KR102010119B1 - Breakwater Structure - Google Patents

Abstract

A breakwater structure is disclosed. In the breakwater structure according to the present invention, the breakwater structure is a breakwater structure that minimizes the influence of the wave energy of the outer sea side on the inland sea side. ; A unit plane in which a plurality of unit structures are arranged in a horizontal and vertical direction on a plane, the unit planes formed by connecting each of the arranged unit structures to each other; And a breakwater wall formed by stacking a plurality of unit planes.

Description

Breakwater Structure

The present invention relates to a breakwater structure, and more particularly, to reduce the cost of constructing a breakwater, to stably reduce waves and waves, and to reduce the time of the breakwater construction process by reducing the time required to work underwater. To breakwater structures.

In general, breakwaters are almost essential to ports and coasts, and they are installed in various forms and construction methods.

In the early days, breakwaters were installed at a height that could prevent some high waves, so that the sections where the breakwaters were installed were blocked by the inland and the open seas. However, the construction of the breakwater in the form of confining the sea water, so that the inflow and outflow of the sea water is not made smoothly, the sea water of the inland sea is contaminated, and various kinds of dirt accumulate, severe odor is generated. It is no exaggeration to say that this would completely destroy the tidal flats and seabed ecosystems on the Inland Sea.

Moreover, the above-mentioned breakwater has a great repulsion force in the seawater hit by the breakwater, and the seawater coming in succession is combined to hit the breakwater with more energy, and as a result, when the digging becomes higher and deeper, the breakwater goes into the inland sea. have.

To remedy this problem, various structures of breakwaters have been proposed to allow seawater to be distributed. One of them is a breakwater using the "unit block for building breakwater" of Korean Patent No. 770238.

1 shows a schematic front view of a breakwater constructed using a unit block for building a breakwater according to the prior art.

Referring to FIG. 1, the unit block is connected to the upper plate 10 and the lower plate 20 by a plurality of pillars 30 to form a single body, and is coupled to the upper and lower surfaces of the upper plate 10 and the lower plate 20. The pit 15 and the pit 25 for the is formed.

The breakwater is first laminated on the frame 50 in which the bite jaw 55 protrudes such that the bite groove 25 of the plurality of unit blocks is engaged with the bite jaw 15 of the frame 50. The plurality of unit blocks are secondary so that the respective bite jaws 15 and the bite grooves 25 of the plurality of unit blocks that are stacked on the first unit block are engaged with each other so as to deviate from each other. In this manner, a plurality of unit blocks are vertically stacked in this manner. As a result, the breakwater facilitates the communication of birds through the space between the pillars of the respective unit blocks.

However, the breakwater structure as described above is required to stack a plurality of unit blocks made of reinforcement, concrete, etc. from the bottom of the sea floor to a set height above the sea level, so that a large number of unit blocks are required. Since it is necessary to go through the process of stacking, there is a problem in that the construction of the breakwater structure is quite difficult, and the time and cost of the construction process are also considerable.

Patent Registration No. 10-0770238 (published date: 2006.11.06)

The present invention has been devised to solve the above problems, it can reduce the breakwater construction cost, can stably reduce the waves and waves, and also reduce the time of the breakwater construction process by reducing the time to work underwater It is an object to provide a breakwater structure that can be.

Breakwater structure according to an aspect of the present invention for achieving the above object, in the breakwater structure to minimize the impact of the wave energy of the sea side on the sea side, any object more than the weight set in the waste tire of a set size Unit structure formed by filling the; A unit plane in which a plurality of unit structures are arranged in a horizontal and vertical direction on a plane, the unit planes formed by connecting each of the arranged unit structures to each other; And a breakwater wall formed by stacking a plurality of unit planes.

The above-described breakwater structure is erected through the unit structures arranged in the vertical direction with respect to the plurality of unit planes stacked in the vertical direction, and forms at least one gap between the unit structures penetrated in the vertical direction or more. It may further include a stacked structure pillar.

The above-described breakwater structure may further include a gap support column installed between the unit structures having a gap among the plurality of unit structures penetrated in a row on the structure stack pillar to support the gap.

