KR20110021231A - Superstructure having many reflection block and breakwater, seawall using the same - Google Patents

Abstract

PURPOSE: A superstructure having multiple reflection blocks and a shore protection are provided to reduce construction costs and reduce reflecting wave by reduction in wave pressure. CONSTITUTION: A superstructure having multiple reflection blocks comprises a bottom plate(100), a parapet(200), and multiple reflection blocks(300). The parapet is projected to the upper part of the bottom plate. The reflection block is installed on the front part of the bottom plate to prevent a part of moonlit waves and reflect waves. The forward protrusion degree of the reflection block is not uniform.

Description

SUPRESTRUCTURE HAVING MANY REFLECTION BLOCK AND BREAKWATER, SEAWALL USING THE SAME}

TECHNICAL FIELD The present invention relates to the field of port technology, and in particular, to a top structure of an implosion structure.

An inner wave structure is a generic name including a breakwater for protecting the inner port from the blue waves of the outer port, and a shelter for protecting the beach structure from the blue waves.

The upper structure of the implosion structure is installed on the concrete structure, which is to prevent the overwhelming wave of the invasive wave, the height (floor height) is the importance of the rear area, the purpose of use, the height of the invasion wave, design It is determined by considering the water level, etc., and the height becomes very large when the wave is large or the tide difference is large.

In addition, since a predetermined weight is required to ensure stability from wave action, it is generally a large structure.

1 shows a conventional inclined breakwater (seat inclined).

As shown, the body sandstone (1) is built on the foundation ground to have both sides inclined, the covering stone (2) is provided to protect the front and rear inclined surface, a plurality of sofa blocks (3) are provided on the outside.

Here, the dam structure 10 is installed at the top of the breakwater, in order to prevent the dam structure 10 from being damaged or pushed by the blue, the covering height of the sofa block (3) is near the floor height of the dam structure (10) If the depth is deep or the soft ground is deep, there is a problem that the construction cost increases significantly.

Figure 2 shows a conventional caisson breakwater.

In order to prevent the amount of sandstone from being excessively deep, the foundation stone 1 is constructed only to a certain height, and a large number of caissons 4 are installed thereon, and then sand or the like is built into the caissons 4. By filling, the wall is stabilized.

In this case, the upper structure 10 is installed at the top of the caisson 4, in order to reduce the weight of the upper structure 10 while preventing the wave, the parapet 11 is installed on the upper surface of the upper structure (10). Sometimes.

However, in the case of taking such a structure, since the area of the front surface of the upper face structure 10 directly hit by the waves is large, the total wave pressure (horizontal component) acting on the structure is increased, and as the reflectance of the waves increases, the waves of the outer port become excessively large. there is a problem.

In addition, the width of the structure itself should be increased to secure the stability of the damaging structure 10. This requires not only a large amount of concrete but also additionally lowers the cost of mounds and ground improvement for the stability of the entire breakwater structure. There is a problem that occurs.

The present invention was derived to solve the above problems, the breakdown structure of the breakwater structure to reduce the wave pressure acting on the top structure of the lake, the wave structure and the reflected wave, while reducing the construction cost The purpose of the present invention is to propose a breakwater or a shelter using this.

The present invention, in order to achieve the object as described above, the bottom plate 100; A parapet 200 protruding upward from the bottom plate 100; And a plurality of reflection blocks 300 installed in front of the bottom plate 100 so as to reflect the blue wave while partially preventing the waves, and the plurality of reflection blocks 300 have a predetermined degree of protrusion toward the front. An upper structure of the implosion structure having a plurality of reflective blocks is provided.

The plurality of reflection blocks 300 may include a reflection block 300a in a first row disposed at the forefront; And a second row of reflection blocks 300b disposed behind the first row of reflection blocks 300a, wherein the first row of reflection blocks 300a and the second row of reflection blocks 300b are alternately disposed one by one. desirable.

It is preferable that the front surface of the reflective block 300 is inclined upward.

In the upper portion of the reflective block 300, it is preferable that the anti-jamming protrusion 310 protrudes forward.

The height of the reflective block 300 is preferably lower than the height of the parapet 200.

The parapet 200 is preferably front inclined upward.

The upper front of the parapet 200 is preferably the front anti-corrugation 210 is formed protruding.

It is preferable that the rear anti-weather prevention part 220 protrudes from the upper rear of the parapet 200, and the height of the rear anti-weather prevention part 220 is higher than the height of the front anti-weather prevention part 210.

It is preferable that the front surface of the rear anti-corrugation unit 220 has a concave curved structure toward the rear.

The present invention is another means for achieving the above object, together with the breakwater and the shelter provided with the dama structure is presented.

The present invention provides a breakwater structure and a breakwater using the same, and a breakwater using the same, which reduces the wave pressure acting on the breakwater, the breakwater, and the construction cost while reducing the construction cost.

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

As shown in Figure 3 below, the dama structure of the implosion structure according to the present invention basically, the bottom plate 100; A parapet 200 protruding upward from the bottom plate 100; In addition to preventing some of the wave wave, a plurality of reflective blocks 300 installed in front of the bottom plate 100 so as to reflect the blue, including, the plurality of reflective blocks 300 is not the degree of protrusion toward the front It is characterized by not.

In this structure, the energy of the blue waves transmitted from the outside of the term is partially reflected by a plurality of reflective blocks 300 installed so that the degree of protrusion toward the front is not constant, while the blue waves surpassing the energy due to the reflection above Since the weakened and then transmitted to the parapet 200, there is an effect that even if the height of the parapet 200 can be lowered to prevent the moon wave.

In addition, since the blue wave reflected by the parapet 200 is weakened again by the disturbance with the blue wave flowing over the reflective block 300 again, the reflected wave can be greatly reduced, thereby preventing the blue wave from increasing. .

