KR20190099845A - Water floating breakwater - Google Patents

Abstract

The present invention provides a floating breakwater, which improves a reducing effect with respect to wave force energy of a relatively big wave of a long wave through a perforating panel provided between buoyant pillars and a high weight flow preventing plate of a lower portion of the perforating panel. According to one embodiment of the present invention, the floating breakwater includes: first buoyant pillars respectively provided to be spaced apart from each other and forming a first path; a perforating panel coupled to the first buoyant pillars at an upper portion of the first path and having a plurality of holes penetrating front and back surfaces; and a flow preventing plate coupled to the first buoyant pillars at a lower portion of the perforating panel, wherein the flow preventing plate is formed to have relatively higher weight than the perforating panel.

Description

Floating breakwater {WATER FLOATING BREAKWATER}

Disclosed herein relates to a breakwater, to a floating breakwater that is suspended in the water phase and reduces the wave energy of waves coming from the open sea.

Unless otherwise indicated herein, the contents described in this identification are not prior art to the claims of this application and the description in this identification is not admitted to be prior art.

In general, breakwaters are installed around the coast to block the waves from the open sea in order to improve the safety of the floating population as marine roads or ports are constructed as cities enter the coast.

Existing breakwaters are mainly made of stone. Since then, mixed breakwaters using both stone and concrete have been used. Recently, a release sofa block has been developed to prevent waves from approaching the sea.

However, breakwaters composed of hetero-sofa blocks manufactured in tetrapod form have a disadvantage in that the structure is difficult when a person falls between the tetrapods, the manufacturing cost is high, and the construction time is long.

In addition, conventional breakwaters have a function of preventing a small wave by floating a heavy object using various materials, but when a large wave approaches, the breakwater function is weakened because the breakwater flows with the long wave.

On the other hand, Korean Patent Publication No. 10-2017-0060502 discloses a flow control underwater breakwater, and Korean Patent Publication No. 10-0796316 discloses a functional block for underwater breakwater, using a variety of materials Although there are underwater breakwaters that have the ability to float high-weight objects to block the waves, these underwater breakwaters have some effect on small wave waves, but when they meet long waves, they do not collide with the waves. There was a problem in that the wave energy of long waves of the long wave can not be effectively reduced due to the tendency to flow up and down with the wave.

In addition, mooring or anchoring systems have been costly to limit the horizontal flow of underwater breakwater in order to keep the original intended position in the horizontal direction relative to the water surface.

The present disclosure solves the above-mentioned disadvantages of conventional breakwaters or underwater breakwaters, and effectively reduces the wave energy of waves of small waves as well as the wave energy of long waves, thereby limiting the horizontal flow of the breakwater. Provide breakwaters to reduce costs.

In addition, the present invention is not limited to the above-described technical problems, and it is apparent that other technical problems may be derived from the following description.

According to an embodiment of the present disclosure, the floating breakwaters are first buoyancy columns each disposed to be spaced apart from each other to form a first passage, coupled with the first buoyancy columns at the top of the first passage, A perforated panel having a plurality of holes penetrating through the surface and a flow preventing plate coupled to the first buoyancy columns at the bottom of the perforated panel, wherein the flow preventing plate is formed to have a relatively higher weight than the perforated panel. do.

In addition, the perforated panel, the flow preventing plate, and the first buoyancy columns may be extended by coupling the outer side of each of the first buoyancy columns.

In addition, the second buoyancy columns disposed behind the first buoyancy columns to form a second passage, the rear breakwater including the perforated panel and the flow preventing plate coupled to the second buoyancy columns to expand and expand further Can be.

In addition, the front and rear portions are in close contact with the back of the first buoyancy column and the front of the second buoyancy column and the center frame and the first and second buoyancy columns are formed so as to be spaced apart from each other and the first and second It may further include anchors coupled to each of the buoyancy columns through a wire or chain and fixed to the seabed.

In addition, each of the first and second buoyancy columns may include buoyancy units that are vertically stacked in a cylindrical shape by combining buoyancy units surrounding a wire frame formed therein.