The breakwater structure described above may further include a cover plate covering the unit plane stacked on the top layer of the breakwater wall.

The breakwater structure described above may further include a deformation plane formed by arranging a plurality of unit structures at intervals of at least one unit structure in a horizontal direction and a vertical direction, and connecting the arranged unit structures to each other. . In this case, the breakwater wall is formed by stacking a plurality of unit planes and a deformation plane.

Breakwater structure according to another aspect of the present invention for achieving the above object, in the breakwater structure to minimize the impact of the wave energy of the sea side on the sea side, any object more than the weight set in the waste tire of the set size Unit structure formed by filling the; A unit plane in which a plurality of unit structures are arranged in a horizontal and vertical direction on a plane, the unit planes formed by connecting each of the arranged unit structures to each other; And breakwater walls erecting a plurality of unit planes in a vertical direction and connecting the plurality of unit planes erected to each other.

The above-described breakwater structure penetrates the unit structures arranged in a horizontal direction so that their centers coincide with respect to a plurality of unit planes forming the breakwater wall, and the plurality of breakwater structures form at least one gap greater than a predetermined interval between the penetrating unit structures. Structure through rods; And a frame supporting each of the structure through rods.

Breakwater structure according to another aspect of the present invention for achieving the above object, in the breakwater structure to minimize the effect of the wave energy of the sea side on the inshore side, any of more than the weight set in the waste tire of the set size A unit structure formed by filling an object; A unit plane in which a plurality of unit structures are arranged in a horizontal and vertical direction on a plane, the unit planes formed by connecting each of the arranged unit structures to each other; And a breakwater wall formed by stacking a plurality of unit planes, wherein a center of an arbitrary unit structure is stacked at a common center of a plurality of unit structures adjacent to each other.

The breakwater structure described above may further include a stacking frame supporting a stack structure of each unit plane forming the breakwater wall.

The above-described breakwater structure may further include a structure stacking column which is erected through the unit structures arranged in the vertical direction and forms a gap having a predetermined interval or more between the unit structures penetrated in the vertical direction.

The above-described breakwater structure may further include a gap support pillar installed between each unit structure disposed in the vertical direction to support the gap.

The above-mentioned breakwater structure may include a plurality of insertion pillars having a lower end inserted into a lower portion perpendicular to the bottom of the seabed and penetrating at least one unit structure through the upper portion protruding from the seabed; And a base support formed of a set of unit structures penetrated by the plurality of insertion pillars, and forming a plane on the upper surface by adjusting the number of unit structures penetrated through the respective insertion pillars. In this case, the breakwater wall is formed on the foundation support.

The above-described breakwater structure, is installed on the seabed topography, and may further include a base ground formed flat on the upper surface. In this case, the breakwater wall is formed on the foundation ground.

According to the present invention, by constructing the breakwater structure using the waste tire, it is possible to greatly reduce the cost required for the breakwater construction.

In addition, according to the present invention, by constructing a breakwater structure using waste tires, it is possible not only to efficiently attenuate wave pressure and waves from the sea side to the sea side, but also to free the inflow of seawater between the sea side and the sea side. Thus, seawater can be prevented from being contaminated.

In addition, according to the present invention, after forming the blocks by connecting the waste tires in groups on the land, since the breakwater structure can be prefabricated, it is possible to reduce the process to work in the water, the time of the breakwater construction process Can also be greatly reduced.

1 is a view showing a breakwater structure constructed using a unit block for building a breakwater according to the prior art.
2 is a view showing a breakwater structure according to an embodiment of the present invention.
3 is a view showing an example of a unit structure constituting the breakwater structure shown in FIG.
4 is a view showing an example of a unit plane constituting the breakwater structure shown in FIG.
FIG. 5 is a diagram illustrating an example of a structure stack pillar that penetrates the unit structure in a vertical direction and forms a gap between the unit structures.
6 is a view showing a breakwater structure according to another embodiment of the present invention.
7 is a diagram illustrating an example of a deformation plane used for the breakwater structure of FIG. 6.
8 is a view showing another example of the deformation plane used in the breakwater structure of FIG.
9 is a view showing a breakwater structure according to another embodiment of the present invention.
10 is a view showing a breakwater structure according to another embodiment of the present invention.
FIG. 11 is a diagram illustrating an example of stacking unit structures to form a breakwater wall of the breakwater structure of FIG. 10.
12 is a view illustrating an example of a laminated structure of the breakwater structure shown in FIG. 10.
FIG. 13 is a view for explaining another example of the laminated structure of the breakwater structure shown in FIG. 10.
14 is a view for explaining a method of forming a plane on the seabed terrain.

