JP3298862B2 - Coastal structure - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shore structure such as a submerged breakwater structure using breakwater and a breakwater.

[0002]

2. Description of the Related Art Various wave-dissipating structures using breaking waves have been proposed for disaster prevention, such as coastal erosion control, and for forming a calm sea area and forming an ocean recreation area. JP-A-4-289
No. 310, a stepped horizontal plate having the deepest portion on the offshore side, a Japanese Utility Model Laid-Open No. 4-57518, a parallel inclined plate, and JP-A-4-1363.
In some cases, a submerged breakwater disclosed in No. 11 is installed offshore from the main body.

[0003]

However, the submerged embankment and the artificial reef construction method are designed to reduce the water depth on the top,
Since the top width (length in the traveling direction of the wave) is increased with respect to the wavelength to obtain a wave-eliminating effect, the structure must be enlarged.

For example, in a wave breaking structure using the above-described composite wave breaking, a unique composite wave breaking is achieved by making the reef a double leaf of upper and lower stages and making the length of the lower leaf 6.5 times the installation depth. In order to exhibit a sufficient wave-eliminating effect, the size of the structure becomes large, and therefore, there is a problem that the construction cost is increased and the construction period is lengthened. An object of the present invention is to reduce the size of a coastal structure such as a submerged breakwater using a breaking wave so that it can be constructed at low cost.

[0005]

Means for Solving the Problems The offshore side of the open top box is an upright wall, an opening is formed at the lower end of the upright wall, and a slit plate is provided at the top end which is inclined so that the offshore side is high. ,
A plurality of inclined slits were formed with respect to the traveling direction of the waves, so that the breaking waves were captured in the case.

[0006]

[Function] The waves that have entered the coastal structure are at the bottom of the sea,
Alternatively, the wave is amplified by a lower reef such as a mound, and the breaking of the water at the upright wall portion of the box sharply causes a breaking wave larger than a normal breaking wave. Furthermore, since the breaking waves enter the slits, the wave transmission rate in the shore direction is reduced, so that a calm sea area is created on the shore side. In addition, the breaking waves rushing into the box form a return water flow that flows offshore through the opening provided in the upright wall, and the sand entrained in the box flows out with the return water flow, preventing sand from accumulating in the box. You. Further, the return water flow easily causes wave breaking in the upright wall portion, and the wave breaking point moves and the wave breaking easily enters the slit, so that wave energy is reduced and the wave extinction efficiency is increased. In addition, by closing the top surface following the upright wall and providing a blockage, the return water flow flowing offshore on the top of the blockage promotes the generation of breaking waves and moves the breaking point, so that the breaking waves reliably enter the slit I will be.

A case in which a box having an opening and a slit is mounted on a rubble mound of the lower leaf shown in FIG. Installation water depth h ₁ of the wave dissipating structure 1, the total length of the mound 3 for installing the box body 2 is L, and height is R _1. Length to the mound X _2, installation height R ₂ of the upstanding walls, the opening height is the box making body 2 of R ₄ from the offshore end of the mound, as upstanding walls 10 at a distance X ₁ to the position did. Depth from the water surface to the crest is R _3. In the upper part of the box 2, slit plates 13 inclined at an angle (θ) when the breaking wave enters the water surface with respect to the traveling direction of the waves are arranged at intervals, and inclined slits 14 are formed. ing.

[0008] The depth R ₃ from the water surface at the top is preferably 1.5 m or less from the viewpoint of wave extinction efficiency, but must be determined in consideration of the influence on the navigating ship. By installing buoys on the sea around the wave-dissipating structure and taking measures against the ship, it is possible to make the crown water depth shallow, and it can be reduced to about 0.5 m. On the mound 3 on the shore side of the box 2, rubble or wave-dissipating blocks are piled up over the shore side lower leaf length distance X ₃ to prevent the box 2 from moving due to waves.

The wave having a wave height H ₀ traveling offshore is amplified by the lower reef mound as the water depth becomes shallower. When the wave reaches the upright wall 10 of the box 2, the wave is sharply reduced to generate breaking waves. The breaking waves rush into the upper surface of the box 2, pass through the oblique slit 14, are reduced in the inside of the box, and generate a return water flow toward the opening 11. The water is returned from the tank and flows out together with the water flow, so that sand does not accumulate inside the box and the space inside the box is always maintained.

[0010] Since a return water flow is generated from the opening 11 to the offshore side, the breaking point of the generated breaking wave moves to the offshore side,
Since it easily enters the slit 14, the wave energy is efficiently reduced. The wave-dissipating blocks and rubble on the shore side of the box 2 eliminate the waves that cannot be caught by the slits 14, reduce the energy converted from the waves into currents at the top of the box, and pass through the wave-dissipating structures waves and is attenuated to the wave height H _1.