According to an embodiment of the present disclosure, the floating breakwater can be used as a breakwater only by assembling from the outside and then moving to fix it with the sea floor through the anchor, thus damaging the marine pollution and surrounding environment generated during the breakwater construction. Can be dramatically reduced.

In addition, the floating breakwater can reduce the wave energy of the wave while being less affected by the wave by placing a perforated panel formed with a plurality of holes penetrating the front and rear surfaces near the surface where the wave energy of most waves are concentrated.

In addition, when adopting a configuration in which a plurality of perforated panels before and after the advancing direction of the wave, it is possible to reduce the wave energy of the wave more effectively by sequentially decreasing the wave energy of the wave.

In addition, a high weight flow barrier plate coupled between buoyancy columns composed of a plurality of buoyancy bodies and located deeper than the perforated panel to alleviate the impact caused by the waves near the surface impacting the perforated panel and floating Prevent the flow of breakwater.

Since the effects of the present invention are naturally exerted by the configuration of the floating breakwater disclosed regardless of whether the inventor recognizes them, the above-mentioned effects are only some exemplary effects, and it is recognized that the inventors have described all the effects which are understood or existed. It should not be.

In addition, the effects of the present invention should be further grasped by the entire description of the specification, even if not described in explicit sentences even those having ordinary skill in the art to which the description belongs belong Any effect that can be recognized as should be seen as an effect described herein.

1 is a state of use of the floating breakwater.
Figure 2 is a perspective view of a floating breakwater according to one embodiment of the contents disclosed herein.
3 is an exploded perspective view of the buoyancy body of FIG.
4 is an exploded perspective view of the floating breakwater of FIG.
5 and 6 are exploded perspective views of the perforated panels of FIG.
Figure 7 is a perspective view of the floating breakwater of Figure 2 seen from another angle.
8 is an enlarged perspective view illustrating a coupling structure of the flow preventing plates and the first beam of FIG. 2;

Hereinafter, with reference to the accompanying drawings looks at the configuration, operation and effect of the floating breakwater according to a preferred embodiment. For reference, in the following drawings, each component is omitted or schematically illustrated for convenience and clarity, the size of each component does not reflect the actual size, and the same reference numerals throughout the specification refer to the same component. Reference numerals for the same components will be omitted in the individual drawings.

1 shows a state diagram of use of a floating breakwater.

2 illustrates a perspective view of a floating breakwater in accordance with one embodiment of the disclosure disclosed herein.

3 shows an exploded perspective view of the buoyancy body of FIG. 2.

4 shows an exploded perspective view of the floating breakwater of FIG. 2.

As shown in Figures 1 to 4, the floating breakwater 100 according to the embodiment includes a front breakwater 200, a rear breakwater 400, a central frame 600 and an anchor 800.

The floating breakwater 100 is connected between the buoyant front breakwater 200 and the rear breakwater 400 through the central frame 600, and the anchor 800 to maintain the position of the floating breakwater 100. It is fixed to the seabed surface 20 located in each of the front and rear of the floating breakwater (100).

The front breakwater 200 is close to the wave 10 of the outer sea and the rear breakwater 400 is far from the wave 10 of the outer sea.

Floating breakwater 100 is fixed to the bottom surface 20 through a plurality of anchors 800 and wires in a floating state in water, it is easy to install and manufacture. In detail, the front breakwater 200 is formed between the first buoyancy columns 220 and the first buoyancy columns 220 which are disposed to be spaced apart from each other to form the first passage 30. It includes a flow preventing plate 242 and the perforated panel 244 blocking a portion of the 30.

The rear breakwaters 400 are second buoyancy columns 420 and second buoyancy columns 420, each of which is spaced apart from each other behind the first buoyancy columns 220 and forms a second passage 40 therebetween. It includes a flow preventing plate 442 and the perforated panel 444 formed between the blocks to block a portion of the second passage (40).

