KR200338794Y1 - Structure of prestress box revetment to prevent coastal corrosion - Google Patents

Abstract

The present invention relates to the structure of the prestress box retaining wall for preventing coastal erosion, and forms a space part of the enclosure to attenuate the energy of waves and langua in front of an upright retaining wall that supports the coastal structure and prevents its collapse. It is to prevent coastal erosion caused by.

The present invention for this purpose, the upright retaining wall (10) for supporting the construction of the coastal road 29 and the like to prevent the collapse;

A protrusion 11 protruding forward by a predetermined width from an upper end of the upstanding retaining wall 10 to prevent the rise of waves 25;

A foundation slab 13 projecting rearward by a predetermined width from the bottom rear surface of the upstanding retaining wall 10 for preventing the fall of the present invention;

A overflow barrier 12 for forming a wave energy damping space portion 15 of the enclosure in a state parallel to the upstanding retaining wall 10 at a distance spaced apart from the upstanding retaining wall 10;

As the space of the enclosure formed between the upstanding retaining wall 10 and the upstream bulkhead 12, the wave 25 that intrudes temporarily beyond the upstream bulkhead 12 is trapped to decelerate the kinetic energy and to the dual eye 26. A wave energy attenuation space 15 which is converted and discharged into a binocular energy attenuation space;

Supports the coastal bottom 28 in a state parallel to the overflow bulkhead at a distance spaced apart from the overflow bulkhead and prevents its collapse, and forms an ionic flow energy attenuation space portion 17 of the enclosure to form a dual eye 26. A overflow wall 14 which prevents erosion of the coastal bottom 28 by the wall;

In the space of the enclosure formed between the overflow wall 12 and the overflow wall 14, when the lancular flow 26 converted from the wave is discharged through the drain 23 of the overflow wall, it spreads widely and vortex phenomenon A binocular energy attenuation space 17 for attenuating the potential energy of the binocular 26;

Left and right side walls 16a and 16b connecting and integrating both ends of the upright retaining wall 10 and the protrusion 11 and the upstream partition 12 and the upstream wall 14 from both ends of the fall prevention basic slab 13. It is characterized by consisting of).

Description

Structure of prestress box revetment to prevent coastal corrosion}

The present invention relates to a prestress box retaining wall for preventing coastal erosion, and more particularly, to a structure of a coastal retaining wall that attenuates coastal erosion by attenuating the kinetic energy of waves and potential energy of languae.

General coastal erosion and sedimentation are natural phenomena of repeated erosion and sedimentation due to the action of waves coming from the sea and the coastal streams generated by tidal currents and tidal currents, currents, winds, and streams converted by the waves hitting the shore. As such erosion and sedimentation have been balanced, the coastline has been in its shape for a long time.

In recent years, however, as artificial structures such as breakwaters, dikes, and coastal roads are constructed one after another, the size and direction of waves, lanyards, and coastal streams have changed, causing coastal erosion and sedimentation in unexpected places.

In order to prevent the coastal erosion over the last few decades, many countries and many people have developed and installed various coastal structures, such as languages, pier and submerged. However, the structures installed without understanding the cause of coastal erosion are causing problems to expand and accelerate the coastal erosion.

The present invention devised to solve the above problems, by forming the space portion (15, 17) of the enclosure for attenuating and converting the kinetic energy of the wave and the potential energy of the dual eye in the front of the standing retaining wall, It is an object of the present invention to provide a coastal erosion prestress box retaining wall that can prevent coastal erosion caused by vines.

1 is a right elevation view showing an embodiment of the present invention

2 is a left side elevation view showing an embodiment of the present invention

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a cross-sectional view showing an example of the use state of the present invention

5 is an elevation view showing an example of the use state of the present invention

6 is an enlarged partial cross sectional view of a bolted sidewall;

7 is a top plan view showing an embodiment of the present invention

8 is a bottom plan view showing an embodiment of the present invention

9 is a front view showing an embodiment of the present invention

10 is a rear view showing an embodiment of the present invention

11 is a right side view showing an embodiment of the present invention

12 is a left side view showing an embodiment of the present invention

13 is a cross-sectional view of the sole plate

14 is an elevation view showing an embodiment of a plurality of fastened state of the present invention as an embodiment