That is, the conventional phase structure takes a structure that resists the wave energy only by the front surface and the parapet, but the phase structure according to the present invention adds a plurality of reflective blocks 300 to Since the pressure can be reduced efficiently, it is advantageous in that the size of the structure can be reduced to reduce the construction cost while sufficiently exhibiting the required implosion performance.

In addition, in order to increase the floor height of the upper teeth in order to further reduce the monthly wave, there is an advantage that it is possible without increasing the cost of construction.

EMBODIMENT OF THE INVENTION Hereinafter, the Example regarding the specific structure of the upper structure according to this invention is described.

The plurality of reflective blocks 300 are installed so that the degree of protrusion toward the front is not constant, thereby effectively reducing the wave energy, and this configuration may be implemented by various examples.

As shown in Figs. 3 and 4, the first row of reflective blocks 300a are disposed; And a second row of reflection blocks 300b disposed behind the first row of reflection blocks 300a, wherein the first row of reflection blocks 300a and the second row of reflection blocks 300b are alternately arranged one by one. In this case, there is an advantage that the construction and maintenance is convenient, but the above-described effects can be obtained as it is.

When the front surface of the reflective block 300 is formed in the vertical direction, excessive blue energy is applied thereto, so that the front surface of the reflective block 300 has an upwardly inclined structure, so that a part of the blue wave is reflected. It may be said that an efficient structure is to allow some parts to overflow and share the wave energy by the parapet 200 at the rear (FIGS. 5 and 6).

When the moon wave bumps 310 protrude forward in the upper portion of the reflective block 300, there is an advantage in that it is possible to effectively prevent the usual small wave moon wave (Figs. 5 and 6).

The reflection block 300 reflects only a part of the acting blue, and the rest of the blue wave, so as to share the energy of the blue with the parapet 200, for this purpose, the height of the reflection block 300 is parapet It is better to be lower than the height of 200.

Even in the case of the parapet 200, the front surface of the parapet 200 is preferably vertically inclined to prevent excessive wave energy from being applied (FIG. 7).

In this case, in order to minimize the blue wave flowing through the parapet 200, it is preferable that the front anti-wave wave 210 is protruded in the upper front of the parapet 200 (Fig. 7).

In order to more safely prepare for the case where the wave rises above the front anti-weather prevention unit 210, it is preferable to take a configuration in which the rear anti-weather prevention unit 220 protrudes from the upper rear of the parapet 200. It is preferable that the height of the anti-weathering unit 220 is higher than the height of the front anti-freezing unit 210.

Here, the rear anti-corruption unit 220 is the last structure to prevent the overflow of the blue wave, and the contacting blue is already weakened by the structure in front of the energy bar bar, the front of the rear anti-wave unit 220 It is desirable to ensure that blue waves are prevented by taking a concave curved structure toward the rear.

The dam structure according to the present invention does not disturb and attenuate the energy of the blue wave by one or two places as in the prior art, but as described above, the energy is attenuated several times. By dispersing the energy, the overall horizontal force can be reduced, thereby reducing the width of the structure body and reducing the amount of moon waves and reflectance.

If the breakdown structure according to the present invention is a breakwater of the structure in which the upper portion may be present at the top, if it is a raft, it can be applied effectively regardless of the rest of the specific structural form.

Since the above is merely described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above All of the technical ideas together with the technical idea of the base will be included in the scope of the present invention.

1,2 is a cross-sectional view showing a conventional breakwater.

3 or less shows an embodiment of the upper structure according to the present invention,

3 is a perspective view of a first embodiment;

4 is a cross-sectional view of the first embodiment.

5 is a sectional view of a second embodiment;

6 is a sectional view of a second embodiment;

7 is a perspective view of a third embodiment.

DESCRIPTION OF REFERENCE NUMERALS

100: bottom plate 200: parapet

210: front over-wave prevention part 220: rear over-wave prevention part

300,300a, 300b: Reflective block 310: Moon wave bump

Claims (11)

Bottom plate 100; A parapet 200 protruding upward from the bottom plate 100; And a plurality of reflective blocks 300 installed in front of the bottom plate 100 to reflect the blue wave while preventing some of the waves. The plurality of reflective blocks 300 is an upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the degree of protrusion toward the front is not constant. The method of claim 1, The plurality of reflective blocks 300 A reflection block 300a in the first row disposed at the foremost; And a second row of reflective blocks 300b disposed behind the first row of reflective blocks 300a. The upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the first and second reflection blocks 300a and 300b in the second row are arranged alternately. The method of claim 1, The reflection block 300 is an upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the front inclined upward. The method of claim 3, Upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the anti-jamming step 310 protrudes forward on the upper portion of the reflective block (300). The method of claim 4, wherein Height of the reflective block 300 is the upper structure of the implosion structure having a plurality of reflective blocks, characterized in that lower than the height of the parapet (200). The method of claim 1, The parapet 200 is an upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the front is inclined upward. The method of claim 6, The upper structure of the parapet 200, the upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the front anti-fogging wave 210 is formed protruding. The method of claim 7, wherein In the upper rear of the parapet 200, the rear anti-wave wave 220 is protruding, The upper structure of the implosion structure having a plurality of reflective blocks, characterized in that the height of the rear anti-fog 220 is higher than the height of the front anti-wave 210. The method of claim 8, A front structure of the implosion structure having a plurality of reflective blocks, characterized in that the front surface of the rear anti-fog 220 is concave curved concave toward the rear. Breakwater, characterized in that the upper structure of any one of claims 1 to 9 is installed on the top. A revetment, characterized in that the upper structure of any one of claims 1 to 9 is installed on the top.

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