Hereinafter, with reference to the accompanying drawings will be described in detail the breakwater structure according to an embodiment of the present invention.

Figure 2 is a view showing a breakwater structure according to an embodiment of the present invention, Figure 3 is a view showing an example of the unit structure constituting the breakwater structure shown in Figure 2, Figure 4 constitutes a breakwater structure shown in Figure 2 It is a figure which shows the example of the unit plane.

2 to 4, the breakwater structure 100 according to the embodiment of the present invention includes a plurality of unit structures 110, a plurality of unit planes 111, a breakwater wall 113, and a stacked structure pillar 120. , Cover plate 130, gap support pillar 140, and base ground 150 may be included.

The unit structure 110 is formed by filling an object having a weight or more set inside the waste tire of a set size. At this time, the unit structure 110 is preferably to use the waste tires of the same size, the object to be filled in the waste tire is preferably set to a weight enough to sink the unit structure 110 to the seabed. Do. For example, as shown in FIG. 3, the unit structure 110 may fill an object 112 such as cement or reinforcing into a waste tire for a passenger car, and prevent the object from popping out. In this case, the unit structure 110 may reduce the cost by filling the construction waste inside the waste tire, it is preferable that the exterior is finished with cement, glue, bond, etc. to prevent the object filled inside. .

The unit plane 111 arranges the plurality of unit structures 110 in the horizontal and vertical directions on a plane, and is formed by connecting the unit structures 110 arranged to each other. In this case, as shown in FIG. 4, the unit planes 110 are arranged in the horizontal and vertical directions by separating each unit structure 110 at a predetermined interval, and connecting rods 114 between the unit structures 110. It can be formed by connecting. That is, the unit structures 110 adjacent to each other in the horizontal and vertical directions are connected to each other by the connecting rod 114, respectively. In addition, a plurality of grooves 116 may be formed in the upper and lower surfaces of each unit structure 110 constituting the unit plane 111. In this case, although shown and described as a plurality of grooves 116 are formed on the upper and lower surfaces of each unit structure 110, the grooves 116 are also formed on each side connected to the connecting rod 114, , It is preferable to insert and fix one end of the connecting rod 114 to each groove 116.

The unit plane 111 may be stacked in a vertical direction in a set number to form a unit plane group. In addition, the forming work of the unit plane 111, the unit plane group and the like can be carried out on land, the process of working underwater because the breakwater structure can be built in units of the formed unit plane 111 or unit plane group It also reduces the time required for the breakwater construction process.

The breakwater wall 113 is formed by stacking a plurality of unit planes 111. In this case, it is preferable that a gap having a set height is formed between at least two or more unit planes 111 among the plurality of unit planes 111 stacked. In this case, the gap between the stacked unit plane 111 and the unit plane 111 may be formed by the structure stack pillar 120.

The structure stacking column 120 is erected through the centers of the plurality of unit structures 110 arranged in the vertical direction with respect to the plurality of unit planes 111 stacked in the vertical direction, and the unit structures penetrated in the vertical direction ( At least one gap is formed between the set intervals 110 or more. In this case, the structure stack pillar 120 is provided in plural and forms a gap between the plurality of unit planes 111 that are stacked in plural to form the breakwater wall 113. That is, as shown in FIG. 5, the structure stack pillar 120 penetrates the plurality of unit structures 110 in a vertical direction and has a gap support pillar in the groove 116 of the unit structure 110 positioned in the vertical direction. A gap may be formed between the unit structures 110 in the vertical direction by installing the 140. At this time, the plurality of gap support pillars 140 are erected between the unit structure 110 in the vertical direction, each of the gap support pillars 140 is preferably set to the same length. Here, although the gap support column 140 is illustrated and described as being installed between each unit structure 110, the gap support column 140 is a unit group by adhering a plurality of unit structures 110 in a vertical direction. After forming a may be installed between the unit group and the unit group.

