KR20110019863A - Automatic water level contolled breakwater - Google Patents

Abstract

PURPOSE: A water level coupling breakwater, composed of a pile, a floating tube, a breakwater structure, and a guide roller, is provided to automatically control the height relate to a water lever. CONSTITUTION: A water level coupling breakwater comprises a pile(1), a floating tube(2), a breakwater structure(3), and a guide roller(4). The pile is installed at a regular interval to expose the upper side on water surface and to bury the lower part on the ground. The floating tube floats on sea using buoyancy as a cylindrical tube in which the upper and lower is closed and the air is filled. The breakwater structure is connected to the floating tube. The guide roller connects the pile and the breakwater structure.

Description

Automatic Water Level Contolled Breakwater

The present invention relates to a breakwater that is a structure that protects the inner port by preventing waves from the open sea, and more specifically, various breakwaters have been erected with advanced technology today, but the installation cost is high, so the wave is not installed in an area Breakwaters and moorings for mooring small boats such as yachts and fishing boats. These are related to level-linked breakwaters that automatically move up and down with seawater.

The breakwater was first constructed using stone, but when the stone shortage started, hybrid breakwaters using both stone and concrete began to be built. In the 1940s, release-type sofa blocks were developed. Although it is used a lot, facility cost is high and construction period is also long, so various types of breakwaters are built according to the characteristics of the area.

The present invention, as described above, because the construction of the breakwater takes a lot of cost and time, and also takes up a lot of area, the invention to solve this problem can be installed with relatively low cost and short air in the area where the waves are not counting The purpose is to install a small breakwater that automatically adjusts the height depending on the water level.

The present invention is to install a breakwater on the seashore to the lower portion is buried underground, the upper portion is exposed to the surface of the pile installed at regular intervals; Two or more buoyant tubes which are clogged in the upper and lower parts and are filled with air and float in the sea water by buoyancy; A breakwater structure connected to the support tube to partially submerge in seawater and partially float on the surface of the water to weaken the progress of the wave; In the water level interlocking breakwater consisting of a guide roller device for connecting the pile and the breakwater structure, the support tube is formed with a metal bracket for the connection with the breakwater structure, the breakwater structure of the frame and the seawater and waves It is composed of a perforated plate formed with a hole to pass a portion, the frame is composed of a horizontal frame formed horizontally, a vertical frame formed vertically, and a reinforcing frame connected by reinforcing the horizontal frame and the vertical frame, In the horizontal frame, a first bracket coupled to the metal bracket of the support tube and a second connecting member coupled to the guide roller device are formed. The metal bracket is installed between the bracket body and the support tube and the bracket body. Elastic band to give elasticity, elasticity when combined with the breakwater structure Composed of an elastic block for absorbing the impact of the primary wave, and the push button is installed between the metal bracket and the first bracket coupled to the bolt and pressing the elastic block, the guide roller device is a roller device frame to form an outer shape, and This problem can be solved by a water level interlocking breakwater, which is installed in a roller device frame and comprises a plurality of rollers to slide up and down of the pile, and a first connection member for connection with the breakwater structure.

When the breakwater is made of piles, flotation tubes and breakwater structures as in the present invention, the breakwater can be made inexpensively and quickly in areas where the waves are not very strong or in the deep water, and as a breakwater of a small ship or a breakwater of a yacht marina. It will work well.

The present invention is a pile (1) installed at regular intervals so that the lower part is buried underground, the upper part is exposed above the water surface to install a breakwater on the sea shore; Two or more buoyant tubes (2) floating in sea water by buoyancy as a cylindrical tube filled with air inside and clogged up and down; A breakwater structure (3) connected to the support tube (2) and partially submerged in seawater and partially floating on the surface of the water to weaken the progress of the wave; It is a water level interlocking breakwater composed of a guide roller device (4) connecting the pile (1) and the breakwater structure (3).

In detail, the support tube 2 is formed with a metal bracket 21 for connection with the breakwater structure 3, the breakwater structure 3 is a frame 31 and the seawater and waves forming a form It is composed of a perforated plate 32 is formed so that a portion of the passage through, the frame 31 is a horizontal frame 311 is formed horizontally, the vertical frame 312 is formed vertically, and the horizontal frame ( 311) and a reinforcing frame 313 for reinforcing by connecting the vertical frame 312, the first frame (3111) coupled to the metal bracket 21 of the support tube (2) to the horizontal frame (311) And, the second connecting member 3112 is coupled to the guide roller device 4 is formed.

