installation of a breakwaters, comprising a first part raised on paving stones, a second part extending in an upper part of the first part and having a frustum shape, Is a polygonal flat cross section, each side is a convex curve toward the center of the polygon, and the vertexes formed by the neighboring sides are rounded, and a method of constructing the multi-coating material and the breakwaters using the same is presented.

Description

Technical Field [0001] The present invention relates to a multi-coating material and a breakwater construction method using the multi-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a covering material used in the construction of a breakwater and a method of constructing a breakwater using the same.

Breakwater is a structure that protects ships and ports belonging to the inner harbor by blocking the blue of the outer sea. Artificial harbors usually require a breakwater.

Generally, breakwaters are divided into slopes, uplifts, and mixes. Among them, slopes are subdivided into four types of breakwaters and block type breakwaters.

The construction of widely used sand breakwaters is as follows. First, a sloped basic structure is constructed by using stones, and a clay stone, an intermediate clay stone, and an outermost clay are sequentially stacked thereon.

The cladding is pressed against the outside of the sloped stones to prevent the slabs from escaping. The covering material is selected using a natural stone having an appropriate weight and a substantially flat surface.

The intermediate covering material has a large load, and is intended to provide structural stability by stably pressing below the covering material and to function to resist the wave.

The outermost covering material is directly exposed to the wave to strike the wave, and it functions to increase the soundness and lifespan of the members below the intermediate covering by reducing the wave significantly.

According to this conventional technique, the breakwaters are designed to resist the waves independently in consideration of the damage and flow of the structure to the attacking waves. In the case of the islands such as the west coast of the Republic of Korea, (TTP), which has been installed in the area for a long time, as a result of the design considering the safety factor substantially, it is confirmed that there is almost no damage or flow when compared with the stationary period.

In the breakwaters having the structure according to the conventional art, most of the passage of the intermediate coating material (TRIPOD) or the outermost covering material (TTP) is a static product, and when the static coating material has a proper weight at a certain design wave or less, It is understood that the design wave does not deviate from the place where it is large and is not directly exposed to the typhoon.

In the case where the waves are relatively calm, such as the west coast, there have been problems such as difficulty in construction due to complicated construction processes such as quarrying stone, cladding material, exterior cladding, and cost increase.

Specifically, the natural stone used as the intermediate covering material is required to have a certain shape and size, and it is difficult to secure the required clay stone due to the depletion of the stone resources. This leads to delays in construction and increases in costs. In addition, when the intermediate covering material is applied, the coated stone having a large load must be stacked on the inclined surface in order to be densely stacked, so that the field work speed is slowed and the labor cost is increased according to the labor of the worker.

Korean Patent Registration No.0492257 (2005.05.20) U.S. Patent No. 6,666,620 (December 23, 2003)

The present invention proposes a multi-coating material which can replace conventional clay and intermediate clay. Specifically, the present invention proposes a multi-coating material for improving the structural stability while effectively preventing the outflow of stones.

Other objects and advantages of the present invention will become apparent to those skilled in the art from the following detailed description.

In order to solve the above problems, the present invention provides an apparatus for use in installation of a breakwater, comprising: a first portion to be lifted up to the paving stones; a second portion extending upwardly from the first portion, , The first portion has a polygonal flat section, each side is a convex curve toward the center of the polygon, and the vertexes formed by neighboring sides are rounded.

Here, the bottom surface of the first portion may include a contact surface portion formed along an edge of the bottom surface, and a recess formed by recessing the inside of the contact surface portion.

Furthermore, the cross-section of the first portion may be triangular, and the cross-section of the second portion may be circular. In addition, the weight of the first portion may be at least twice the weight of the second portion.

The present invention also provides a method of constructing a breakwater, comprising the steps of: forming a slag layer having slopes by stacking slag stones; and densely mounting the multi-layer material according to any one of claims 1 to 4 on slopes of the slag layer present.

The step of mounting the multi-coating material may include contacting at least two neighboring multi-coating materials in the first portion.

According to the embodiment of the present invention, it is possible to replace the clay stone and the intermediate clay stone which have been required in the prior art, thereby increasing the convenience of construction, shortening the construction period and reducing the construction cost. In addition, it is possible to minimize the flow of the multi-coating material, thereby preventing breakage of the multi-coating material due to collision due to the flow, and enhancing the structural stability of the breakwater.

The effects of the present invention will be clearly understood and understood by those skilled in the art, either through the specific details described below, or during the course of practicing the present invention.