On the other hand, in the embodiment of the present invention, although the structure laminated column 120 is shown and described as forming a gap by installing the gap support pillar 140 between the unit structure 110 penetrating in the vertical direction, structure laminated column 120 is installed through the set number of unit structures 110, the locking member (not shown) is installed on the upper side, and the unit structure penetrated by passing through the set number of unit structures 110 again on the locking member A gap may be formed between the 110. In this case, the shape of the locking member may be any shape as long as it is a structure capable of supporting the unit structure 110.

Here, the structure stack pillar 120 is preferably made of reinforcement, concrete, or the like of a predetermined strength or more to vertically support the plurality of unit structures 110 to be penetrated and to withstand wave energy of the wave energy.

The cover plate 130 covers the upper ends of the plurality of structural stacked columns 120 and the uppermost unit structures 110 of the unit structures 110 penetrated through the respective structural stacked columns 120. In this case, the cover plate 130 may cover the upper end of each of the plurality of stacked structure pillars 120 and each unit structure 110, and may be made of a concrete material so that a person or a vehicle may pass through the upper surface thereof. However, the cover plate 130 is not limited to the described materials, and of course, various materials may be utilized. For example, the cover plate 130 may be formed of a transparent acrylic plate having a predetermined thickness, and may be implemented to visually check the sea water and the fish circulating into the breakwater structure.

Base ground 150 is made of the foundation work of the bottom of the sea floor, flatten the bottom surface of the seabed unstable terrain, so that the unit structure 110 can be stably stacked on the top surface. In this case, a support plate (not shown) for supporting and fixing the plurality of structure stacking pillars 120 in the vertical direction may be stacked on the upper surface of the base ground 150. In this case, the base ground 150 is made of a sand stone, and may be provided with a coated stone (not shown) for fixing the laminated support plate after the support plate is laminated on the upper surface.

On the other hand, the breakwater structure 100 according to an embodiment of the present invention may omit the foundation ground 150. In this case, each structure stacking column 120 is formed so that the lower portion is inserted into the terrain of the seabed more than a predetermined length, and a plurality of structure stacking columns 120 are stacked on each structure stacking column 120 from the ground surface of the seabed. The upper surface of the uppermost unit structure 110 may form a plane. That is, each of the stacked structure pillars 120 are laminated through the larger number of unit structures 110 as the inserted seabed terrain is concave, and the smaller the number of unit structures 110 as the inserted seabed terrain is convex. By stacking through, the planes of the unit structures 110 stacked through the stack pillars 120 may be horizontally aligned with each other to form a plane.

6 is a view showing a breakwater structure according to another embodiment of the present invention, Figure 7 is a view showing an example of a deformation plane used for the breakwater structure of Figure 6, Figure 8 is used for the breakwater structure of Figure 6 It is a figure which shows another example of a deformation plane.

6 to 8, the breakwater structure 200 according to the embodiment of the present invention includes a plurality of unit structures 110, a unit plane 111, deformation planes 115 and 117, and a structure stack pillar 120. The cover plate 130 may include a base ground 150, a plurality of support pillars 210, and a breakwater wall 213. Here, the configuration and function of the plurality of unit structures 110, the unit plane 111, the structure stack pillar 120, the cover plate 130 and the base ground 150 is a plurality of units shown in Figs. Since the structure and function of the structure 110, the unit plane 111, the structure stack pillar 120, the cover plate 130 and the base ground 150 is the same or similar, the same reference numerals are given, and the detailed description thereof will be given herein. Omit.