The metal bracket 21 is provided between the bracket body 211, the support tube (2) and the bracket body 211 to give elasticity when the elastic band 212 and the breakwater structure is combined with the elastic body An elastic block 213 that absorbs the impact of waves, and a push button 214 installed between the metal bracket 21 and the first bracket 3111 and coupled to the bolt 215 to press the elastic block 213. It consists of

The guide roller device 4 is a roller device frame 41 to form an outer shape, and a plurality of rollers 42 are installed in the roller device frame 41 to be able to slide up and down of the pile (1) ) And a water level interlocking breakwater composed of a first connecting member 43 for connection with the breakwater structure 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall perspective view of a one-stage breakwater installed in the shallow depth of the water level interlocking breakwater according to the present invention, Figure 2 is a full perspective view of a three-stage or more breakwater installed in the depth of the water level interlocking breakwater according to the present invention. 3 is a perspective view of the flotation tube of the water level interlocking breakwater according to the present invention, Figure 4 is an exploded view of the fastening tube and the bracket of the breakwater structure of the water level interlocking breakwater according to the present invention, Figure 5 is a water level according to the present invention Figure 6 is a schematic view of the first embodiment of the breakwater structure of the interlocking breakwater, Figure 6 is a schematic view of a second embodiment of the breakwater structure of the water level interlocking breakwater according to the present invention, Figure 7 is a bracket connecting rod of the guide roller device of the water level interlocking breakwater according to the present invention Figure 8 is a schematic diagram of the connection of the guide roller set of the water level interlocking breakwater according to the present invention, Figure 9 is a water level according to the present invention Metal bracket body perspective view of the interlocking breakwater, Figure 10 is a perspective view of the elastic band coupled to the bracket body of the water level interlocking breakwater according to the present invention, Figure 11 is an elastic band perspective view of the water level interlocking breakwater according to the present invention, Figure 12 is the present invention The metal bracket and the elastic block and the elastic band coupled to the floating tube of the water level interlocking breakwater according to the perspective view.

The present breakwater of FIG. 1 illustrates a schematic component of a breakwater in which a one-stage breakwater structure is installed in a thin water depth, and the present breakwater in FIG. 2 schematically illustrates a breakwater in which a three-stage breakwater structure is installed in a deep water depth. Although it shows a composition of phosphorus, depending on the environment, such as the depth and the intensity of the wave, the breakwater structure may be composed of two or more stages, the number of the pile (1) is shown according to the area where the breakwater is to be installed Breakwaters of the same structure are installed continuously.

As shown in Figures 1 and 2, the present invention provides a pile (1) installed at regular intervals so that the lower part is buried underground, the upper part is exposed on the water surface to install a breakwater on the sea shore; Two or more buoyant tubes (2) floating in sea water by buoyancy as a cylindrical tube filled with air inside and clogged up and down; A breakwater structure (3) connected to the support tube (2) and partially submerged in seawater and partially floating on the surface of the water to weaken the progress of the wave; Water level interlocking breakwater consisting of a guide roller device (4) connecting the pile (1) and the breakwater structure (3), the flotation tube (2) is connected to the guide roller device (4) according to the water level (1) while climbing up and down the perforated plate 32 of the breakwater structure (3) to block or weaken the wave, the three-stage breakwater structure (3) is the breakwater structure (3) is attached to the support tube Floating breakwater structure (3a), the upper breakwater structure (3b) is installed on the buoyancy breakwater structure (3a) to weaken the waves traveling over the water surface, and installed in the bottom of the floating breakwater structure (3a) It consists of a lower breakwater structure 3c that weakens the progress.

The quantity and size of the floating tube (2) is calculated by calculating the weight of the breakwater structure (3) and the buoyancy of the buoyant tube (2) to sufficiently beat the weight of the breakwater structure (3) part of the breakwater structure (3) Is produced in the appropriate amount and size that can float on the water surface, by the guide roller device (4) to ride the pile (1) so that the breakwater structure (3) is well balanced according to the water level 2 Install more than

The pile 1 is buried and buried so that the tip of the pile reaches a solid ground so that it can support each structure without being knocked down by waves, and when the soft layer continues deeply and the pile cannot reach the solid ground, the pile and pile are buried. Buried deep enough to support the load by the frictional force of the, the installation interval of the pile is installed at regular intervals in consideration of the installation and handing of the floating tube (2) and the breakwater structure (3). The pile above the water surface is covered with a conical cap to prevent rainwater from entering.

