KR20090124351A - Sinkable vertical membrane breakwater - Google Patents

Abstract

PURPOSE: A sinkable vertical membrane breakwater is provided to construct easily with little cost and human by simplifying a structure, secure a view, and form a sea route easily by being installed when necessary. CONSTITUTION: A sinkable vertical membrane breakwater comprises a buoy(100), a vertical membrane(700), a mooring line(200), and a position adjustment unit(300). The buoy is selectively possible for air injection so that the buoy performs a breakwater role. The vertical membrane is arranged in a down direction by being connected with the buoy. One end of the mooring line is connected with the buoy, and the other end of the mooring line is fixed and coupled in seafloor and controls movement of the buoy. The position adjustment unit allows the buoy and the vertical membrane to be selectively floated, or controls the position for sinking.

Description

Submerged vertical membrane breakwater {SINKABLE VERTICAL MEMBRANE BREAKWATER}

The present invention relates to an erosion vertical membrane breakwater, and more specifically, the structure can be easily installed with a simple cost and manpower and equipment, and secured viewability by selectively installing on the sea surface only when necessary. At the same time, the present invention relates to an immersion vertical membrane breakwater that can easily form a passage through which a vessel passes.

1 is a side view showing the structure of a conventional breakwater.

As shown in the figure, the conventional breakwater is a wave energy that is partially supported firmly on the seabed and submerged in the seawater to block the flow of the seawater, and a portion of the upper portion protrudes above the seawater surface and is transmitted along the sea surface. It consists of the caisson part 10 which absorbs a blue wave, and the several tetrapods 20 provided in the circumference | surroundings of the caisson part 10. As shown in FIG.

The tetrapod 20 is to enhance stability of the structure by dispersing and absorbing waves, which are wave energy transmitted along the seawater surface, together with the caisson part 10.

However, the conventional breakwater has a problem that the construction cost is significantly increased when the existing ground is a soft ground as well as blocking the water pollution inside the harbor by blocking the sea water circulation inside and outside the harbor.

In addition, since the structure is permanently installed at a predetermined position during initial manufacture, there is a problem in that it is difficult to form a ship's route since the ship must bypass the breakwater when passing through the perimeter of the breakwater.

In view of the above, an object of the present invention is to provide a relatively low cost, manpower, and the like by using a shock absorber that can absorb high tensile loads and mooring excessive tensile loads in mooring lines instead of simply structure. It can be easily installed by equipment, and it can be installed on the sea surface only when necessary, so that the permanent structure can be replaced to secure additional static temperature and block long period wave in the sea where the incident wave is relatively small, and secure the view. At the same time, to provide an eroded vertical membrane breakwater that can easily form a passage for the vessel to pass.

The erosion vertical membrane body breakwater for achieving the object of the present invention as described above, buoys floating on the sea surface to selectively perform the role of the breakwater and is provided with air injection; A mooring line having one end connected to the buoy and the other end fixedly coupled to the sea bottom so as to prevent the buoy from flowing as the sea surface flows; The buoy and the vertical membrane body is characterized in that it is configured to include a position control unit for selectively floating or adjusting its position to settle on the sea floor.

As described above, the immersion vertical membrane breakwater according to the present invention can be easily constructed with low cost and manpower and equipment by simplifying the structure, and selectively installs it on the sea surface only when necessary, thereby preventing the function and long-period wave blocking. Of course, there is an effect that can easily form a sea passage through which the vessel passes while ensuring the view of the offshore.

Hereinafter, with reference to the accompanying drawings an erosion vertical membrane breakwater according to an embodiment of the present invention in more detail as follows.

2 is a side view showing a structure in which the submerged vertical membrane breakwater according to an embodiment of the present invention is floating on the sea surface, Figure 3 is a submerged vertical membrane breakwater according to an embodiment of the present invention is settled to the sea floor 4 is a cross-sectional view showing the structure of the shock absorber of FIGS. 2 and 3, and FIGS. 5, 6 and 7 are cross-sectional views showing other components of the shock absorber, and FIG. 9 is a side view showing a structure in which the submerged vertical membrane breakwater breaks up to the sea surface according to another embodiment of the present invention, and FIG. 9 is a view illustrating a structure in which the submerged vertical membrane breakwater breaks down to the sea bottom according to another embodiment of the present invention Side view.

As shown in these figures, the submerged vertical membrane body breakwater according to an embodiment of the present invention, buoy 100 and buoy 100 that is floating on the sea surface to selectively perform air injection to perform the role of breakwater, and buoy 100 Mooring line 200 and buoy 100, one end of which is connected to the buoy 100 and the other end of which is fixedly coupled to the sea bottom so as to prevent the movement of the buoy 100 to restrain the movement of the buoy 100. ) Is configured to include a position adjusting unit 300 to selectively adjust the position to float on the sea surface or to settle to the sea bottom.

The buoy 100 is formed in a tubular shape that extends along the sea surface and is selectively formed to enable air injection therein, and is preferably formed of a material having elasticity to adjust its volume according to the degree of the moon wave.

