KR20130007679A - Breakwater structure - Google Patents

Abstract

PURPOSE: A breakwater structure is provided to quickly and accurately sensing the state of a breakwater by being added with a monitoring system and to prevent environment contamination while maintaining the original function of a breakwater by being equipped with a structure for a smooth mobility of sea water between the inland and open seas. CONSTITUTION: A breakwater structure(100) includes a first unit assembly body(110), a second unit assembly body(120), a cover plate(130), and a blocking wall. The first unit assembly body comprises a first frame(111) and multiple spherical bodies(112) stored in a first frame. The second unit assembly body comprises a second frame(121) and at least a spherical body(122) stored in a second frame. The second unit assembly body is laminated on the first unit assembly body. The cover plate is installed to cover the top part of the laminated second unit assembly body. The blocking wall is vertically installed between the second unit assembly bodies laminated on the upper part of the first unit assembly body. [Reference numerals] (AA) Open sea; (BB) Inland sea

Description

Breakwater structure {Breakwater structure}

The present invention relates to a breakwater structure, and more particularly, to prevent the contamination of the inland sea by allowing seawater to move freely from the inland sea to the open sea and from the outboard sea to the inland sea while preventing high waves from the open sea. It relates to a breakwater structure that can be.

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 on the sea side is contaminated, and various kinds of dirt accumulate, in severe cases odor occurs. It is no exaggeration to say that this would completely destroy the tidal flats and seabed ecosystems on the Inland Sea.

In addition, the above-mentioned breakwaters do not effectively prevent the waves coming in. The seawater hit by the breakwater has a large repulsion force, and it is combined with the seawaters coming in succession, and hits the breakwater with more energy. Enters the Inland Sea beyond the breakwater.

To remedy this problem, various structures of breakwaters have been proposed to allow seawater to be distributed. One of them is a breakwater constructed by laminating using "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 constructing a breakwater according to the prior art.

The unit block shown in FIG. 1 is connected by a plurality of pillars 30 in which the upper plate 10 and the lower plate 20 are alternately formed to form a single body, and the upper plate 10 and the lower plate 20 are coupled to each other. The jaw 15 and the grooving groove 25 are formed. Since a plurality of unit blocks are vertically stacked on the frame 50 in which the bite jaw 55 is formed to protrude, a breakwater capable of smoothly communicating birds is constructed.

However, in the breakwater having such a structure, a plurality of horizontal plates, that is, the upper plate 10 and the lower plate 20 are provided, so that the waves moving up and down basically enter the inner space of the breakwater and are not transmitted in the vertical direction of the breakwater. It does not have the disadvantage of not using all of the internal volume of the breakwater. In addition, the above-described breakwater of the prior art induces the flow of the sea water only in the horizontal direction of the wave, it can not effectively attenuate the wave energy of the wave having an irregular three-dimensional movement, the reflected wave due to the components of the breakwater is generated significantly However, there is a problem in that the resistance of the breakwater components is relatively large, which adversely affects the safety of the entire structure.

Moreover, the breakwater of the prior art only attenuates a part of the wave energy and the remaining energy is transferred towards the inshore sea. As a result, when the weather deteriorates such as a typhoon, the breakwater does not absorb or disperse the wave energy and delivers it to the harbor, thereby causing a problem that the facilities or the vessels in the berth are damaged.

Accordingly, the present invention has a structure that can prevent the waves flowing into the inland sea when the wave height is high, while having a structure that allows the seawater to move smoothly between the inland sea and the outer sea when the usual waves are calm, while fully utilizing the unique function of the breakwater The purpose is to provide an eco-friendly breakwater structure that can be released from various environmental pollution.

The breakwater structure according to the first embodiment of the present invention includes: at least one first unit assembly having a first frame and a plurality of spherical or polyhedrons accommodated in the first frame; A plurality of second unit assemblies having a second frame and at least one spherical body or a polyhedron accommodated in the second frame and stacked on the first unit assembly; And a cover plate installed to cover the uppermost part of the stacked second unit assemblies.

Breakwater structure according to a second embodiment of the present invention, at least one first unit assembly having a first frame and a plurality of spherical or polyhedral accommodated in the first frame; A plurality of second unit assemblies having a second frame and at least one spherical body or a polyhedron accommodated in the second frame and stacked on the first unit assembly; A barrier wall vertically installed between the stacked second unit assemblies above the first unit assembly; And a cover plate installed to cover the top of the stacked second unit assembly and the blocking wall.