As shown in Figure 3 and 4, the support tube (2) is a cylindrical tube filled with air in the upper and lower parts, it is made of Poly Ethylene (PE) material to reduce its own load, and strengthen the strength It is also preferable to be manufactured in a double tube structure.

The support tube (2) is formed with a metal bracket 21 for connecting to the breakwater structure (3), the metal bracket 21 is a bracket body 211, the support tube (2) and the bracket body The elastic band 212 is provided between the 211 to give elasticity, the elastic block 213 for absorbing the impact of the wave to give elasticity when combined with the breakwater structure, the metal bracket 21 and the first bracket Installed between the (3111) is coupled to the bolt 215 and consists of a pusher 214 for pressing the elastic block 213.

As shown in FIG. 5, FIG. 5-1 illustrates an embodiment in which the frame 31 is divided into two stages when the height of the breakwater structure 3 is high and there is a structural problem. 2 shows an embodiment in which the frame 31 of the breakwater structure 3 is made in one stage, and the quantity of the accessory components is the same.

The breakwater structure 3 is composed of a frame 31 and a perforated plate 32 formed with a hole so that a portion of sea water and waves can pass therethrough, and the frame 31 has a horizontal frame 311 formed horizontally. ), A vertical frame 312 formed vertically, and a reinforcement frame 313 for reinforcing by connecting the horizontal frame 311 and the vertical frame 312, the horizontal frame 311 is the support tube A first bracket 3111 coupled to the metal bracket 21 of (2) and a second connecting member 3112 coupled to the guide roller device 4 are formed, and the second connecting member 3112 is formed. The second connector 3112a of the bracket type is formed, and the bolt hole 3112a1 is formed in the second connector 3112a so that the guide roller device 4 and the breakwater structure 3 of the bracket are of the type of bracket. It is connected to each other as a connection.

The thickness or width of the members of the horizontal frame 311 and the vertical frame 312 and the reinforcement frame 313 of the frame 31 may be appropriately designed according to the spacing between the piles 1 and the size of each frame. It is preferable.

The perforated plate 32 is made of a rust-resistant stainless steel material, a hole is formed so that a portion can pass through without receiving the force of the wave directly, the hole is circular (○) or square (□) or △, It is formed by the assembly of ○, □, ▽ shape, the perforated area of the perforated plate 32 is 50 ~ 70% of the total perforated plate area does not receive all the force of the wave directly to increase the durability of the perforated plate and the force of the wave It is preferable because it attenuates.

As shown in FIG. 6, the present embodiment has the same content as that of FIG. 5, and when the breakwater structure is configured as a plurality of stages as shown in FIG. ) And the connection of the breakwater structure (3) is also a connecting ring type to connect flexibly without being subjected to direct waves, that is, the horizontal frame (311) and the metal bracket (21) of the support tube (2) The first bracket 3111 to be coupled, the second connecting member 3112 coupled to the guide roller device 4, the first connecting ring 3113 coupled to the breakwater structure on the top, and the breakwater on the bottom A second connection ring 3114 coupled to the structure is formed and connected by a connection ring, and the second connection member 3112 of the breakwater structure 3 is formed of a ring-type third connection ring 3112b, and Guide roller device (4) and the breakwater structure (3) It represents that are connected to each other in a ring.

As shown in FIG. 7, the guide roller device 4 is installed inside the roller device frame 41 and the roller device frame 41 to form an outer shape to move up and down of the pile 1. It consists of a plurality of rollers 42 and the first connecting member 43 for the connection with the breakwater structure 3, the first connecting member 43 is a triangular bracket type first connecting rod It is formed of a 431 is connected to the second connecting rod (3112a) of the breakwater structure (3) to allow the breakwater structure (3) to move freely up and down the pile (1), bolts in the bolt hole (4311) It is coupled to the second connecting rod (3112a) of the breakwater structure (3).

As shown in FIG. 7-1, only one side of the first connecting rod 431 is installed at the last pile when the pile 1 is installed continuously. The first connecting rod 431 may be attached to the left side. 7-2 is a guide roller device 4 installed on the pile 1 in the middle when the pile 1 is continuously installed on both sides of the first connecting rod 431.

Since the long rollers among the rollers 42 may be configured in a set of three, the rollers may be composed of a total of eight rollers, and the number of rollers may vary depending on the diameter of the pile.

The guide roller device 4 should be installed so as not to interfere with the pile 1, so that the guide roller device 4 can move freely up and down the pile 1 with a minimum of frictional resistance. In addition, the roller device frame 41 of the guide roller device 4 is made of a material that is not rust, the shape of the roller device frame 41 to facilitate the installation of each roller 42 and the first connecting member 43. It can be modified. The rollers 42 should have sufficient strength to overcome the impact when the roller device frame 41 and the rollers themselves collide with the pile by the waves, and the rollers can be replaced, and each material It is made of rust-resistant material.