The mooring line 200 is formed of a rope or chain, one end of which is coupled to the buoy 100 and the other end of which is fixedly coupled to the sea bottom, and has a length sufficient to allow the buoy 100 to float on the sea surface. On the line, the buoy 100 is provided with a shock absorber that can mitigate the impact generated during the flow.

The shock absorber is provided with a connector 411 at one end of the shock absorber so as to buffer the load due to the horizontal and rotational movement of the floating structure, and a buffer space therein, and a cylinder 410 in the longitudinal direction. A piston-shaped disk 420 is installed in the buffer space so as to be movable along the piston rod, one end is fixedly coupled to the piston 420 and the other end is formed to extend through the one end of the cylinder 410 to the outside ) And an elastic member provided between the piston 420 and the other end of the cylinder 410.

The cylinder 410 is provided with a buffer space therein, one end 413 is provided with a connector 411 protruding a predetermined length along the thickness direction and a ring formed at the end, one end and the other end In 414, an orifice hole 412 having a predetermined diameter is formed in plural through the circumferential direction.

As shown in FIG. 7, both ends of the cylinder 410 may be provided with a cylindrical viscoelastic anti-vibration rubber 600 having a predetermined height so as to more efficiently cushion the externally acting shock. .

The buffer space of the cylinder 410 is provided with a disk-shaped piston 420 having a diameter substantially the same as the cylinder 410 and installed to be movable along the longitudinal direction of the cylinder 410, one side of the piston 420 The piston rod 430 is fixedly coupled.

One end of the piston rod 430 is fixedly coupled to the piston 420, the other end is formed to extend through the center of the other end 414 of the cylinder 410, the outer end is formed, the end of the annular connector 431 is formed have.

The elastic member has a smaller diameter than the cylinder 410 so as to be accommodated in the buffer space of the cylinder 410, and is formed to narrow the spring pitch interval toward one side, the cylindrical non-linear spring 440 that increases the elastic modulus as the displacement increases It may be made of a conical non-linear spring 441 that is formed so as to decrease toward one side of the diameter is increased to increase the elastic modulus while increasing the displacement.

In addition, by arranging the plurality of compression coil springs 510, 520, and 530 of different lengths overlapping the periphery of the piston rod 430, the elastic modulus increases while the displacement increases, so that the cushioning action can be efficiently performed.

When overlapping a plurality of springs, support jaws 431 and 432 capable of supporting the respective compression coil springs 510, 520, and 530 on the piston rod 430 are provided along the radial direction of the piston rod 430. It should be formed to protrude to a predetermined length.

The position adjusting unit 300 may be configured as a winding device 320 having a driving motor 310 fixedly coupled to the sea bottom and selectively winding the vertical membrane body 700, as shown in FIGS. 8 and 9. As in another embodiment of the present invention, the position adjusting unit 300 is the winding device 320 is fixedly coupled to the sea bottom, one end is connected to one side of the buoy 100 and the other end of the winding device 320 Is connected to the drive shaft of the drive motor of 321 is composed of a rope or chain 310 is selectively wound in accordance with the drive of the drive motor 321.

The vertical membrane body 700 includes a plurality of offset holes 710 are formed on the surface of the vertical membrane body 700, the offset hole 710 formed in the vertical membrane body 700 located on one side and the other side located The offset holes 710 formed in the vertical membrane body 700 are alternately arranged to be more effective in buffering the impact force of the wave.

Since the winding device 320 is fixedly coupled to the sea bottom and is always in contact with water, the outer surface of the winding device 320 is preferably waterproof to prevent corrosion of the driving motor 320 therein. It is effective to adjust to.

When the impact force of the wave acts on the buoy 100, one end is connected to the buoy 100 and the other end is connected to the chain or rope 200 so as to more effectively absorb or disperse the impact force to prevent the flow of the buoy 100. Auxiliary mooring line 500 is further connected to.

The auxiliary mooring line 500 has the same configuration as the mooring line 200, and the shock absorber 400 is provided on the line like the mooring line 200.

The operation of the erosion vertical membrane breakwater according to an embodiment of the present invention configured as described above is as follows.

When the wave height is low, the chain of the position adjusting unit 300 or the rope 700 is wound around the winding device 320 in a state where air is not injected into the buoy 100 so that the buoy 100 is close to the sea bottom. As it is located, the view is secured and the ship can pass easily.

When the wave height is increased due to the typhoon or the wind, the air is injected into the buoy 100 and at the same time, the driving motor 321 of the winding device 320 operates to wind the vertical membrane body 700 which is wound on the driving shaft. Or buoy 100 due to the buoyancy of the air filled in the buoy 100 because the rope or chain 310 (another embodiment of the present invention) is loosened and air is injected onto the sea surface. Installation of the buoy 100 is complete.

After the installation of the buoy 100 and the vertical membrane body 700 is completed, the impact load due to the blue acts on the buoy 100, the cylinder 410 of the shock absorber 400 and the auxiliary shock absorber 500 The piston 420 and the piston rod 430 installed in the buffer space are drawn out of the cylinder along the height direction of the cylinder 410.