As described above, according to the present invention, the seawater can move freely from the inland sea to the offshore sea and from the offshore sea to the inland sea while preventing high waves, thereby preventing the contamination of the inland sea.

In addition, according to the present invention, by further providing a barrier wall on the inner sea side of the breakwater, the direction of the reflected wave reflected by the wave hits the barrier wall is dispersed in the upper space where the seawater is not full, the wave breakwater when the wave height is high It not only prevents the water from passing over it, but it also reduces the amount of seawater that flows from the bottom of the water (the lower part of the breakwater without a barrier) to the inland sea, thereby improving the positive temperature of the inland sea. You can get the effect.

In addition, according to the present invention, since there is a space inside the breakwater and the internal space provides a habitat for animals and plants, it is possible to prevent contamination of the inland sea and to have an additional effect that fish and algae can inhabit.

Moreover, according to the present invention, by further providing a monitoring system for monitoring the state of the breakwater, there is an effect that can quickly and accurately detect the state of the breakwater.

1 is a schematic front view of a breakwater constructed using a unit block for building a breakwater according to the prior art.
2 is a cross-sectional view showing a breakwater structure according to a first embodiment of the present invention.
FIG. 3 is a perspective view illustrating the first unit assembly shown in FIG. 2.
4 is a perspective view illustrating a modification of the first unit assembly illustrated in FIGS. 2 and 3.
5 is a perspective view illustrating another example of the first unit assembly.
6 is a perspective view illustrating still another example of the first unit assembly.
FIG. 7 is a perspective view illustrating the first unit assembly shown in FIG. 6.
8 is a perspective view illustrating a modification of the first unit assembly illustrated in FIGS. 6 and 7.
FIG. 9 is a perspective view of the second unit assemblies shown in FIG. 2. FIG.
10 is a cross-sectional view showing a breakwater structure according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

2 is a cross-sectional view showing a breakwater structure according to a first embodiment of the present invention. The breakwater structure 100 according to the first embodiment of the present invention shown in FIG. 2 includes a first frame 111 and a plurality of spherical bodies 112 or polyhedrons accommodated in the first frame 111. At least one first unit assembly 110; A plurality of second unit assemblies 120 having a second frame 121 and at least one spherical body 122 or a polyhedron accommodated in the second frame 121 and stacked on the first unit assembly 110. ; And a cover plate 130 installed to cover the uppermost part of the stacked second unit assemblies 120.

The first unit assembly 110 has a shape in which a plurality of spherical bodies 112 or polyhedra are accommodated in the first frame 111. The first frame 111 is made of metal or reinforced concrete with excellent corrosion resistance, and the spherical body 112 or polyhedron may be made of concrete. If necessary, the first frame 111 is reinforced with a core material of the spherical body 112 or polyhedron. This can be used.

The spherical body 112 is not necessarily limited to having a spherical shape of a garden, and a curved body having an elliptical cross section or having a plurality of irregular curved portions may be used. Moreover, the surface of the spherical body 112 may be smooth, or a plurality of grooves or protrusions may be formed, such as golf balls.

Although not shown, in the case of polyhedrons, the breakwater structure 100 may be structurally more stable because these polyhedrons are in contact with each other, rather than points, and have a predetermined area, and in some cases, the first frame 111 may be It is possible to design an economic breakwater structure that can reduce the components. Considering this point, as the polyhedron, a regular 12 or more regular polyhedron is preferable, but is not necessarily limited thereto, and an irregular polyhedron may also be used. In addition, the surface of the polyhedron may be smooth, or a plurality of grooves or protrusions may be formed.

The first unit assembly 110 is preferably installed on the flat base support 140 disposed on the bottom surface of the seabed, but is not necessarily limited thereto. In addition, the first unit assembly 110 may be installed in various ways, and can be divided into a single type and an assembled type.

As shown in FIGS. 2 to 5, first, the side frame 113 of the first frame 111 is installed as a fence over the base support 140, and then divided into the side frame 113. In the space, the spherical body 112 or the polyhedron is stacked and evenly arranged in one layer. Here, the side frame 113 may have a height ranging from the base support 140 to approximately the average water surface, and may simply constitute the side frame 113 using only a plurality of vertical members 113a (see FIG. 3). More preferably, the side frame 113 may be composed of a plurality of vertical members 113a and at least one horizontal member 113b connecting the vertical members 113a (see FIG. 4).