As shown in FIG. 8, the other embodiment is the same as that of FIG. 7, and the guide roller device 4 assumes that the type of the first connection member 43 is the fourth connection ring 432 of the ring type. And the breakwater structure 3 are connected to each other by a connecting ring, and as shown in FIG. 8-1, only one side of the fourth connecting ring 432 is the last file when the file 1 is continuously installed. The fourth connecting ring 432 may be attached to the left side, and the fourth connecting ring 432 is located at both the left and right sides as shown in FIG. 8-2, so that the pile 1 may be continuously installed. The guide roller device (4) is installed in the pile (1) in the middle of the city, Figure 8-3 is a view of the connection between the fourth connecting ring 432 and the fourth connecting ring (3112b) of the breakwater structure (3) To show the filling with a nut (4321) so that the ring does not escape, the first edge of the breakwater structure (3) Ring 3113 and the second link 3114 is not how the connections are equally filled with the nuts (4321) come out of the ring and thereby damping the impact caused by the wave to be connected to a flexible block.

As shown in FIGS. 9, 10, and 11, the metal bracket 21 is provided between the bracket body 211 and the support tube 2 and the bracket body 211 to give elasticity to the elastic band ( 212, and the elastic block 213 to give elasticity when combined with the breakwater structure to absorb the impact of the wave, and is installed between the metal bracket 21 and the first bracket (3111) is coupled to the bolt 215 And a pusher 214 that presses the elastic block 213.

9 is a schematic view of the bracket body 211, and the bracket body 211 is a bolt hole 2111 for coupling to the bolt 215 with the first bracket 3111 of the breakwater structure (3) Is formed.

As shown in FIGS. 10 and 11, the elastic band 212 has a groove 2121 formed in the elastic band 212 to prevent the bracket body 211 from being separated from the elastic band 212. The main body 211 is fitted tightly.

As shown in FIG. 12, FIG. 12-1 is a view before the elastic block 213 is installed, and FIG. 12-2 is a view after the elastic block 213 is installed in the support tube 2. The metal bracket 21 is installed and the elastic block 213 is installed, and when the elastic block is properly protruded and pressed by the pusher 214, the flotation tube 2 and the breakwater structure 3 are shown. In combination with the elasticity it is possible to increase the durability of each structure.

The elastic band 212 and the elastic block 213 is made of urethane, rubber, synthetic rubber or silicone material to absorb the impact of the waves to increase the durability of the support tube (2) made of light PE material.

When the breakwater is made of piles, flotation tubes and breakwater structures as in the present invention, the breakwater can be made inexpensively and quickly in areas where the waves are not very strong or in the deep water, and as a breakwater of a small ship or a breakwater of a yacht marina. It will work enough.

1 is an overall perspective view of a single-stage breakwater installed in a shallow depth of the water level interlocking breakwater according to the present invention

Figure 2 is an overall perspective view of a three-stage or more breakwater installed in the depth of the water level interlocking breakwater according to the present invention

Figure 3 is a full perspective view of the support tube of the water level interlocking breakwater according to the present invention

Figure 4 is an exploded view of the fastening tube of the water level interlocking breakwater and the bracket of the breakwater structure according to the present invention

5 is a schematic view of the first embodiment of the breakwater structure of the water level interlocking breakwater according to the present invention

6 is a schematic view of a second embodiment of the breakwater structure of the water level interlocking breakwater according to the present invention;

7 is a schematic view of the bracket connecting rod of the guide roller device of the water level interlocking breakwater according to the present invention

Figure 8 is a schematic diagram of the connection of the guide roller set of the water level interlocking breakwater according to the present invention

9 is a perspective view of a metal bracket body of the water level interlocking breakwater according to the present invention

10 is a perspective view of the elastic band coupled to the bracket body of the water level interlocking breakwater according to the present invention

11 is a perspective view of the elastic band of the water level interlocking breakwater according to the present invention

12 is a perspective view of the metal bracket and elastic block and elastic band coupled to the floating tube of the water level interlocking breakwater according to the present invention