Each of the center frames 600 is disposed between each of the first and second buoyancy columns 220 and 420, and the front of each of the center frames 600 is formed with a rear surface of each of the first buoyancy columns 220. The rear side is coupled to the front surface of each of the second buoyancy columns 420 in a state spaced apart from the front side.

Specifically, the front of each of the center frame 600 is coupled to the back of each of the first buoyancy columns 220 in the form of a long extending up and down through the H beam (Beam), each of the center frame 600 The rear side is also coupled to the front side of each of the second buoyancy columns 420 through the H beam.

In the illustrated embodiment, the front breakwater 200 and the rear breakwater 400 are fixed back and forth by the center frame 600 so that the wave 10 passes through the first passage 30 to the second passage 40. It is configured, but the front breakwater 200 in front of the front breakwater 200 in the state with only the front breakwater 200 without the rear breakwater 400 is connected to the anchor 800 through a wire or a chain to be used alone as a floating breakwater 100 Of course it is possible. Each of the first buoyancy columns 220 includes buoyancy bodies 222.

Each of the first buoyancy columns 220 is formed in a cylindrical shape in which a plurality of buoyancy bodies 222 are vertically stacked to extend upward and downward, and are made of a porous polymer material to provide buoyancy to the floating breakwater 100. .

A first passage 30 is formed between the first buoyancy columns 220 to move the waves 10 coming from the external sea, and the perforated panel 244 and the flow preventing plate 242 each have a first passage ( Covering the upper part and the lower part of the 30, respectively, to disperse the wave energy of the wave (10).

Each of the perforated panel 244 and the flow preventing plate 242 is formed in the form of a plate covering each of the upper and lower portions of the first passage 30, the perforated panel 244 is formed in the form of a porous plate to form a wave ( 10) to reduce the wave force, the flow preventing plate 242 has a higher weight than the perforated panel 244 for the stable floating of the front breakwater (200).

In detail, each of the flow preventing plates 242 is disposed to be vertically stacked on each other at the lower portion of the first passage 30, and is formed in a plate shape, and both sides of the first buoyancy columns 220 are respectively disposed between the first and second buoyancy columns 220. It is coupled with the central frame 600 coupled to the rear of each of the buoyancy columns 220.

The position of the perforated panel 244 is determined by the area, weight, and the number of stacked layers of the flow preventing plates 242. The area, weight, and number of stacked layers of the flow preventing plates 242 are floating breakwaters. It can be selected according to the size of the 100 or the wave energy of the wave 10 or the area in which the floating breakwater 100 is installed, each of the flow preventing plate 242 is a corrosion-resistant ceramic containing cement and concrete It may be made of a material or a metal material.

The flow preventing plate 242 is, for example, when formed of a heavy concrete plate when the perforated panels 244, 444 are inclined toward the rear by a long wave waves, the flow blocking plate located below By applying the force to return the perforated panels (244, 444) to the forward direction (242) has the advantage of preventing the flow of the floating breakwater 100 and the wave energy of the long wave 10. Since the flow preventing plate 242 located below the floating breakwater 100 is heavy, the center of gravity of the floating breakwater 100 is located below, so that the perforated panels 244 and 444 located above the floating breakwater 100 are located. When inclined, there is a force based on the gravity that is not inclined and to the original position. In addition, where the flow preventing plate 242 is located, the wave is weak compared to the place where the perforated panels 244 and 444 are located, when the flow preventing plate 242 is inclined while the perforated panels 244 and 444 are inclined. There is also a resistance by water applied to the barrier plates 242. The force by gravity and the resistance by water have the effect of preventing the flow of the floating breakwater 100 and reducing the wave energy of the long wave 10. The perforated panel 244 is formed in a plate shape coupled between the first buoyancy columns 220, and a plurality of holes penetrating the front and rear surfaces are formed to be uniformly spaced apart from each other in a lattice form.

The perforated panel 244 is coupled to the sides of each of the first buoyancy columns 220 in a state spaced apart from the flow preventing plate 242 by a predetermined distance from the top of the flow preventing plate 242, approaching from the external sea The first collision with the wave 10 reduces some of the wave energy of the wave 10.