1 is a schematic perspective view of a multi-coating material according to an embodiment of the present invention;
FIG. 2 is a partial cross-sectional view of the embodiment shown in FIG. 1. FIG.
3 is a cross-sectional view of a first portion employed in the embodiment shown in Fig.
4 is a cross-sectional view taken along line AA of Fig.
Figure 5 is a bottom view of the embodiment shown in Figure 1;
6 is a view sequentially illustrating a method of constructing a breakwater according to an embodiment of the present invention.
7 is a plan view of the multi-coating materials stacked in FIG. 6;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the construction, function and operation of a multi-coating material and a breakwater construction method using the same according to the present invention will be described with reference to the accompanying drawings.

However, 'first part' and 'second part' are terms used to distinguish different components. The term 'vertex' refers to a line or curve that forms the outline of a polygon. The term 'edge' refers to a boundary between a face and a face, and a boundary .

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not to be construed as limiting the technical spirit of the invention. It is to be understood that the invention is not to be limited by any of the details of the description to those skilled in the art from the standpoint of a person skilled in the art that any or all of the drawings shown in the drawings are not necessarily the shape,

1 to 5 are views related to a multi-coating material according to an embodiment of the present invention.

The multi-coating material (10) of the present invention is used for installation of a breakwaters, and is raised in a crowded manner in a stacked stone material. The multi-coating material 10 comprises a first part 1 which is raised on the limestone and a second part 2 which extends upwardly from the first part 1.

The first portion 1 has a substantially polygonal flat section. In the embodiment shown, the cross section of the first part 1 is triangular. However, the cross-sectional shape of the first portion 1 may be a polygon that is closely arranged to form one face, i.e., a square, a hexagon, or the like. In the following description, the flat section of the first section is limited to a triangle.

The first part (1) is laid on the piled mortar and prevents the mortar from being exposed to the outside, thereby preventing leakage of mortar stones by the waves. The bottom of the first part 1 is in direct contact with the limestone, and the bottom is concave except for the edges. The specific shape and function of the bottom surface will be described later.

In FIG. 3, the flat section of the first part is substantially triangular, and each of the vertexes 11 is rounded by a first curvature to form a curve. This reduces the collapse of the vertex portion by collision of the multi-coating materials disposed in close contact with the blue or the like. In addition, when the multi-coating material is densely mounted, the spacing between the multi-coating material and the neighboring multi-coating material can be easily adjusted, thereby enhancing the convenience of mounting the multi-coating material.

In addition, each side 12 of the triangular flat cross section has a convex curve toward the center. The side portion of the first portion 1 corresponding to the side forms a curved surface which is recessed inward by the second curvature.

As shown in Fig. 3, the second radius of curvature is larger than the first radius of curvature.

There is a slight change in shape depending on whether a flat section of a certain height is observed in the entire height of the first portion 1, but the vertex 11 and the side 12, which are rounded at most the height, The shape characteristics of the flat section to be formed are maintained. In particular, the rounded vertex and the shape of the depressed edge are formed over at least a height section in contact with the neighboring multi-coat material.

2, the transverse section through the central axis I and each vertex 11 of the first section 1 includes a first extension E1 which extends outwardly from the central axis I, And a first finishing portion D1 formed at an end of the first extending portion. As shown in the figure, the first extended portion E1 is formed so as to be inclined in a direction in which the upper end gradually decreases as the distance from the center axis increases. The first finished portion D1 is formed so as to be inclined with respect to the center axis I ) In the direction away from the outside. Also, as shown, the cross-sections for the three vertices relative to the central axis coincide.

As also shown in Fig. 4, the AA cross section of Fig. 1 through the central axis I and each side 12 of the first section 1 also has a second extension extending outwardly from the central axis I, (E2) formed at the end of the first extension portion, and a second finishing portion (D2) formed at the end of the second extension portion. As shown in the drawing, the second extended portion E2 is also formed so as to be inclined toward the lower end as the distance from the center axis is gradually decreased. The second finished portion D2 is also formed so as to be inclined with respect to the center axis I ) In the direction away from the outside. 4, all of the transverse sections passing through the arbitrary point of the central axis I and the respective sides 12 of the first part 1 correspond to the shape of the curved surface embedded in the second curvature There is only a difference in degree, but all have a similar structure.

2 and 4, the first extending portion E1 is longer than the second extending portion E2. This is a natural consequence of the shape of the first part 1 which is a shape of a substantial triangle.

The shape of the flat section of the first portion 1 is as shown in Fig. It is important to stably and promptly mount the multiple lacquer materials 10 while minimizing the gap S between the adjacent multiple lacquer materials during the process of densely mounting the plurality of the multi lacquer materials 10 on the plane.