<Code Description of Main Parts of Drawing>

1: file

2: flotation tube 21: metal bracket

211: bracket body 2111: bolt hole

212: elastic band 2121: groove

213: elastic block 214: push

2141: bolt hole

215: Bolt 215a: Nut

3: breakwater structure 3a: floating breakwater structure

3b: upper breakwater structure 3c: lower breakwater structure

31: frame 311: horizontal frame

3111: first bracket 3111a: bolt hole

3112: second connecting member 3112a: second connecting rod

3112b: third link

3113: first connection ring 3114: second connection ring

312 vertical frame 313 reinforcement frame

32: punched plate

4: guide roller device 41: roller device frame

42: roller 43: first connecting member

431: first connecting rod 4311: bolt hole

432: 4th ring

SL: Sea level GL: Sea bottom

Claims (10)

A pile (1) installed at regular intervals so that the lower part is buried underground and the upper part is exposed on the water surface to install a breakwater on the sea shore; Two or more buoyant tubes (2) floating in sea water by buoyancy as a cylindrical tube filled with air inside and clogged up and down; A breakwater structure (3) connected to the support tube (2) and partially submerged in seawater and partially floating on the surface of the water to weaken the progress of the wave; In the water level interlocking breakwater consisting of a guide roller device (4) connecting the pile (1) and the breakwater structure (3), The support tube (2) is formed with a metal bracket 21 for connection with the breakwater structure (3), The breakwater structure 3 is composed of a frame 31 and a perforated plate 32 formed with a hole to pass a portion of the sea water and waves, The frame 31 has a horizontal frame 311 formed horizontally, a vertical frame 312 formed vertically, and a reinforcing frame 313 connecting and reinforcing the horizontal frame 311 and the vertical frame 312. Consisting of, The horizontal frame 311 is formed with a first bracket 3111 coupled to the metal bracket 21 of the support tube 2, and a second connecting member 3112 coupled to the guide roller device 4 is formed , The metal bracket 21 is provided between the bracket body 211, the support tube (2) and the bracket body 211 to give elasticity when the elastic band 212 and the breakwater structure is combined with the elastic body An elastic block 213 that absorbs the impact of waves, and a push button 214 installed between the metal bracket 21 and the first bracket 3111 and coupled to the bolt 215 to press the elastic block 213. ) The guide roller device 4 is a roller device frame 41 to form an outer shape, and a plurality of rollers 42 are installed in the roller device frame 41 to be able to slide up and down of the pile (1) And a first connection member (43) for connection with the breakwater structure (3). The method of claim 1, The breakwater structure 3 includes a floating breakwater structure 3a having a floating tube attached thereto, an upper breakwater structure 3b installed on the floating breakwater structure 3a to weaken waves traveling above the water surface, and the floating breakwater structure (3a) Water level interlocking breakwater, characterized in that consisting of a lower breakwater structure (3c) is installed in the lower portion to weaken the progress of the wave in the sea. The method of claim 1, The first connecting member 43 of the guide roller device 4 forms a first bracket 431 of a triangular bracket type, and the second connecting member 3112 of the breakwater structure 3 is formed of a bracket type first. The water level interlocking breakwater, characterized in that the guide roller device (4) and the breakwater structure (3) is connected to each other as a connection of the type of bracket, formed of two connecting rod (3112a). The method of claim 1, The first connecting member 43 of the guide roller device 4 forms a ring-shaped fourth connecting ring 432, and the second connecting member 3112 of the breakwater structure 3 is a ring-type third It is formed of a connecting ring (3112b), the water level interlocking breakwater, characterized in that the guide roller device (4) and the breakwater structure (3) is connected to each other by a connecting ring. The method according to claim 1 and 2, The horizontal frame 311 includes a first bracket 3111 coupled to the metal bracket 21 of the support tube 2, a second connecting member 3112 coupled to the guide roller device 4, and an upper portion thereof. The first link ring (3113) is coupled to the breakwater structure in the water level interlocking breakwater, characterized in that the second link ring (3114) is coupled to the breakwater structure in the lower portion. The method of claim 1, The support tube (2) is made of Poly Ethylene (PE) material, water level interlocking breakwater, characterized in that the double pipe structure for strength reinforcement. The method of claim 1, Water peristaltic breakwater, characterized in that the perforated area of the perforated plate 32 is 50 to 70% of the total perforated plate area. The method of claim 1, Water level interlocking breakwater, characterized in that the material of the elastic band 212 and the elastic block 213 is urethane, rubber, synthetic rubber or silicon material. The method of claim 1, A water level interlocking breakwater, characterized in that the shape of the hole formed in the perforated plate 32 is circular (○). The method of claim 1, A water level interlocking breakwater, characterized in that the shape of the hole formed in the perforated plate 32 is a combination of?,?,?,?.

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