Part of the seawater passes through the holes formed in the perforated panel 244 by the wave 10, and the rest of the seawater collides with the back surface of the perforated panel 244 between the holes. Through this process, wave energy is reduced.

The second buoyancy column 420 includes buoyancy bodies 220.

Each of the buoyancy bodies 422 is formed in the same shape as each of the buoyancy bodies 222, and is stacked relatively higher than the height of the buoyancy bodies 222 constituting the first buoyancy column 220.

Each of the perforated panel 444 and the flow preventing plate 442 is formed in a plate shape covering each of the upper and lower portions of the second passage 40, and the perforated panel 444 is the wave energy of the wave 10. To reduce the flow, the barrier plate 442 provides a weight for the stable floating of the rear breakwater (400).

The flow preventing plate 442 is formed in the same plate shape as each of the flow preventing plates 242 disposed under the front breakwater 200, and both sides thereof have a second buoyancy column between each of the second buoyancy columns 420. Are coupled to both sides of each of 420.

The stacking number of the flow preventing plates 442 may be changed depending on the size of the wave 10 or the region in which the floating breakwater 100 is installed, and is made of a corrosion resistant ceramic material including cement and concrete.

Each of the flow preventing plates 242 and 442 is disposed under each of the front breakwater 200 and the rear breakwater 400 so that the wave 10 collides with the perforated panels 244 and 444 to float the breakwater 100. When the upper end of the panel tilts toward the rear, the perforated panels 244 and 444 are pulled forward.

When the flow preventing plates 242 and 442 are formed of a heavy concrete plate, each of the perforated panels 244 and 444 is inclined backward by a large wave as well as a small wave, and then again through a high weight. While returning to the original position, the perforated panels 244 and 444 have an advantage of reducing the wave energy of the wave 10 to the original position forward.

Thus, each of the perforated panels 244, 444 is inclined primarily forward by the wave 10, reducing the wave energy of the wave 10, and through the flow preventing plates 242, 442 in the inclined state. The wave energy of the wave 10 continuously approaching in the process of moving toward the rear to the original position is reduced.

The perforated panel 444 is coupled between the second buoyancy columns 420 so as to be detachable or attachable to an inner surface of each of the second buoyancy columns 420 formed on the second passage 40.

The perforated panel 444 is formed to protrude upward relative to the perforated panel 244 when the floating breakwater 100 is disposed at sea.

Each of the perforated panels 444 secondly reduces the wave energy of a portion of the wave 10 in which the wave energy is reduced while passing through the perforated panel 244 to significantly reduce the height of the wave 10 reaching the coast.

Meanwhile, the floating breakwater 100 may expand and install a breakwater of the same type as the rear breakwater 400 or the front breakwater 200 in addition to the rear of the rear breakwater 400, and is relatively larger than the rear breakwater 400. It can be extended by adding a high breakwater.

Referring to FIG. 3, each of the buoyancy bodies 222 and 422 may include a first body 223, a second body 224, lower wires 225, upper wires 226, and side wires 227. , Lower fastening nuts 228, upper fastening nuts 229, and fastening parts 230.

Each of the first body 223 and the second body 224 is formed to extend in one direction in the shape of a semi-circular arch, and when combined with each other, is formed in a cylinder shape, and is an eco-friendly material having excellent heat resistance, impact resistance, durability, and recycling. It is made of expanded polypropylene (EPP) material to provide enhanced buoyancy.

Each of the lower wire 225, the upper wire 226, and the side wires 227 is inserted into each of the first body 223 and the second body 224 to insert the first and second bodies 223 and 224. Improve durability of each one and prevent breakage by deformation.

Each of the lower wires 225 is inserted to be adjacent to a bottom surface of each of the first body 223 and the second body 224, and is formed in a bilateral trapezoidal shape to form the first body 223 and the second body 224. Deformation to the pressure of the seawater delivered to the lower edge of each of these is prevented.