In FIG. 7, one of the multi-coating materials 10 comes into contact with the neighboring multi-coating material 10 at two places due to the recessed sides 12. This two-point contact is mainly made at the connection point B between the vertex 11 and the side 12 forming the curved line or at both ends C of the side 12.

If the sides are formed in a simple straight line, the two faces to be contacted (one side of the first part of the installed multi-coating material and one side of the first part of the multi-coating material to be installed) The degree of difficulty of moving the multi-coating material to be installed laterally is increased. If they can not be aligned in parallel, the neighboring multi-coating materials will come into contact with each other at one point, so that the multi-coating materials installed after the multi-coating material installed at an obtuse angle become unstable.

However, due to the feature of the first part (1) contemplated in the present invention, the contact surfaces of neighboring multi-coat materials are not aligned in parallel, so that they can be contacted at two points of contact, Is advantageous in that convenience of the apparatus is assured.

Referring again to FIGS. 4 to 5, the bottom surface of the first portion 1 is recessed to form a curved surface.

Specifically, the bottom of the first portion 1 is divided into a contact surface portion 13 formed along the periphery of the bottom surface and a concave portion 14 formed by recessing the inside of the contact surface portion.

The contact surface portion 13 is a region divided along the circumference of the bottom surface, and is a portion contacting the ground when a multi-coating material is placed on a flat surface. Although the contact surface portion is shown as being flat in the figure, some protrusions may be formed on the contact surface portion so as to protrude downward.

The concave portion 14 is a depressed portion toward the inside of the multi-coating material 10 except for the contact surface portion 13. In the drawing, the concave portion 14 is shown as one continuous curved surface, but may be depressed at the boundary with the contact surface portion.

By forming the concave portion 14, it becomes possible to increase the force of the multi-coating material 10 pressing the mortar through the contact surface portion 13 having the limited area. That is, the stones having a relatively small volume are strongly pressed against the contact surface portion, so that a part of the contact surface portion is embedded in the dead stone, and the multi-coating material is mounted. As a result, an organic material layer such as a water moss is formed on the surface of the siltstone, so that the multi-coating material does not slip on the surface layer of the siltstone.

If the bottom of the multi-coating material is simply formed as a flat surface, the convenience of fabrication is improved, but the multi-coating material flows from the deadstone due to organic matters such as water moss. The slip flow of the multi-coating material by organic materials or the like is a problem that can occur largely on the sloped surface of the paving stone, and is common to existing coating materials having a substantially flat bottom.

However, in the present invention, the load of the multi-coating material 10 is concentrated on the contact surface portion 13 through the recessed portion 14, so that a high vertical stress can be obtained as compared with other covering materials having the same load. As a result, the above-mentioned problem of slip can be solved.

On the other hand, the second part 2 extends from the upper center in the first part 1, and is in the shape of a roughly anticlockbone.

The second part (2) is integral with the first part (1). The end portion of the second portion 2 is rounded to form a curved surface.

The cross section of the second portion 2 may be circular or polygonal. However, when the cross section of the second portion 2 is circular, the shape contacting the wave can be made constant irrespective of the installation direction of the multi-coating material 10, thereby eliminating the need to consider the installation direction, .

On the other hand, considering the structural stability, the weight of the first part 1 is at least twice the weight of the second part 2. Specifically, it is preferable that the weight of the first part 1 is 2 to 6 times that of the second part 2.

If the weight of the first part 1 is less than twice the weight of the second part 2, the center of gravity of the multi-coating material 10 is formed too high to lower the structural stability of the multi-coating material. That is, there is a possibility that the multi-coating material flows due to strong waves. Particularly when the multi-coating material 10 is provided on a sloped surface, there is a problem that the weight ratio between the first portion 1 and the second portion 2 is easily caused to flow on the slope due to the high center of gravity of less than 2 times do.

On the other hand, when the weight of the first part 1 is set to exceed 6 times the weight of the second part 2, under the condition of producing the multi-coating material using concrete having general strength and specific gravity, The volume of the second part 2 with respect to the first part 1 must be made very small and accordingly the height of the second part 2 must be reduced or the area of the flat section must be made small. As described above, since the second portion 2 having a small volume is low in height, it is difficult to expect the effect of reducing the wave power, or the flat stiffness is reduced, and the structural stiffness is excessively low. However, when the material constituting the multi-coating material, for example, the rigidity of the concrete material is excellent, the weight of the first part 1 may exceed 6 times the weight of the second part 2. [

6 and 7 are views related to a method of constructing a breakwater according to an embodiment of the present invention.

6 (a), 6 (b) and 6 (c) show sequential steps of the method of constructing the breakwaters. The step corresponding to (c) may be omitted.