In addition, assuming that the spherical body 112 or the polyhedron stacked in the inner space of the side frame 113 is stacked in three layers, for example, as shown in FIG. 3, the second layer is disposed between the first layer and the third layer. The layers may be stacked in a staggered manner, or the first to third layers may be stacked in a lattice arrangement horizontally and vertically as shown in FIG. 4. The stacking structure in which layers are stacked alternately can be constructed in a more robust and dense form, but is not limited to such a stacking method, and can be stacked in various ways to suit a specific environment of an installation area by changing the density.

On the other hand, as shown in Figure 5, after the pillar member 113c acting as a vertical member of the side frame 113 arranged in a honeycomb when viewed in plan view on the base support 140, and installed vertically, The spherical body 112 or the polyhedron may be piled up in the space of the substantially hexagonal column shape partitioned by the pillar member 113c. As described above, the pillar member 113c of the side frame 113 may have a height that extends from the base support 140 to approximately the average water surface. Such a configuration has the advantage that the spherical body 112 or the polyhedron can be firmly arranged while being aligned in the vertical direction.

After the spherical body 112 or the polyhedron is stacked in the inner space up to the top height of the side frame 113, the top frame connected to the side frame 113 while covering the stacked spherical body 112 or the polyhedron ( 114 may be installed. The upper frame 114 is for stably installing the second unit assembly 120 or the barrier wall 250 to be described later on the first unit assembly 110, a grid member or a honeycomb mesh member or a flat plate It can be formed as a member.

6 to 8, as shown in Figures 6 to 8, a plurality of first unit assembly 110 is prepared in advance in other places and installed by moving or moving to the construction area of the breakwater structure 100 prefabricated arrangement or stacking. . The first frame 111 is formed in a box shape of a substantially hexahedron, that is, the side frame 113 is connected between the upper frame 114 and the lower frame 115, and a certain number of spherical bodies 112 therein. Or polyhedrons are arranged and stacked to accommodate.

The plurality of first unit assemblies 110 thus formed are appropriately arranged on the base support 140. When each of the first unit assemblies 110 has a height reaching approximately the average water surface, when arranged in a single layer as shown in FIG. Otherwise, the first unit assemblies 110 are arranged and stacked in a multi-layer up to an average surface level. At this time, if necessary, a separate connection means (not shown) for connecting the first unit assembly 110 may be used.

In addition, in one first unit assembly 110, it is assumed that the spherical body 112 or the polyhedron stacked in the inner space of the first frame 111 is stacked in three layers, for example, as shown in FIG. 7. The second layer may be stacked alternately between the first layer and the third layer, or the first to third layers may be stacked in a lattice arrangement horizontally and vertically as shown in FIG. 8.

The second unit assembly 120 has a shape in which at least one spherical body 122 or polyhedron is accommodated in the second frame 121. The second frame 121 is made of metal or reinforced concrete having excellent corrosion resistance, and the spherical body 122 or polyhedron may be made of concrete. If necessary, the second frame 121 is reinforced with a core material of the spherical body 122 or polyhedron. This can be used. The spherical body 122 or the polyhedron used in the second unit assembly 120 may be formed of the same or different size and material as the spherical body 112 or the polyhedron used in the first unit assembly 110.

The second unit assembly 120 may be made in various sizes, for example, as shown in FIG. 2, the large second unit assembly 123 according to the size of the spherical body 122 or the polyhedron accommodated therein. The second unit assembly 124 may be divided into the small second unit assembly 125. In addition, the number of spherical bodies 122 or polyhedrons accommodated in the second frame 121 is preferably about 1 to 10, but is not necessarily limited thereto, and the number may be changed as necessary. Therefore, the size and number of the spherical body 122 or the polyhedron accommodated in the second unit assembly 120 may be used in appropriate combination. For example, in FIG. 9, a large second body having three spherical bodies 122 may be used. The unit assembly 123 and the small second unit assembly 125 having two spherical bodies 122 are enlarged and shown.