Each of the upper wires 226 is inserted to be adjacent to an upper surface of each of the first and second bodies 223 and 224, and is formed in a bilateral trapezoidal shape to form the first bodies 223 and the second bodies 224. Deformation to the pressure of the seawater delivered to each upper edge is prevented.

Each of the side wires 227 is formed to connect edges of each of the lower wire 225 and the upper wire 226 adjacent to the position where the first and second bodies 223 and 224 are joined to each other through wires. do.

In addition, the side wires 227 may have a pair of wires extending up and down in parallel in the concave protruding portions of the first body 223 and the second body 224 so that the upper wire 226 and the lower wire ( 225 is formed to connect.

Each of the lower fastening nuts 228 has corners of each of the lower wires 225 adjacent to a position where the first and second bodies 223 and 224 are joined to each other, and the first body 223 and the second body, respectively. A portion is exposed to engage with each of the lower wires 225 located in the concavely protruding portion of each of the 224 to couple the bolt to the outside of each of the buoyancy bodies 222 and 422.

Each of the upper fastening nuts 229 may have an upper wire 226 adjacent to a position where the first and second bodies 223 and 224 are joined to each other at the top of each of the first body 223 and the second bodies 224. The outer edges of each of the buoyancy bodies 222 and 422 in combination with each of the upper wires 226 located at the corners of each of the two and the concavely protruding portions of each of the first and second bodies 223 and 224. Some parts are exposed to allow bolts to be coupled to it.

The fastening parts 230 fasten bolts through grooves formed adjacent to positions of both sides where the first body 223 and the second bodies 224 are joined to each other to connect the first and second bodies 223 and 224. Combine with each other.

Specifically, each of the bolts of the fastening part 230 penetrates a part of both sides of each of the first body 223 or the second body 224 so that each of the bolts of the second body 224 or the first body 223 is formed. Combined with both edges.

Accordingly, each of the lower wires 225, the upper wires 226, and the side wires 227 may be coupled to each other, and may be inserted into each of the first body 223 and the second body 224 so that the buoyancy body ( The durability of each of the 222 and 422 is improved, and the assembling property is high through the lower fastening nut 228 and the upper fastening nut 229.

As shown in FIG. 4, each of the center frames 600 includes a first beam 620, a second beam 640, an upper beam 660, and a lower beam 680.

Each of the central frames 600 is disposed between the first and second buoyancy columns 220 and 420 to oppose the wave energy of the wave 10 that collides with the first and second buoyancy columns 220 and 420. To maintain the distance between the first and second buoyancy columns 220 and 420 and to prevent deformation of each of the first and second buoyancy columns 220 and 420.

The first beam 620 is formed to extend in the vertical direction along the concave rear surface of each of the buoyancy bodies 422 so that the buoyancy bodies 422 are connected to each other on the same vertical line. Combined with each.

In detail, the first beam 620 is formed in the form of an H beam, and consists of a vertical plate formed in the center, and an upper plate and a lower plate formed in an “H” form by being combined with upper and lower portions of the vertical plate, respectively. The upper or lower plates are tightly coupled to the front surface of the buoyancy bodies 422.

The second beam 640 is formed in the same H-beam shape as the first beam 620, the vertical plate formed in the center, the upper plate is formed in the form of "H" combined with each of the upper and lower portions of the vertical plate and The upper or lower plates formed of lower plates and formed at the rear of the second beam 640 are tightly coupled to the rear surfaces of the buoyancy bodies 222.

The upper beam 660 is formed in the form of an "H" beam through vertical plates coupled vertically between the upper and lower plates and the upper and lower plates, each end of which is the top front of the first beam 620. The other end is extended to a front by a predetermined distance and coupled to the rear surface of the second beam 640.

One end of the lower beam 680 is coupled with the flow preventing plate 442 in the form of a hook that surrounds the upper end of the flow preventing plate 442, and the other end extends by a predetermined distance toward the front to prevent the flow preventing plate 242. It is coupled to the flow preventing plate 242 in the form of a hook that surrounds the top of the).