As a result of the experiment, in order to create a calm sea area where the ratio of the wave heights H ₁ and H ₀ is 0.3 or less, the relationship between the specifications of the wave-dissipating structure shown in FIG. It turned out to be necessary. Lower leaf height _{R 1 = h 1 / 3~h 1} /2 upstanding wall height _{R 2 = h 1 / 3~h 1} /2 aperture height _{R 4 = R 2 / 10~R 2} /3 lower leaves length It is X ₁ = 1h ₁ ~3h ₁ box body length X ₂ = 2h ₁ ~4h ₁ Kishi side lower leaf length X ₃ = 1h ₁ ~3h ₁ slit plate angle theta = 25 to 45 °

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIGS. 2 and 3, a wave-absorbing structure 1 is a prestressed concrete box 2 having a width of 10 m, a height of 3 m, and a length of 20 m, and an offshore end. The part is an upright wall 10 having an opening 11 with a height of 1 m at the lower end. The inside of the box 2 is partitioned by a partition wall 12.
On the upper surface of the box 2, between the partition walls 12, 3
A slit plate 13 inclined at 0 degrees is arranged at intervals, and an inclined slit 14 is formed. This box 2 is used as a unit, and the required number is installed along the coastline.

The box 2 is installed on a seabed gradient gently inclined from the coast so that the top is 1.5 m deep from the water surface. Rubble is piled up on the shore side of the box 2 to prevent the box 2 from moving due to waves.

The waves that have traveled offshore are amplified as the water depth becomes shallower, and when they reach the upright wall 10 of the case 2, breaking waves occur due to a sharp decrease in water depth. The breaking wave rushes into the upper surface of the box 2, passes through the oblique slit 14, is reduced in energy inside the box, and generates a return water flow toward the opening 11.
Since the sand carried inside the box is discharged from the opening 11, the sand does not accumulate, and the space inside the box is always maintained.

The rubble on the shore side of the box 2 eliminates the waves that cannot be caught by the slit 14 and reduces the energy converted from the waves into the current at the upper part of the box. Since the generation of the water current from the shore to the offshore is suppressed, the movement of the sand on the seabed is reduced, and the erosion of the shore is prevented. Further, a plurality of square holes 15 are provided at the bottom of the box 2 so that a large lifting pressure does not act on the bottom surface of the box 2.

FIG. 4 shows an example in which the height of the sea floor is 3 m and the total length is 40.
m, a rubble mound 3 with a gradient of 1: 2 was constructed, and at a position 10 m from the offshore top end of this mound 3, a width of 10 m and a height of 3
A wave-dissipating structure 1 is provided by installing a prestressed concrete box 2 having a length of 15 m and a length of 15 m. The upper surface of the box 2 is open, and an opening 11 having a height of 40 cm is formed at the lower end of an upright wall 10 provided at the offshore end. The inside of the box is partitioned by a partition 12, and a slit plate 13 inclined by 30 degrees with respect to the traveling direction of the wave is arranged between the partitions 12 at an open portion on the upper surface of the box 2. An inclined slit 14 is formed, and a plurality of square holes 15 are provided at the bottom of the box 2.

A rubble is installed on the shore side of the wave-dissipating structure 1, and a stiffening block is installed on the surface to eliminate waves that cannot be completely caught by the slits 14 and to reduce the flow toward the shore. The roughness is set to be high. 3m offshore from opening 11
A solidification block is laid on the surface of the mound 3 to prevent scouring due to the vertically downward component of the return water flow heading offshore through the opening 11. The roots compaction block, it is desirable to lay over more than 1/2 of the lower reef length X _1.

The waves that have entered the wave-dissipating structure 1 are amplified by the mound 3 rising from the sea floor, and
Breaking waves are generated by the rapid decrease in water depth at, and rush toward the slit, and are reduced in the interior of the box and generate a return water flow toward the opening. Opening 1
The return water flow heading offshore through 1 promotes the generation of breaking waves, and a breaking point is generated on the slit, so that the breaking wave reliably enters the slit.

The example of FIG. 5 is basically the same as that of FIG. 4, except that 5 m offshore on the upper surface of the box 2 is a closed portion 16 and the remaining 10 m is an open portion 17. A slit plate 13 inclined by 30 degrees with respect to the traveling direction of the wave is arranged between the partition walls 12 at intervals on the upper surface open portion of the box 2, and an inclined slit 14 is formed.

The wave that has entered the wave-dissipating structure is amplified by the mound 3 rising from the sea floor, and a sudden decrease in water depth at the upright wall 10 generates wave breaking at the upper surface blocking portion 16, and the wave breaks toward the slit 14. The water is depressurized inside the box and generates a return water flow toward the opening 11. The return water flow heading offshore through the opening 11 and the return water flow heading offshore through the obstruction 16 on the upper surface of the box facilitate generation of breaking waves, and wave breaking points are generated on the slits, so that wave breaking is ensured. Rush into the slit. Occlusion 16 is preferably 1 / 3-1 / 2 of the length X ₂ of the box body 2.