The second unit assembly 120 is previously manufactured in another place and installed by moving to the construction area of the breakwater structure 100 by arranging or stacking on the upper frame 114 of the first unit assembly 110. The second frame 121 is formed in a substantially hexahedral box shape, that is, the side frame 128 is connected between the upper frame 126 and the lower frame 127, and a certain number of spherical bodies 122 therein. Or align the polyhedrons in a row to accommodate them.

When the plurality of second unit assemblies 120 are disposed on the first unit assembly 110, the second unit assembly 120 having two or more spherical bodies 122 or polyhedrons is shown in FIG. 2. As described above, it is preferable to install the second unit assembly 120 such that the two or more spherical bodies 122 or the polyhedrons are long and stacked in the vertical direction. Do. In this case, if necessary, a separate connection means (not shown) for connecting the second unit assemblies 120 may be used.

Since the first unit assembly 110 is installed at a height close to the average surface as much as possible, the stacked second unit assemblies 120 are normally exposed to the outside of the surface considerably.

When arranging a plurality of second unit assemblies 120, on the outer sea side of the breakwater structure 100, a large second unit assembly 123 having a spherical body 122 or a polyhedron having a volume larger than that of the inner sea side is disposed, The medium second unit assembly 124 and the small second unit assembly 125, which are gradually smaller in volume toward the inner sea, are disposed in this order. In addition, even if the second unit assemblies 120 of the same size are arranged, the second unit assembly may be arranged such that the alignment between the spherical bodies 122 or the polyhedrons accommodated in each second unit assembly 120 is consistent or shifted. By properly applying and arranging the 120, the density of the spherical body 122 or the polyhedron is changed to be more dense on the inland sea side so that the breakwater structure 100 suitable for the specific environment of the installation area can be constructed. In addition, by appropriately selecting and combining the size of the second unit assembly 120, in particular, the size of the spherical body 122 or the polyhedron through the actual wave data of the installation area of the breakwater structure 100, the whole of the breakwater structure 100 The width can be minimized.

The cover plate 130 is installed to cover the uppermost part of the stacked second unit assembly 120. The cover plate 130 is generally made of concrete, but is not limited thereto. The cover plate 130 serves to confine the seawater inside the breakwater structure 100 and may be used as a sidewalk and a roadway.

The reason for differentiating the density of the spherical body 122 or the polyhedron in the breakwater structure 100 according to the first embodiment of the present invention is that a large reflected wave is a region where the wave hits the breakwater structure 100 for the first time on the outer sea side. By placing the bulky spherical body 122 or the large second unit assembly 123 having a polyhedron, the voids between the bulky spherical body 122 or the polyhedrons are formed to be large, the seawater This is to smoothly move into the breakwater structure 100 and to prevent crossing the breakwater structure 100. In addition, by compactly arranging the relatively small volume spherical body 122 or the small second unit assembly 125 having a polyhedron on the inner sea side, the effect of maximizing the offset of the wave energy due to the increased surface area and irregularity Will be. When the small second unit assembly 125 is arranged very densely, seawater entering the breakwater structure 100 may not be leaked toward the inland sea at all.

In addition, the breakwater structure 100 according to the first embodiment of the present invention may include a monitoring system 150 for monitoring the state of the breakwater structure 100. Referring back to FIG. 2, the monitoring system 150 ) Is attached to the plurality of settling system 151 installed on the base support 140, the first frame 111 of the first unit assembly 110 or the second frame 121 of the second unit assembly 120. A plurality of inclinometers 152, the pressure gauge 153 which is installed at a height close to the average surface in the first frame 111 of the first unit assembly 110, and collects and stores the data in which the abnormality from these measuring devices And a control device 154 for transmitting data via wireless communication. Such monitoring system 150 is preferably disposed on the outer sea side of the breakwater structure 100.

The settlement meter 151 and the inclinometer 152 are means for continuously measuring the inclination of the breakwater structure 100. Since the operating principles are similar to each other, the same product may be used. The settlement system 151 and the inclinometer 152 are usually installed in a vertical or horizontal direction and may be located or embedded on the surface of the breakwater structure 100. In FIG. 2, an example in which the settlement system 151 is disposed in the width direction of the breakwater structure 100 is illustrated, but is not limited thereto, and may be disposed intermittently or continuously along the longitudinal direction of the breakwater structure 100.

In the breakwater structure 100 according to the first embodiment of the present invention, it is preferable to use an electric settler or an electric inclinometer. The settlement meter 151 or the inclinometer 152 calculates an angle with respect to the direction of gravity with respect to the amount of motion caused by an electronic incline sensor embedded in an aluminum tube. Or current).