Specifically, one end and the other end portion of the lower beam 680 is combined with each of the flow preventing plate 442 and the flow preventing plate 242 in the form of a hook, the central portion of each of the one end and the other end of the lower beam 680 It is formed in the form of an H beam that connects a portion and the other end portion to each other to maintain a stable distance between the heavy weight of the flow preventing plates (242, 442).

The lower beam 680 is preferably installed to be parallel to the upper beam 660, and may be changed according to the seabed situation or the wave energy of the wave 10, and additionally depending on the weight of the flow preventing plates 242 and 442. The upper beams 660 and the lower beams 680 may be installed.

One end portion and the other end portion of the lower beam 680 are combined with the H-beam of the center through a bracket bent in a "b" shape, and each of the first beam 620 and the second beam 640 and the upper beam ( The coupling structure of one end and the other end of 660 is also coupled through the bracket.

5 and 6 show exploded perspective views of the perforated panels of FIG. 2.

As shown in FIG. 5, the perforated panel 444 includes a panel frame 445, frames 446, panel bodies 447, upper nuts 448, fixing panels 449, and side fixing panels. (450).

Each of the panel bodies 447 is formed in a rectangular plate shape, and a plurality of holes 50 penetrating each of the panel bodies 447 back and forth are formed so that when the wave 10 collides, part of the sea water is a hole 50. Move forward through the) and the rest flows in a state in which the wave energy is reduced by the panel body 447.

Since a portion of the seawater is moved toward the coast through the holes 50, the panel body 447 is prevented from being subjected to excessive pressure, thereby preventing damage to the panel body 447 and overturning of the floating breakwater 100. There is this.

The perforated panel 444 is coupled to each other in a state in which eight panel bodies 447 are vertically stacked in two rows of the perforated panel 444, and four panel bodies 247 to be described later are disposed at the corners of the rectangular parallelepiped shape. It is formed relatively higher than the perforated panel 244 coupled to each other.

The panel frame 445 is formed in a shape in which the wire is bent in a rectangular shape and is inserted into the edge of each of the panel bodies 447. Each of the frames 446 crosses the inside of the panel frame 445 through the wire. It is inserted in the upper and lower portions of the panel frame 445 in the cross shape to improve the durability of the perforated panel 444.

Each of the upper nuts 448 is formed at the corners and both centers of each of the panel frames 445, and is coupled with the panel frame 445. A fixing panel 449, which will be described later, surrounds the edges of the panel bodies 447. The fixed panel 449 and the panel body 447 is fixed by coupling with the bolts in a close state.

The fixing panel 449 is formed in a plate shape extending to both sides, and is coupled to the upper and lower edges and the rear surface of the perforated panel 444 to fix the panel bodies 447 and closely contact the panel bodies 447 through bolts. It is coupled with the panel body (447).

Both ends of each of the fixing panels 449 are coupled to each of the plate-shaped side fixing panels 450 extending upward and downward through bolts or welding, and the side fixing panels 450 are extended toward the bottom to buoyancy. Engage with the sides of each of the sieves 422.

Therefore, the perforated panel 444 is closely coupled to the plurality of buoyancy bodies 422 located on both sides through the side fixing panel 450, and a portion of both sides is separated from the buoyancy bodies 422 by the wave 10. Even if there is an advantage that the position is maintained by the coupling force with the buoyancy body 422 located in the lower portion.

The perforated panel 242 includes a panel frame 245, a frame 246, a panel body 247, upper nuts 248, fixing panels 249, and side fixing panels 250.

The panel body 247 is formed in a rectangular plate shape, and a plurality of holes 50 penetrating back and forth through the panel body 247 is formed so that when the wave 10 collides, part of the sea water passes through the holes 50. It moves forward and the rest flows in a state where the wave energy is reduced by the panel body 247.

Since a portion of the seawater is moved toward the coast through the holes 50, the panel body 247 is prevented from being subjected to excessive pressure, thereby preventing damage to the panel body 247 and overturning of the floating breakwater 100. There is this.