<Explanation of symbols for main parts of drawing>

10 upright retaining wall 11 protrusion 12 overflow wall

13: foundation slab for preventing fall 14: overflow wall

15: wave energy attenuation space portion 16a, 16b: side wall

17: lancular energy attenuation space portion 18: sole plate

19 fastening hole 20 fastening bolt 21 fastening washer nut

22: Bleeding extension 23: Drain hole 24: Foundation structure (sole concrete)

25: Wave 26: Ian 27: The Sea

28: shore (coastal bottom) 29: road (coastal road)

30: existing coastal retaining wall 31: sidewalk (sidewalk)

The present invention for achieving the above object is an upstanding retaining wall for supporting a structure such as a coastal road to prevent the collapse;

A protrusion protruding forward by a predetermined width from the top of the upstanding retaining wall to prevent the rise of waves;

A foundation slab projecting rearward by a predetermined width from the bottom rear surface of the upstanding retaining wall for preventing the fall of the present invention;

A overflow barrier rib forming a wave energy damping space portion of the enclosure in a state parallel to the upstanding retaining wall at a distance spaced from the upstanding retaining wall;

The space of the enclosure formed between the upstanding retaining wall and the overflow bulkhead, which traps the waves entering the moment beyond the overflow bulkhead to attenuate the kinetic energy, and converts them into lysates and discharges them into the lysine energy attenuation space. Wow;

The overflow stream supporting the coastal floor in a state parallel to the overflow stream bulkhead at a distance spaced apart from the overflow stream bulkhead to prevent its collapse and forming an angular energy decay space portion of the enclosure to prevent loss of the coastal floor by the ly flow. The wall;

An angular flow which is a space of the enclosure formed between the overflowed wall and the overflowed wall, and when the lysine transformed from the wave is discharged through the drainage outlet of the overflowed wall, it diffuses widely and causes vortex to attenuate the potential energy of the lysate. An energy attenuation space portion;

It provides a structure of the coastal erosion-prevention prestress box retaining wall, characterized in that the left and right side walls to connect and integrate both the upright retaining wall and the protrusion and the overflow bulkhead and the both ends of the overflow wall from both ends of the fall prevention basic slab.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 14 as follows.

1 is a right elevation view showing an embodiment of the present invention,

Figure 2 is a left side elevation view showing an embodiment of the present invention,

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a cross-sectional view showing an embodiment of the use of the present invention,

5 is an elevation view showing an embodiment of a use state of the present invention,

6 is an enlarged partial cross-sectional view of a bolted sidewall;

7 is a top plan view showing an embodiment of the present invention,

8 is a bottom plan view showing an embodiment of the present invention,

9 is a front view showing an embodiment of the present invention,

10 is a rear view showing an embodiment of the present invention,

11 is a right side view showing an embodiment of the present invention,

12 is a left side view showing an embodiment of the present invention,

13 is a cross-sectional view of the sole plate,

Figure 14 is an elevation view showing an embodiment of a plurality of fastened state of the present invention,

Embodiments of the present invention include an upstanding retaining wall 10 that supports a structure such as a coastal road 29 and prevents collapse thereof;

A protrusion 11 protruding forward by a predetermined width from an upper end of the upstanding retaining wall 10 to prevent the rise of waves 25;

A foundation slab 13 projecting rearward by a predetermined width from the bottom rear surface of the upstanding retaining wall 10 for preventing the fall of the present invention;

A overflow barrier 12 for forming a wave energy damping space portion 15 of the enclosure in a state parallel to the upstanding retaining wall 10 at a distance spaced apart from the upstanding retaining wall 10;

As the space of the enclosure formed between the upstanding retaining wall 10 and the overflow bulkhead 12, the wave 25 that intrudes temporarily beyond the overflow partition 12 is trapped to decay the potential energy and into the lysine 26. A wave energy attenuation space 15 which is converted and discharged into the binocular energy attenuation space;