Wave pressure gauge 153 is a means for measuring the distribution pressure of the wave on the breakwater structure 100, is installed at a height close to the average surface is a good product that can accurately and quickly detect the minute changes in the wave. If necessary, it can be used together with a wave meter or crest meter.

When an abnormality occurs in data measured by the sediment meter 151, the inclinometer 152, the paometer 153, and the like, the controller 154 collects the data and transmits the data to a remote server unit (not shown) through wireless communication. In order to control the transmission, data can be transmitted only when an abnormality occurs to prevent the data from overflowing. The communication method may use any wireless communication technology such as Bluetooth communication, Zigbee, Binary CDMA, WLAN, CDMA, UWB, RF communication, and is not limited to any one communication method.

The remote server unit receiving the data may analyze and store the received data, and notify the manager that an abnormality has occurred in the state of the breakwater structure 100 through an alarm sound, a warning light, and a text message.

The cable 155 connected to each component of the monitoring system 150 supplies power or transmits an output signal. The cable 155 is formed of a hard and corrosion resistant material such as metal or plastic, for example. It is good to install so that it is accommodated inside. In FIG. 2, only the connection between each component and the cable 155 is schematically illustrated for convenience of illustration.

Hereinafter, the operation of the breakwater structure 100 according to the first embodiment of the present invention will be described in detail.

First of all, in order to accurately understand the operation of the breakwater structure 100 according to the first embodiment of the present invention, it is necessary to understand the flow of sea water. Seawater flows have a constant amplitude, periodicity, and speed of travel, no matter how high the waves may occur. In other words, if a high wave from the open sea enters the inland sea, the high wave does not always come in continuously, but if a wave with the largest amplitude has a constant period and velocity like a sine wave, it will slide in succession. This lowest wave is pushed in repeatedly.

At this time, the breakwater structure 100 according to the first embodiment of the present invention has a plurality of spherical bodies 112 or polyhedrons forming voids, so that seawater can normally move freely from the inner sea to the open sea and from the open sea to the inland sea. There is an effect that can prevent the pollution of the inner sea.

In addition, the breakwater structure 100 according to the first embodiment of the present invention uses surface frictional resistance of a spherical body 122 or a polyhedron having a lot of blue energy of seawater coming into the breakwater structure 100 during a bad weather such as a typhoon. Attenuate significantly. That is, the plurality of dense spherical bodies 122 or polyhedrons generate an irregular three-dimensional seawater flow similar to the movement of the waves inside the breakwater structure 100 and increase the surface area to which the waves touch to attenuate the force of the waves. As a result, these spherical bodies 122 or polyhedrons sharply reduce the force of the waves trying to enter the inland sea by changing the flow of seawater coming in the horizontal direction.

In particular, the breakwater structure 100 according to the first embodiment of the present invention uses a very irregular flow of seawater using the surface area of a plurality of spherical bodies 122 or polyhedrons and voids formed between these spherical bodies 122 or polyhedrons. It transforms into a very complicated turbulent flow that spreads in all directions, reducing the wave energy, and at the same time spreading the direction of the wave toward the inland sea in the left and right directions, and retarding the flow of seawater that is pushed toward the inland sea.

The breakwater structure 100 has a configuration to disperse the force hitting the breakwater structure 100 with the sea water, and less reflected waves, even if the wave is constructed at a height lower than the breakwater structure of the prior art over the breakwater structure 100 Can be prevented. Moreover, since seawater is dispersed in the breakwater structure 100 into voids formed between a plurality of spherical bodies 122 or polyhedrons, the breakwater structure is dispersed by the surface area of the force that is increased by the force hitting the breakwater structure 100. The strength of the force per unit area received by the structure 100 due to the waves is also greatly reduced, it is possible to implement a structurally very stable breakwater structure 100 than the breakwater applied in one direction of the prior art. In addition, the entire breakwater structure 100 composed of simple components can shorten the construction period, and there is a great advantage that can also reduce the loss of gravel and earth and sand washed out in the seawater usually appear in the construction of the breakwater.