The perforated panel 244 is in close contact with each other in a state in which four panel bodies 247 are disposed at positions corresponding to each of the corners of the rectangular perforated panel 244, and formed relatively lower than the perforated panel 444. do.

Each of the panel frames 245 is formed of a wire bent in a rectangular shape to be inserted into an edge of each of the panel bodies 247, and upper nuts 248 are coupled to each corner.

Each of the frames 246 is combined with each of the panel frames 245 in a state where they cross each other in a cross shape inside the panel frame 245 to improve durability against wave energy by the waves 10.

Each of the upper nuts 248 is coupled to each corner of each of the panel frames 245, and the side fixing panel 250, which will be described later, is coupled to the bolts while being in close contact with both sides of the panel bodies 247. It is coupled with the panel body 247 through.

The fixing panel 249 is formed in a plate shape extending to both sides, and is coupled to the upper and lower edges and the rear surface of the perforated panel 244 to fix the panel bodies 247 and are coupled with the panel bodies 247 through bolts. .

Both ends of each of the fixing panels 249 are coupled to each of the plate-shaped side fixing panels 250 extending up and down by bolts or welding, and the side fixing panels 250 are extended toward the bottom to be buoyant. Are associated with the sides of each of the sieves 222.

The side fixing panel 250 is formed in a plate shape extending in the upper and lower parts, is in close contact with both sides of the panel body 247 coupled to each other is coupled to the panel body 247 through the bolts.

The side fixing panel 250 is in close contact with the buoyancy bodies 222 constituting each of the second buoyancy columns 220 in a part extending toward the bottom and spaced apart from each other.

Therefore, the perforated panel 244 is closely coupled to the plurality of buoyancy bodies 222 positioned on both sides through the side fixing panel 250, and portions of both sides are separated from the buoyancy bodies 222 by the waves 10. Even if it is there is an advantage that the position is maintained by the coupling force with the buoyancy body 222 located below.

FIG. 7 shows a perspective view of the floating breakwater of FIG. 2 from another angle. FIG.

8 is an enlarged perspective view illustrating a coupling structure of the flow preventing plates and the first beam of FIG. 2.

As shown in FIGS. 7 and 8, the floating breakwater 100 includes fastening plates 850, fixing plates 900, and side fixing plates 950.

Each of the fastening plates 850 is formed in a rectangular plate shape, and the buoyancy bodies 422 are in close contact with a portion of the rear surface of each of the buoyancy bodies 422 while the buoyancy bodies 422 are vertically stacked on each other. Are fastened with each of them.

In addition, each of the fastening plates 850 is in close contact with a part of the front surface of each of the buoyancy bodies 222 in a state where each of the buoyancy bodies 222 are vertically stacked on each other, and is fastened to each of the buoyancy bodies 222 through bolts. To improve the coupling force of each of the buoyancy body (222).

3, 7 and 8, the upper end of each of the fastening plates 850 is coupled with the lower fastening nuts 228 of each of the buoyancy bodies 222 and 422 stacked on the upper side, and the fastening plate ( The lower end of each of the 850 is fastened to the upper fastening nut 229 of each of the buoyancy bodies 222 and 422 stacked on the lower part, and the upper wire 226 inserted into each of the buoyancy bodies 222 and 422. ) And the lower wire 225 are connected to each other.

Therefore, each of the buoyancy bodies 222 or the buoyancy bodies 422 are connected to each other by connecting the upper wires 226 and the lower wires 225 inserted therein through the fastening plates 850 in a vertically stacked state. The durability of the wave 10 of the first buoyancy column 220 or the second buoyancy column 420 is significantly increased.

One end of the fixing plate 900 is formed in the form of a plate coupled to the front of the first beam 620 to be in close contact with the buoyancy body 422 disposed on both sides of the flow preventing plate 442.

The other end of the fixing plate 900 extends toward the inside of the flow preventing plate 442 at both sides of the flow preventing plate 442, and is inserted into each of the flow preventing plates 442, and the flow preventing plates 442 are provided. Two fixing plates 900 are arranged on each side of the same vertical line to be spaced apart from each other at a predetermined interval.