At this time, the impact load is buffered by the nonlinear spring 440 installed between the piston 420 and the bottom of one side of the cylinder 410. Unlike the linear spring, the nonlinear spring 440 increases the elastic modulus according to the displacement. Even if a large displacement occurs, no secondary fluctuations occur, so that the impact load can be gradually absorbed even more reliably with less displacement.

In addition, water flows through the orifice hole 412 provided on both bottom surfaces of the cylinder 410 and generates friction and jet flow, thereby generating kinetic energy of the piston 420 and the piston rod 430. By further reducing the buffering effect, the chain or the rope 200 can be prevented from being cut by the external force, and at the same time, it can stably prevent the moon wave.

In addition, the impact force of the waves generated on the surface of the seawater through the above-described process is buffered by the buoy 100, the impact force generated in the seawater is offset holes formed alternately in the plurality of vertical membrane body 700 ( It is canceled while passing through 710 to buffer its impact force.

When the crest is calm again, the air injected into the buoy 100 is discharged to the outside and the drive motor 321 of the winding device 320 is operated to operate the vertical membrane body 700 (an embodiment of the present invention) or a chain or rope. By gradually winding (310, another embodiment of the present invention) on the drive shaft, the buoy 100 moves again close to the sea floor, thereby securing viewability and easily forming a passage through which the vessel passes.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a side view showing the structure of a conventional breakwater,

2 is a side view showing a structure in which the submerged vertical membrane breakwater according to an embodiment of the present invention is floating on the sea surface,

Figure 3 is a side view showing a structure in which the submerged vertical membrane breakwater sedimented to the sea floor according to an embodiment of the present invention,

4 is a cross-sectional view showing the structure of the shock absorber of FIGS. 2 and 3;

5, 6, and 7 are cross-sectional views showing other components of the shock absorber,

8 is a side view showing a structure in which the submerged vertical membrane breakwater according to another embodiment of the present invention is floating on the sea surface,

9 is a side view showing a structure in which the submerged vertical membrane breakwater is settled to the sea bottom according to another embodiment of the present invention.

** Description of the symbols for the main parts of the drawings **

100: buoy 200: mooring line

300: position adjusting unit 310: chain or rope

320: winding device 400: shock absorber

410: cylinder 411, 431: connector

412: orifice hole 420: piston

430: piston rod 440: non-linear spring

500: auxiliary mooring line 600: viscoelastic dustproof rubber

700: vertical membrane body 710: offset hole

Claims (13)

A buoy floating on the sea surface to selectively serve as a breakwater and optionally provided with air injection; A vertical membrane body connected to the buoy and disposed vertically downward; A mooring line having one end connected to the buoy and the other end fixedly coupled to the sea bottom so as to prevent the buoy from drifting as the sea surface flows; The buoyancy and vertical membrane body breakwater, characterized in that it comprises a position control unit for adjusting the position of the buoy and the vertical membrane body to selectively float or settle to the sea bottom. The method of claim 1, The vertical membrane body breakwater piercing vertical membrane body characterized in that a plurality of offset holes are formed through. The method of claim 2, The vertical membrane body breakwater piercing vertical membrane body characterized in that it is provided in plurality. The method of claim 3, Offset holes provided in each of the plurality of vertical membrane bodies are reciprocating vertical membrane membrane breakwater, characterized in that arranged alternately with each other. The method of claim 1, The mooring line is a breakwater vertical membrane breakwater, characterized in that the one end is coupled to the buoy and the other end is formed of a rope or chain fixedly coupled to the sea bottom. The method of claim 5, The submerged vertical membrane breakwater, characterized in that the auxiliary mooring line is further fixedly coupled to the bottom surface and the other end is connected to the vertical membrane body. The method of claim 6, On the mooring line and the auxiliary mooring line immersion vertical membrane breakwater, characterized in that the buffer is provided that can mitigate the impact generated when the buoy flows. The method of claim 7, wherein The shock absorbing device includes a cylinder having a connector at one end and a buffer space provided therein, a piston installed in the shock absorbing space to be movable along the longitudinal direction of the cylinder, and one end fixedly coupled to the piston and the other end An immersion vertical membrane breakwater, comprising: a piston rod extending through the other end of the cylinder and extending outward; and an elastic member provided between the piston and the other end of the cylinder. The method of claim 8, The elastic member is a breakthrough vertical membrane body breakwater, characterized in that it is provided with a non-linear spring in which the elastic modulus increases as the displacement increases. The method of claim 8, Both ends of the cylinder piercing vertical membrane breakwater, characterized in that a plurality of orifice holes are formed through. The method of claim 7, wherein A plurality of orifice holes are formed through the piston, and both sides of the cylinder are provided with cylindrical viscoelastic dustproof rubber having a predetermined height. The method of claim 1, The position adjusting part is a piercing vertical membrane body breakwater, characterized in that the winding device is fixedly coupled to the sea bottom surface to selectively wind the vertical membrane body. The method of claim 1, The position adjusting unit is composed of a winding device fixedly coupled to the sea bottom, and one end is connected to one side of the buoy and the other end is connected to the winding device, and optionally a rope or chain wound around the winding device. Eroded vertical membrane breakwater.

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