Deformation planes 115 and 117 arrange a plurality of unit structures 110 while spaced apart from at least one unit structure 110 in the horizontal and vertical directions, and connect the unit structures 110 arranged to each other. Is formed. That is, as shown in FIGS. 7 and 8, the deformation planes 115 and 117 are arranged in the horizontal and vertical directions by spaced apart from each unit structure 110 at set intervals, and the plurality of unit structures 110 arranged. At least one of the unit structures 110 may be removed in a set pattern, and the unit structures 110 adjacent to each other may be connected to each other. At this time, each of the unit structures 110 adjacent to each other in the horizontal and vertical directions are connected to each other by a connecting rod 114. In addition, a plurality of grooves 116 may be formed in the upper and lower surfaces of each unit structure 110 constituting the deformation planes 115 and 117. 7 and 8 illustrate a plurality of grooves 116 formed on the upper and lower surfaces of the unit structures 110, but also the grooves 116 on each side surface connected to the connecting rods 114. It is formed, it is preferable to insert and secure the connecting rod 114 to one end of each groove 116.

The deformation planes 115 and 117 may be stacked in a vertical direction in a set number to form a deformation plane group. In addition, the unit plane 111 and the deformation planes 115 and 117 of different shapes may be combined to form a deformation plane group. In addition, the forming work of the unit plane 111, the deformation plane (115, 117), the unit plane group, the deformation plane group, etc. can be performed on land, the formed unit plane 111, deformation plane (115, 117), Since the breakwater structure can be constructed in units of a unit plane group or a deformation plane group, it is possible to reduce the process of working underwater and also to reduce the time of the breakwater construction process.

The plurality of support columns 210 may be generated by stacking the unit planes 110 and the deformation planes 115 and 117 so that the unit structures 110 which are empty in the vertical direction in a specific column or a specific row do not occur. For example, when the unit planes 111 and the deformation planes 115 and 117 illustrated in FIGS. 7 and 8 are stacked as described above, the unit structure (1), the third column, the fifth column, and the like are stacked. 110 may be continuously stacked in the vertical direction, when the gap is formed by the structure stacking pillar 120 and the gap support pillar 140 when the unit plane 111 and the deformation planes 115 and 117 are stacked. In addition, by stacking the unit structure 110 in the vertical direction can form a continuous pillar shape. The pillar shape formed in this way is called a support pillar 210. In this case, the structure stacking pillars 120 may be all erected in each support pillar 210 or may be erected in at least one support pillar 210 of the plurality of support pillars 210. That is, when stacking the unit plane 110, the deformation plane (115, 117) may be stacked continuously without forming a gap between the plane and the plane, in this case, the structure stack pillar 120 is a support pillar formed At least one of the support 210 may be penetrated in the support pillar 210. As a result, a distribution path of seawater is generated between the support pillars 210, and the stability of the breakwater structure 100 may be enhanced by the support pillars 210. In addition, the plurality of support pillars 210 may be formed by continuously adapting the unit structure 110 between the unit planes 110 and the deformation planes 115 and 117 to be stacked.

The breakwater wall 213 is formed by stacking a plurality of unit planes 111, deformation planes 115 and 117, unit plane groups, and deformation plane groups. In this case, it is preferable that a gap having a set height is formed between at least two or more planes among the plurality of unit planes 111 and the deformation planes 115 and 117 stacked. In this case, the gap between the stacked planes may be formed using the structure stack pillar 120. Here, the breakwater wall 213 is preferably formed by stacking the unit plane 111 and the deformation plane (115, 117) that the unit structure 110 at a specific position always overlaps. For example, when the unit plane 111 and the deformation planes 115 and 117 illustrated in FIGS. 7 and 8 are stacked, the unit structure 110 is empty in the first column, the third column, and the fifth column. Breakwater walls 213 stacked in a vertical direction without a load are formed.

6 to 8 illustrate and describe the breakwater wall 213 having the support pillars 210 formed one by one in order to form a distribution path of the seawater in the front and rear directions of the breakwater structure 200, the unit plane ( 111 and the deformation planes 115 and 117 of various patterns may be combined and stacked to form a breakwater wall 213 having a distribution path of seawater in various directions and shapes.

In addition, although the breakwater structure 200 is shown as including the foundation ground 150 in Figure 6, the breakwater structure 200 according to an embodiment of the present invention is the same as the case of the breakwater structure 100 described above, each structure The lower portion of the stacking pillar 120 and the support pillar 210 may be implemented to be inserted into the seabed terrain over a predetermined length.

9 is a view showing a breakwater structure according to another embodiment of the present invention.