In addition, one end of the fixing plate 900 is formed in the form of a plate coupled to the back of the second beam 640 that is in close contact with the buoyancy body 222 disposed on both sides of the flow preventing plate 242.

The other end of the fixing plate 900 extends toward the inside of the flow preventing plate 242 at both sides of the flow preventing plate 242 and is inserted into each of the flow preventing plates 242, and the flow preventing plate 242 Two fixing plates 900 are arranged on each side of the same vertical line to be spaced apart from each other at a predetermined interval.

Therefore, the fixed plate 900 improves the coupling force between the flow preventing plate (242, 442) and each of the first and second buoyancy columns (220, 420) so that the floating breakwater (100) to the wave (10) When the inclination toward the front or rear by a stable maintenance function to return to the original state, the other end increases the durability of each of the check plate 242, 442 inside each of the check plate (242, 442) There is an advantage to stably support the heavy-duty flow preventing plates (242, 442).

Meanwhile, the floating breakwater 100 sequentially couples the perforated panels 244 and 444 and the flow preventing plates 242 and 442 to the outside of each of the front and rear breakwaters 200 and 400 and the center frame 600. By combining with each other can be expanded to a size suitable for the area to block the wave (10).

The side fixing plate 950 is formed in the form of a plate extending upward and downward and is coupled to the bottom fastening nut 228 and bolts exposed on the outer surface of each of the vertically stacked buoyancy bodies 222 and 422.

 The side fixing plate 950 is coupled to the other side of the buoyancy bodies 222 and 422, one side of which is coupled to each of the flow preventing plates 242 and 442, to improve the coupling force of the buoyancy bodies 222 and 422, and the buoyancy body ( The other side of each of the 222 and 422 is prevented from spreading.

Meanwhile, the front breakwater 200 or the rear breakwater 400 may be used as the floating breakwater 100 alone by connecting the front and the rear with the anchor 800 through a wire or a chain, respectively.

In addition, the floating breakwater 100 may be used as a floating solar power plant to generate electricity by combining a solar panel on the top, and may be used to protect yachts anchored offshore from the waves 10. .

Although the preferred embodiments of the present invention have been described with reference to the accompanying drawings, the embodiments described in the specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention and represent all of the technical idea of the present invention. It is to be understood that there may be various equivalents and variations in place of them at the time of the present application. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from an equivalent concept should be construed as being included in the scope of the present invention.

100: floating breakwater 200: front breakwater
400: rear breakwater 600: center frame

Claims (5)

First buoyancy columns disposed to be spaced apart from each other to form a first passageway;
A perforated panel coupled to the first buoyancy columns at an upper portion of the first passage and having a plurality of holes penetrating the front and rear surfaces; And
And a flow preventing plate coupled to the first buoyancy columns at the bottom of the perforated panel.
The flow preventing plate is a floating breakwater, characterized in that the weight is formed relatively higher than the perforated panel.
The method of claim 1,
Floating breakwater, characterized in that the expansion by combining the perforated panel, the flow preventing plate and the first buoyancy columns in addition to the outside of each of the first buoyancy columns.
The method of claim 1,
Second rear buoyancy columns disposed at the rear of the first buoyancy columns to form a second passage, a rear breakwater including a perforated panel and a flow preventing plate coupled to the second buoyancy columns to expand and couple; Floating breakwater.
The method of claim 3,
A central frame formed so that front and rear portions are in close contact with the rear surface of the first buoyancy column and the front surface of the second buoyancy column and connect the first and second buoyancy columns to be spaced apart from each other; And
Floating breakwater further comprises anchors coupled to each of the first and second buoyancy columns through a wire or chain and fixed to the seabed.
The method of claim 3, wherein each of the first and second buoyancy columns,
Floating breakwater comprising a; buoyancy units surrounding the wire frame formed therein are bonded to each other and formed in a cylindrical shape and buoyancy stacked vertically.

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