Supports the coastal bottom 28 in parallel with the overflowed bulkhead at a distance spaced apart from the overflowed bulkhead and prevents the collapse thereof, and forms an ionic flow energy attenuating space portion 17 of the enclosure to form a coastal surface by the dual flow. A overflow wall 14 to prevent erosion of the floor 28;

In the space of the enclosure formed between the overflow wall 12 and the overflow wall 14, when the language 26 converted from the wave is discharged through the drain port 23 of the overflow wall 12, and spreads it widely An eye flow energy attenuation space 17 for causing a vortex phenomenon to attenuate potential energy of the eye flow;

Left and right side walls 16a and 16b connecting and integrating both ends of the upstanding retaining wall 10, the protrusion 11, and the upstream partition wall 12 and the upstream wall 14 from both ends of the fall prevention basic slab 13. It is a structure composed of).

The present invention configured as described above will be described in more detail as follows.

Upstanding retaining wall 10; It is a structure excellent in durability and weatherability that can support a structure such as a coastal road 29 to prevent its collapse as well as to support the intense impact energy of the waves 25 coming from the sea 27.

The protrusion 11 is; Since the waves smashed against the lower part of the upright retaining wall violate the upright retaining wall 10 due to a drooping phenomenon, the coastal road and the like can be lost and flooded, and thus the upper part of the upright retaining wall is prevented. Protruding portion (11) is formed to prevent the waves from crossing the upright retaining wall (10).

And the sole plate 18 is fixed to the upper surface of the protrusions, and fastened to the hook of the crane during the movement and installation of the present invention to facilitate its movement and installation, and after the installation of the present invention is completed, such as street lights and guard rails It is supposed to be able to enter.

The overflow bulkhead 12; The top surface is formed as an inclined surface so that the waves 25 coming from the sea 27 can easily cross the overflow bulkhead 12 and enter the wave energy damping space 15 at one time.

The drain port 23 formed in the overflow partition wall; The kinetic energy and potential energy were attenuated when the entire wave which entered the wave energy attenuation space part at once was converted into an ionic flow at a time and was discharged to the eye flow energy attenuation space part 17 to flow toward the sea 27. Even if a large amount of languae 26 flows at a time, the coastal bottom 28 is eroded.

However, when discharging the irises 26 from the wave energy damping space 15, the irises 26 continue to be divided little by little during the period of the wave through a small drain 23 without discharging the whole irises at once. If it is discharged, the little drift flows little by little so that the coastal bottom 28 is not eroded, so that a certain amount of drainage holes 23 are formed on the overflow bulkhead to delay the discharge of the langues 26.

In this process, the sand introduced into the wave energy decay space portion 15 and the iris flow energy decay space portion 17 together with the waves 25 are also discharged toward the sea along with the drift through the drain port 23. Sand is not deposited in the damping space 15 and the binocular energy damping space 17.

Wave energy attenuation space 15; When the wave 25 coming from the sea 27 enters the overflow bulkhead 12 at one time, the intruded wave 25 is confined together with confinement in the wave energy attenuation space, thereby damping the kinetic energy of the wave. Of course, at the same time it is converted to lans and is discharged to the lancular energy attenuation space 17 through the drain port (23).

Overflow wall 14; The lysate 26 discharged from the drain 23 impinges on the overflow wall 14 to attenuate its potential energy, and the lysate 26, which has been damped by the potential energy, crosses the overflow wall 14 to the sea. The height of the top surface is the same as the height of the coast bottom 28 so as not to erode the shore bottom 28 as it flows, but is equal to or less than the top surface of the overflow bulkhead 12.

The binocular energy attenuation space 17; In the process, the potential energy of the myeloids 26 is diffused through the drain port 23 so as to strike the overflow wall 14 and diffuse widely in the ionic energy attenuation space 17, causing vortex phenomena. It is intended to attenuate.

Therefore, even if the lancular flows over the overflow wall 14 toward the sea, the languacan 26 with potential energy attenuated will not be able to erode the coastal bottom 28.

The left and right side walls 16b and 16a; In order to build the coastal retaining wall by placing the present invention as a unit and placing a plurality of the present invention on the shoreline, the sidewalls can be firmly integrated with the entire coastal retaining wall by fastening bolts (20, 21). The biting extension part 22 protrudes outward from the lower end of 16b, and the several bolt fastening hole 19 is formed in a horizontal state.