FIG. 6 shows an example in which the box 2 is constructed on a table 5 constructed by placing a leg 4 made of a concrete pile, a steel pipe or the like on the seabed. Same as the wave structure. The table 5 supported by the legs 4 corresponds to a mound, and the wave that has entered on the upper surface of the table 5 is amplified, and a breaking wave is generated on the upright wall 10 of the box 2.
Is to rush into.

The height of the rear wall 18 on the shore side of the box 2 is higher than the upright wall 10 on the offshore side, and the mounting position of the slit plate 13 is higher toward the shore. Accordingly, the breaking waves are reliably caught by the slits 14 and prevent the waves from propagating to the shore beyond the rear wall 18. Even in the case of a legged type, the height of the rear wall 18 does not always have to be high, and may be the same height as the upright wall. Basically, the mound is simply replaced with a legged type stand.

The legs 4 are generally made of concrete piles, but the base 5 is manufactured in a factory as a steel-structured jacket, and a steel pile is poured into the jacket and fixed at the site. Can be shortened.

This legged wave-breaking structure has the advantage that it can be constructed without reclamation of the sea area, so that it has little effect on the environment. Also, when the installation water depth is deep or the seabed slope is steep, It is effective for Installing a wave-breaking structure etc. in a seated location where the seabed is soft and unstable is likely to sink, so it is possible to prevent the settlement by piled up to the foundation rock as a legged type in this way preferable. The present invention can be applied not only to a wave-dissipating structure but also to a breakwater.

[0025]

The coastal structure of the present invention is smaller in size than a conventional wave-breaking structure by providing a slit behind the upright wall and guiding the breaking waves generated by the upright wall to the slit. The above-mentioned wave elimination efficiency can be achieved. This makes it possible to construct a wave-dissipating structure at low cost, restore shallow beaches on steep eroded coasts, and improve the stability of beaches and the ability to purify seawater. It can create an environment. Furthermore, since a water area with high calmness can be created between the wave-dissipating structure and the beach, a place suitable for marine recreation can be provided. The slits and the entire coastal structure increase the diversity of living organisms, function as fish reefs, and oxygen is supplied by the breaking wave jets, increasing dissolved oxygen, making it a favorable environment for biological growth. The diversity of

In addition, when the wave-dissipating structure of the present invention is applied to a beach nourishment or artificial beach on a gently sloping beach, fine sand is supplied to the shore with high wave-dissipating efficiency, and the particle size of the sand beach is reduced. Can create a comfortable beach.

By providing a slit at the portion where the strong jet of the generated composite breaking wave enters, the generation of splash and horizontal vortex is suppressed, and the wave entering from the slit passes through the opening of the upright wall. As the current returns to the offshore side, the breaking point moves, and the breaking wave is more easily captured by the slit. Therefore, the wave is reduced and the wave is prevented from being regenerated. Therefore, the wave is effectively eliminated, and a similar wave-dissipating structure is obtained although the size is reduced as compared with the conventional wave-dissipating structure using the breaking wave. The effect is obtained. By using a double leaf, not only the reflectance can be reduced, but also the transmittance can be reduced with the generation of the composite breaking wave. Therefore, in the wave-dissipating structure of the present invention, wave extinction is efficiently performed, and wave-dissipation is effectively performed.

[Brief description of the drawings]

FIG. 1 is a sectional view of a coastal structure.

FIG. 2 is a cross-sectional view of the wave-absorbing structure.

FIG. 3 is a front view of the wave breaking structure.

FIG. 4 is a sectional view of a two-stage wave-absorbing structure.

FIG. 5 is a cross-sectional view of a wave-breaking structure having a closed portion provided on the upper surface of a box.

FIG. 6 is a cross-sectional view of a wave-absorbing structure provided on a base having a leg structure.

FIG. 7 is an installation state diagram of a wave-absorbing structure having a leg structure.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Coastal structure (wave-dissipating structure) 2 Box 3 Mound 10 Upright wall 11 Opening 12 Partition wall 13 Slit board 14 Slit 15 hole 16 Closed part 18 Rear wall

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-5-132913 (JP, A) JP-A 55-110520 (JP, U) JP-A 6-46024 (JP, U) 57938 (JP, B2) Jiko 67045 (JP, Y2) (58) Field surveyed (Int. Cl. ⁷ , DB name) E02B 3/06

Claims (6)

(57) [Claims] An off-shore front surface is an upright wall having an opening formed at a lower end thereof, and a slit plate is provided at a top end thereof, which is inclined so that an off-shore side is high, and is provided in a wave traveling direction. A coastal structure with multiple sloped slits. 2. The shore structure according to claim 1, wherein the upper surface of a predetermined section from the upright wall is closed. 3. The shore structure according to claim 1, wherein a hole is provided in a bottom portion. 4. A coastal structure according to any one of claims 1 to 3, wherein the housing is installed on a mound and formed in two steps. 5. A shore structure in which the shore structure comprising the box of claim 1 or 2 is installed on a base having a leg structure. 6. The container according to any one of claims 1 to 5, wherein a shore side wall of the box is higher than an upright wall on the offshore side, and the slit is disposed so as to be higher toward the shore. Coastal structure.