First, as shown in FIG. 6 (a), the slag stone 31 is stacked to form a slag layer 3 having slopes. At this time, the paving stone 31 to be used may be a volume and a size specified by the law or the like.

6 (b), the multi-coating material 10 of the above-described embodiment is densely mounted on the slag layer 3 including the inclined surface of the slag layer 3.

Wherein each of the neighboring multi-coating materials has at least two contacts in the first portion as the first portion has a flat cross-section with the rounded vertex and curved sides described above.

Figure 7 is a top view of a closely packed multi-coating material. The multi-coating materials (10) are formed to have a small gap (S) between neighboring multi-coating materials by the shape characteristic of the flat section of the first portion. The maximum size (maximum diameter of the void area) of these voids S is formed to be smaller than the minimum diameter of the prescribed paving stone. For example, if the minimum diameter of the paving stone is 25 cm, the maximum size of the pores should be less than 25 cm. The radius of curvature of the rounded vertex and the radius of curvature of the side forming the recessed curved line are limited to a certain range.

If the design wave of the place where the breakwater is installed is proper, the construction of the breakwater can be completed by installing the multi-coating material.

6 (c), the outermost covering material T.T.P, 4 is provided on the multi-coating material 10. The outermost covering material 4 may be a conventional tetrapod or multi-coating material or a combination thereof. When covering the TTP on the multi-coating material 10, one leg of the TTP is sandwiched between the neighboring second portions of the coated multi-coating material, as shown in FIG. 6 (c) You can mount it with the legs facing up. Also, although the outermost covering material in the drawing is mounted as a single layer, it can be mounted in a double layer as required.

By installing the breakwaters using the multi-coating material of the present invention, it is possible to omit the installation of the covering material and the installation of the intermediate covering material, which are required in the prior art. Particularly, by using the multi-coating material having the shape characteristic of the flat cross-section, the multi-coating material can be arranged in a dense arrangement easily, and the first portion of the multi-coating material arranged in a concentrated manner can effectively prevent the leakage of the muffle.

In addition, the multi-coating material is mounted while the bottom surface of the slab layer is partially digged, thereby increasing the bottom friction force and the adhesion force. Thereby increasing the structural integrity of the breakwaters.

10: Multi-coating material
1: first part
11: vertex 12: side 13: contact surface portion 14: concave portion
2: second part
3: slag layer 31: sandstone
4: Outermost covering material
S: Pore

Claims (6)

A multi-coating material comprising a first part (1) having a substantially flat cross-section and a second part (2) extending vertically upwards from the center of the first part (1)
A flat section of each vertex 11 of the first section 1 is rounded and a flat section of each side 12 of the first section 1 is rounded with a radius of curvature larger than the vertex,
The transverse section passing through the central axis I of the first portion 1 and each vertex 11 has a first extending portion E1 extending outwardly from the central axis I and a second extending portion And the first end portion (D1) is formed so as to be inclined in a direction in which the upper end gradually decreases as the distance from the center axis increases, and the first finishing portion (D1) 1 convexly rounded in the direction away from the center axis I of the portion 1,
The cross-sections for three vertices relative to the central axis coincide,
All transverse sections passing through any one point of the central axis I and each side 12 of the first part 1 comprise a second extending part E2 which extends outwardly from the central axis I, And a second finishing portion (D2) formed at an end of the second extending portion (E2), wherein the second extending portion (E2) is formed so as to be inclined in a direction in which the upper end is gradually lowered away from the central axis, The portion D2 is convexly rounded in the direction away from the central axis I of the first portion 1,
The first extending portion E1 is longer than the second extending portion E2,
The bottom surface of the first part (1) is substantially triangular to prevent leakage of stones,
Said second portion (2) having a truncated cone-shaped multi-coating material;
(2) of the prepared multi-coating material is directed upwardly and is mounted on the bottom surface of the first part (1), the three parts of the first part (1) (B, B or C, C) with the side surface of the first part (1) of the neighboring multi-coating material so as to prevent leakage of the stones, And simultaneously implementing a wave dissipation block structure for protecting the object against the object; And
The TTP of the second stage is placed on the upper part of the multi-coating material, wherein one leg of the TTP is sandwiched between the neighboring second portions of the multi-coating material covered in the third step, The method comprising the steps of:
The method according to claim 1,
The bottom surface of the first part (1)
A contact surface portion 13 formed along an edge of the bottom surface,
And a concave portion (14) formed by recessing the inside of the contact surface portion.
The method according to claim 1,
Wherein the flat section of the second portion (2) is circular.
The method according to claim 1,
Wherein the weight of the first part (1) is at least two times to six times that of the second part (2).
delete A breakwater constructed by the method of constructing a breakwater according to any one of claims 1 to 4.

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