On the other hand, the plurality of bolt fastening hole 19 is formed by the method of forming when manufacturing the present invention and the method of drilling in the construction site.

Therefore, the present invention facilitates the installation of various coastal structures, including the construction of coastal roads, and has an effect of preventing coastal erosion by waves and lanyards.

Claims (6)

An upstanding retaining wall 10 supporting a construct such as a coastal road 29 to prevent its collapse; A protrusion 11 protruding forward by a predetermined width from an upper end of the upstanding retaining wall 10 to prevent the rise of waves 25; A foundation slab 13 projecting rearward by a predetermined width from the bottom rear surface of the upstanding retaining wall 10 for preventing the fall of the present invention; A overflow barrier 12 for forming a wave energy damping space portion 15 of the enclosure in a state parallel to the upstanding retaining wall 10 at a distance spaced apart from the upstanding retaining wall 10; As the space of the enclosure formed between the upstanding retaining wall 10 and the upstream bulkhead 12, the wave 25 that intrudes temporarily beyond the upstream bulkhead 12 is trapped to decay the kinetic energy and to the languae 26. A wave energy attenuation space portion 15 which is converted and discharged into the binocular energy damping space portion; Supporting the coastal bottom 28 in a state parallel to the overflow bulkhead at a distance spaced apart from the overflow bulkhead in front of the wall to prevent the blockage and to form the lancular energy attenuation space portion 17 of the enclosure to the lean flow 26 A overflow wall 14 which prevents erosion of the coastal bottom 28 by the wall; In the space of the enclosure formed between the overflow wall 12 and the overflow wall 14, when the lancular flow 26 converted from the wave is discharged through the drain 23 of the overflow wall, it spreads widely and vortex phenomenon A binocular energy attenuation space 17 for attenuating potential energy of the binocular 26 by generating a; Left and right side walls 16a and 16b connecting and integrating both ends of the upstanding retaining wall 10 and the protrusion 11 and the upstream partition 12 and the upstream wall 14 from both ends of the fall prevention basic slab 13. The structure of the prestress box retaining wall for preventing coastal erosion, characterized in that consisting of. The method of claim 1, The overflow partition 12 which guides a wave to the wave energy attenuation space part 15, A structure of a prestress box retaining wall for preventing coastal erosion, characterized in that the upper portion of the overflow bulkhead is formed as a slope so that waves can easily cross the overflow bulkhead. The method of claim 1, The drain port 23 formed in the overflow partition 12 is Coastal erosion prevention prestress box, characterized in that the drain partition 23 is formed in the overflow bulkhead 12 for delaying the release of the iris when the iris flow from the wave energy damping space portion to the iris energy damping space portion. Structure of the retaining wall. The method of claim 1, The left and right side walls 16b and 16a are In order to build a coastal retaining wall by mounting a plurality of the invention on a coastline using the present invention as a unit, the side wall is firmly integrated with the entire coastal retaining wall by fastening bolts (20, 21). The biting extension part 22 protrudes outward from the lower end of 16b. The structure of the prestress box retaining wall for preventing coastal erosion, characterized in that the plurality of bolt fastening holes 19 are formed in a horizontal state. The method of claim 1, Wave energy attenuation space 15, Waves that trap the waves 25 intruding into the temporary flow beyond the overflow wall 12 to attenuate the kinetic energy as well as convert them into languae 26 and discharge them into the language energy attenuation space 17. The structure of the prestress box retaining wall for preventing coastal erosion, characterized in that the energy attenuation space (15) is formed. The method of claim 1, The binocular energy attenuation space 17 is The bleeds discharged through the drain 23 impinge on the overflow wall 14 to cause the vortices to diffuse widely in the lysine energy attenuation space, and attenuate the potential energy of the lyre 26. Coastal erosion, characterized by the formation of an ionic flow energy attenuation space (17) that prevents the shore bottom (28) from being lost due to the lys (26) when the flow flows over the overflow wall (14) into the sea. Structure of prestress box retaining wall for prevention.