9, the breakwater structure 300 according to the embodiment of the present invention includes a plurality of unit structures 110, a unit plane 111, a plurality of structure through-bars 160, a frame 170, and a breakwater wall ( 313). Herein, the unit structure 110 and the unit plane 111 have the same structure and function as the unit structure 110 and the unit plane 111 shown and described with reference to FIGS. 3 and 4, and therefore, the same reference numerals are given herein. The detailed description is omitted.

The structure through rod 160 penetrates the centers of the plurality of unit structures 110 in a horizontal direction and forms at least one gap greater than a width set between the unit structures 110 penetrating in a line. At this time, the structure through-rod 160 is formed in the unit structure at a predetermined interval, or to form a gap between the unit structure 110 using the gap support pillar 140, as in the case of the structure laminated column 120 described in FIG. The clearance between the unit structures 110 may be formed by fixing the 110. Herein, the structure through bar 160 stands the plurality of unit planes 111 in the vertical direction, and the unit structures 110 arranged in the horizontal direction so that their centers coincide with respect to the plurality of unit planes 111 standing in the vertical direction. It may penetrate and form at least one gap greater than or equal to a predetermined interval between the penetrating unit structures 110.

In addition, the structure through rod 160 penetrates the centers of the plurality of unit structures 110 in a horizontal direction, and each unit structure 110 penetrating in a line is located at the center of the plurality of unit structures 110 adjacent to each other. The unit structure 110 may be penetrated so as to be positioned, and the breakwater wall may be formed using the plurality of unit structures 110. In this case, it is preferable that a gap support rod is formed between the unit structures 110 adjacent to each other to form a gap.

The frame 170 supports at least one structure through rod 160 installed in the horizontal direction. That is, the frame 170 supports and fixes the structure through rod 160 in the horizontal direction at the front and the rear of the at least one structure through rod 160. In FIG. 9, the frame 170 supports and supports the structure through rod 160 only at the front and the rear of the structure through rod 160. It may be formed to support.

At this time, the frame 170 erected in the vertical direction of the frame 170 may be implemented to be inserted into the seabed terrain over a set length, as shown in the lower end. However, the breakwater structure 300 according to the embodiment of the present invention may be installed on the upper surface of the base ground 150 is installed, of course.

The breakwater wall 313 stands up the plurality of unit planes 110 in the vertical direction, and is formed to reduce the wave energy by connecting the plurality of the unit planes 110 to the plurality of structure through-bars 160. In this case, the structure through bar 160 penetrates all the unit structures 110 arranged horizontally with respect to the plurality of unit planes 110 or partially horizontally within a range of forming a rigidity capable of reducing wave energy. Only through the unit structures 110 in the direction.

10 is a view showing a breakwater structure according to another embodiment of the present invention.

Referring to FIG. 10, the breakwater structure 400 according to the embodiment of the present invention includes a plurality of unit structures 110, a foundation ground 150, a laminated frame 180, a stepped cover plate 190, and a breakwater wall ( 413). Here, since the unit structure 110 and the foundation ground 150 are the same as the unit structure 110 and the foundation ground 150 of FIGS. 2 and 3, detailed description thereof will be omitted.

Here, the plurality of unit structures 110 may be arranged in a horizontal and vertical direction on a plane to form a unit plane (refer to FIG. 4), and the plurality of unit planes 111 are stacked to breakwater walls 413. Can be formed. In this case, the breakwater wall 413 is located at a common center of a plurality of adjacent unit structures 110 of the unit plane 111 where the center of each unit structure 110 of the unit plane 111 stacked above is located below. It may be formed to be laminated so as to. For example, when the unit planes 111 are stacked, the unit planes 111 stacked on the unit planes 111 may have the unit planes 111 positioned below the unit planes 110, as shown in FIG. 11. It may be stacked to be positioned between the four unit structures (110). In FIG. 11, although the unit structure 110 in which the breakwater wall 413 is stacked above is illustrated and described as being stacked between four unit structures 110 positioned below, the breakwater wall 413 is disposed upward. The stacked unit structures 110 may be implemented to be stacked between two unit structures 110 positioned below or stacked between three unit structures 110 positioned below. At this time, the breakwater wall 413 is formed to gradually reduce the number of unit structures 110 as the unit planes 111 stacked upward with respect to the plurality of unit planes 111, as shown in FIG. 10. It may be implemented as.