On the other hand, the breakwater structure 100 according to the first embodiment of the present invention includes a monitoring system 150 for monitoring the state of the breakwater structure 100, the settlement meter 151, the inclinometer 152, wave pressure When an error occurs in the data measured by the system 153 or the like, the control device 154 collects and stores the data and transmits the data to the remote server through wireless communication. Subsequently, the remote server unit having received the data may analyze and store the received data, and notify the manager that an abnormality has occurred in the state of the breakwater structure 100 through an alarm sound, a warning light, and a text message. Therefore, there is an effect that can quickly and accurately detect the state of the breakwater structure (100).

By providing the monitoring system 150 in the breakwater structure 100 in this way, in the event of a natural disaster such as typhoon, tsunami, earthquake, the safety of the breakwater structure 100 itself, as well as the marine state near the breakwater structure 100 It can be closely monitored and thus has the advantage of ensuring the safety of ships and local residents. In addition, through such a monitoring system 150, there is an effect that allows the state or local governments to accumulate and utilize the characteristic data about the ocean.

10 is a cross-sectional view showing a breakwater structure according to a second embodiment of the present invention. The breakwater structure 200 according to the second embodiment of the present invention illustrated in FIG. 10 includes a first frame 111 and a plurality of spherical bodies 112 or polyhedrons accommodated in the first frame 111. At least one first unit assembly 110; A plurality of second unit assemblies 120 having a second frame 121 and at least one spherical body 122 or a polyhedron accommodated in the second frame 121 and stacked on the first unit assembly 110. ; A blocking wall 250 vertically installed between the second unit assemblies 120 stacked on the first unit assembly 110; And a cover plate 130 installed to cover the top of the stacked second unit assembly 120 and the blocking wall 250.

Except that the second embodiment of the present invention further includes a barrier wall 250 installed vertically between the second unit assemblies 120, the remaining components are the same as those of the above-described first embodiment. same. Thus, in the description of the breakwater structure 200 according to the second embodiment of the present invention, the same components as the breakwater structure 100 according to the first embodiment with the same reference numerals while giving a detailed description of the configuration and function Will be omitted.

The blocking wall 250 is a flat wall member having a predetermined thickness, and is made of concrete or reinforced concrete, but is not limited thereto, and may use various materials. The barrier wall 250 is installed on the upper frame 114 of the first unit assembly 110. By constructing the barrier wall 250, the barrier wall 250 directly blocks the incoming waves through the breakwater structure 200 and at the same time, To keep calm.

The breakwater structure 200 according to the second embodiment of the present invention is characterized by the flow of very irregular seawater coming from the open sea side and the surface area of the plurality of spherical bodies 122 or polyhedrons and the voids formed between these spherical bodies 122 or polyhedrons. It transforms into a very complicated turbulent flow that spreads in all directions, reducing the wave energy, and at the same time spreading the direction of the wave toward the inland sea in the left and right directions, and delaying the flow of seawater that is pushed toward the inland sea. Furthermore, waves hitting the blocking wall 250 installed on the upper portion of the first unit assembly 110 continue to pile up and move toward the upper portion of the breakwater structure 200, and the reflected wave starting from the blocking wall 250 passes through the upper portion. As you return to the open sea, you meet the calming waves and let the water flow out to the open sea without major collisions. Through this series of processes, the wave energy of the wave is confined inside the breakwater structure 200, and a stable flow of seawater is created inside the breakwater structure 200 before a large wave comes again.

On the other hand, the barrier wall 250 is not installed at the inner edge of the inner sea side, but is installed on the first unit assembly 110 at a position moved by a predetermined distance from the inner sea side to the outer sea side, and then the side of the inner sea side of the barrier wall 250. By stacking the small second unit assemblies 125 adjacent to each other, it is possible to improve the static temperature of the inshore sea by providing a space for receiving and canceling reflected waves that may occur on the inshore sea side. In this way, when the static temperature of the inland sea is improved, an effect of creating an environment in which the vessel can be moored more stably is obtained.

In addition, the blocking wall 250 prevents the wind passing through the breakwater structure 200 above the water surface, and thus has the advantage of creating a calm environment that separates the inner sea inside the breakwater structure 200 from the outer sea. .