12, as illustrated in FIG. 12, two, three, or four unit structures 110 of adjacent unit planes 111 positioned downward with respect to a plurality of unit planes 111 that are stacked with each other. The unit structure 110 of the upper unit plane 111 stacked on the common center is fixed to support the laminated structure of the unit plane 111 of the breakwater wall 413. That is, instead of stacking the plurality of unit structures 110 using the structure stacking pillars 120, the stacking frame 180 stacks the plurality of unit planes 111 in a stepped manner, and the unit planes stacked above. The unit structures 110 of 111 and a plurality of adjacent unit structures 110 of the unit plane 111 positioned below are fixed and supported.

However, the stacking structure of the breakwater wall 413 includes a plurality of adjacent adjacent planes of the unit planes 111 in which the unit structures 110 of the unit planes 111 in which the plurality of unit planes 111 are stacked above are located. When stacked to be located at the common center of the unit structure 110, as shown in FIG. 13, the structure stack pillar 120 may be implemented to stand through the unit structures 110 arranged in the vertical direction. . At this time, the structure stack pillar 120 is preferably formed to form a gap or more set intervals between the unit structure 110 penetrated in the vertical direction in order to facilitate the distribution of sea water. In this case, the unit structures 110 that penetrate in the vertical direction of the arbitrary structure stack pillars 120 and the unit structures 120 that penetrate in the vertical direction of the adjacent structure stack pillars 120 are respectively disposed in the vertical direction. A gap support pillar 118 may be installed between the unit structures 110 to support a gap for distribution of seawater.

Stepped cover plate 190 is a plurality of unit structures 110 are laminated by a stacking frame 180 and the outer side of the breakwater structure 400 is made of a stepped, the uppermost unit structure 110 and the stepped Cover the outer surface with steps. At this time, it is preferable that the outer surface covered with a step is formed with a hole so that seawater can flow.

On the other hand, the above-mentioned breakwater structure (100, 200, 400) may be implemented in a form in which the foundation ground 150 is removed. In this case, as shown in FIG. 14, the lower end portions of the plurality of insertion pillars 220 are inserted into the seabed terrain 80 over the length set vertically downward, and from the seabed terrain 80 of each insertion column 220. At least one unit structure 110 penetrates the protruding upper end portion. At this time, the unit structure 110 penetrating the upper end of each insertion column 220 is the top of the unit structure 110 through which the upper surface of the unit structure 110 is located at the top of the adjacent insertion column 220 It is stacked to be horizontal to the upper surface of the unit structure 110 of. In this manner, the unit structures 110 are penetrated through the plurality of insertion pillars 220, and the foundation support 222 is formed on the seabed terrain 80 as a set of unit structures 110 penetrated through the insertion pillars 220. In addition, the upper surface of the base support 222 may be formed in a plane to form the breakwater walls 113, 213, and 413 thereon.

Claims (13)

delete delete delete delete delete delete delete In the breakwater structure that minimizes the influence of the wave energy of the sea side on the sea side,
A unit structure formed by filling an arbitrary object having a predetermined weight or more inside the waste tire of a set size;
A unit plane in which a plurality of the unit structures are arranged in a horizontal and vertical direction on a plane, and each of the arranged unit structures is connected to each other;
A plurality of unit planes stacked in a step shape, wherein a breakwater wall formed by stacking the centers of arbitrary unit structures in a common center of a plurality of unit structures adjacent to each other;
A laminated frame supporting a laminated structure of each of the unit planes forming the breakwater wall; And
A stepped cover plate which covers the outermost surface of the unit structure and the breakwater wall in a step shape,
The laminated frame is fixed to and support a unit structure of the upper unit plane stacked on the common center of a plurality of adjacent unit structures of the lower unit plane and a plurality of lower unit structures,
The stepped cover plate is a breakwater structure, characterized in that the hole is formed so that seawater can be distributed to the outer surface covered by the stepped. delete delete delete delete delete

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