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

100, 200: breakwater structure
110: first unit assembly
120: second unit assembly
130: cover plate
140: foundation support
150: monitoring system
250: barrier wall

Claims (22)

At least one first unit assembly having a first frame and a plurality of spherical or polyhedrons accommodated in the first frame;
A plurality of second unit assemblies having a second frame and at least one spherical body or a polyhedron accommodated in the second frame and stacked on the first unit assembly; And
Cover plate installed to cover the uppermost part of the stacked second unit assembly
Breakwater structure comprising a. At least one first unit assembly having a first frame and a plurality of spherical or polyhedrons accommodated in the first frame;
A plurality of second unit assemblies having a second frame and at least one spherical body or a polyhedron accommodated in the second frame and stacked on the first unit assembly;
A barrier wall vertically installed between the stacked second unit assemblies above the first unit assembly; And
A cover plate installed to cover the top of the stacked second unit assembly and the blocking wall
Breakwater structure comprising a. The method according to claim 1 or 2,
The first unit assembly is a breakwater structure is installed on the base support disposed on the bottom surface of the seabed. The method of claim 3,
The first unit assembly is a breakwater structure formed by stacking the spherical body or the polyhedron while arranging the side frame of the first frame on the base support, and partitioned by the side frame. The method of claim 4,
The side frame has a height from the base support to the average surface of the breakwater structure. The method of claim 5,
The side frame is a breakwater structure formed of a plurality of vertical members. The method according to claim 6,
The vertical member is a pillar member,
The first unit assembly is arranged in a honeycomb shape when the pillar member is viewed in plan view on the base support, and installed vertically, and stacking the spherical body or the polyhedron in a space partitioned by the pillar members. Breakwater structure. The method of claim 5,
The side frame is a breakwater structure formed of a plurality of vertical members and at least one horizontal member connecting the vertical members. 5. The method of claim 4,
The stacked spherical body or polyhedron is stacked in a grid arrangement arranged horizontally and vertically breakwater structure. 5. The method of claim 4,
The stacked spherical body or polyhedron is a breakwater structure stacked so that the intermediate layer is arranged between the upper layer and the lower layer. 5. The method of claim 4,
Breakwater structure that is connected to the side frame and the top frame is installed covering the stacked spherical or polyhedron. The method of claim 11,
The upper frame is a breakwater structure formed of a net member or plate member. The method of claim 3,
The first frame is formed by connecting the side frame between the upper frame and the lower frame,
A breakwater structure in which a plurality of first unit assemblies having a predetermined number of the spherical bodies or the polyhedrons arranged and stacked in the first frame are arranged or stacked on the foundation support. The method according to claim 1 or 2,
The second frame is formed by connecting the side frame between the upper frame and the lower frame,
A breakwater structure in which a plurality of second unit assemblies having a predetermined number of the spherical bodies or the polyhedrons arranged in a line in the second frame are stacked on the first unit assembly. 15. The method of claim 14,
The second unit assembly is a breakwater structure is divided according to the size of the spherical body or polyhedron accommodated in the second unit assembly. 16. The method of claim 15,
When arranging the plurality of second unit assemblies, a second unit assembly having a spherical body or a polyhedron having a larger size than that of the inner sea side is disposed on the outer sea side of the breakwater structure, and a spherical body or polyhedron having a smaller size toward the inner sea side. Breakwater structure comprising a second unit assembly having a. The method according to claim 1 or 2,
A spherical body or polyhedron used in the first unit assembly and a spherical body or polyhedron used in the second unit assembly are formed of the same or different size and material. The method according to claim 1 or 2,
A spherical body or polyhedron used in the first unit assembly and a surface of the spherical body or polyhedron used in the second unit assembly are smooth or breakwater structures having a plurality of grooves or protrusions formed therein. The method according to claim 1 or 2,
The polyhedron used in the first unit assembly and the polyhedron used in the second unit assembly are icosahedron or more regular dodecahedral breakwater structure. The method of claim 3,
Breakwater structure further comprising a monitoring system for monitoring the state of the breakwater structure. 21. The method of claim 20,
The monitoring system includes a plurality of settling systems installed on the base support, a plurality of inclinometers attached to the first unit assembly or the second unit assembly, a wave pressure meter installed on the first unit assembly, and the settling system And Breakwater structure comprising a control device for collecting and storing the data in which the abnormality from the inclinometer or the paometer to transmit data through wireless communication. The method of claim 2,
The barrier wall is installed on the first unit assembly at a position moved from the inner sea side to the outer sea side of the breakwater structure,
A breakwater structure in which the second unit assemblies are stacked adjacent to the inner sea side of the barrier wall.

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