JP3643816B2 - Breakwater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a breakwater.
[0002]
[Prior art]
As a means of calming the coastal sea area, for example, artificial reefs and breakwaters in which a substantially hollow hexahedral wave-dissipating block 40 as shown in FIG. (See FIG. 7). In addition, the artificial reef and the breakwater can be constructed not only by the substantially hollow hexahedron wavebreak block 40 but also by stacking the substantially hollow tetrahedron wavebreak blocks 40 as shown in FIG. In any case, they reduce wave energy by breaking the wave that pushes.
In order to enhance the effect of reducing wave energy, Japanese Patent Laid-Open No. 2001-336132 proposes a coastal structure in which the top end is opened and a slit plate is provided at the top end.
[0003]
[Problems to be solved by the invention]
However, if the top of the coastal structure is flat, even if an opening is provided at the top, the wave can be guided into the coastal structure unless the wave enters from the front of the opening. The wave energy reduction effect was small.
In addition, if the top of the coastal structure is flat, the waves directly hit the top of the coastal structure, so the impact was great, and the structure of the coastal structure had to be strengthened to withstand the impact.
Furthermore, when there were no walls facing the waves in the part facing the offshore side of the coastal structure, the effect of reducing wave energy was small when long-period waves rushed.
[0004]
Therefore, an object of the present invention is to provide a breakwater that has a large wave energy reduction effect, does not require strengthening the structure, and exhibits a great reduction effect even for long-period waves.
[0005]
[Means for Solving the Problems]
In order to solve the above-described problem, the invention according to claim 1 is, for example, as shown in FIGS. 1 to 5, a bottom portion 2 that is a bottom, and the bottom portion 2 is continuous with and parallel to each other, and openings 3 a and 4 a are provided. The wave-dissipating block 10 including the formed first wall portion 3 and second wall portion 4 and the ceiling portion 1 continuous with the first wall portion 3 and the second wall portion 4, and the first wall portion 3 on the offshore side. , A breakwater 100 in which a plurality of second wall portions 4 are set in the sea with the second wall portion 4 facing the shore side, and the ceiling portion 1 is higher on the first wall portion 3 side, and on the second wall portion 4 side. Formed in a low inclined surface, the opening 3a of the first wall 3 is formed so that at least a part thereof is higher than the ceiling 1 at the upper end of the second wall 4, and the wave-dissipating block 10 is The first wall 3 is installed so as to be substantially perpendicular to the water surface.
[0006]
According to the first aspect of the present invention, since the water flow over the upper end of the first wall portion flows along the ceiling portion that is an inclined surface, the direction of the water flow toward the shore can be changed. Here, when a wave breaker is constructed by installing a plurality of wave-dissipating blocks in succession, the ceiling part smoothly guides the water flow to the opening of the first wall part of the wave-dissipating block adjacent to the shore side. Therefore, the effect of reducing water flow energy can be increased. Furthermore, the water flow over the first wall portion does not directly hit the ceiling portion, and it is not necessary to strengthen the structure of the wave-dissipating block in order to withstand the impact.
[0007]
The invention according to claim 2 is, for example, as shown in FIG. 1, in the breakwater 100 according to claim 1, the opening portion of the first wall portion 3 in the wave-dissipating block 11 installed on the most offshore side. The wall surface above 3 a is formed wider than the wall surface above the opening 3 a in the other wave-dissipating block 10.
[0008]
According to the second aspect of the present invention, the presence of the wall portion at the top of the opening widens the surface where the water flow collides with the first wall portion, so that the energy of the water flow can be greatly reduced. Here, when constructing a breakwater, if a breakwater block having a wall surface portion is installed on the most offshore side, a lot of energy can be reduced before the water flow enters the breakwater. Furthermore, since the wave period can be disturbed at the wall surface portion, even if a long-period wave is pushed, it is easily broken and the wave energy can be reliably reduced.
[0009]
The invention according to claim 3 is, for example, as shown in FIG. 1 to FIG. 5, in the breakwater 100 according to claim 1 or 2, a plurality of pieces are separated from each other at the lower end portion of the second wall portion 4. A leg portion 6 is provided, and a convex portion 7 that can be fitted into a space 8 surrounded by the lower end edge of the second wall portion 4 and the leg portion 6 is provided at the lower end edge of the first wall portion 3. And
[0010]
According to the third aspect of the present invention, when constructing a wave breaker, it is possible to fit and connect the convex part of a certain wave-dissipating block and the concave part of another wave-dissipating block. Therefore, the installation work of the breakwater in water can be facilitated. In addition, when a vertical upward lifting pressure that causes the breakwater to fall or slips on the breakwater, the breakwater adjacent to the offshore side suppresses the breakwater affected by the lifting pressure by its weight. Can improve the stability of the breakwater.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example of an embodiment according to the present invention will be described in detail with reference to the drawings.
First, the configuration of the coastal structure will be described.
As shown in FIGS. 1 to 5, the wave-dissipating block 10 as a coastal structure reduces the wave energy of waves rushing from offshore, and is formed in a hexahedron, for example, as shown in FIG. An upper surface portion 1 as a portion, a lower surface portion 2 as a bottom portion, a front surface portion 3 as a first wall portion, a rear surface portion 4 as a second wall portion, a side surface portion 5, a leg portion 6, a convex portion 7, a concave portion 8, and the like. It is provided and is made of concrete.
[0014]
The upper surface portion 1 is formed in a rectangular wall shape when viewed from the front, and has an inclined surface that is high on the front surface portion 3 side and low on the rear surface portion 4 side. The inclination angle is substantially equal to the angle at which waves from offshore are incident on the upper surface portion 1. The upper surface portion 1 is formed so as to be connected to the upper edge of the front surface portion 3, the rear surface portion 4, and the side surface portion 5, and is located above the lower surface portion 2.
[0015]
The lower surface portion 2 is a portion that is attached to the mound 20 constructed on the sea floor, and is formed in a rectangular wall shape when viewed from the front. Further, from the lower surface portion 2, the front surface portion 3 rises from the offshore side edge at a substantially right angle with respect to the lower surface portion 2, and the rear surface portion 4 from the shore side edge at a substantially right angle to the lower surface portion 2. The side surface 5 is raised substantially perpendicularly to the lower surface 2 from the remaining side edges. In addition, the lower surface portion 2 is formed with an opening 2 a for preventing sediment accumulation in the wave-dissipating block 10 and ensuring the flow of water inside and outside the wave-dissipating block 10.
[0016]
The front surface portion 3 is raised from the side edge on the offshore side of the bottom surface portion 2 and is installed so as to face the offshore side. Further, an opening 3 a for guiding the wave to the inside of the wave-dissipating block 10 is formed over almost the entire area of the front surface portion 3.
[0017]
The rear surface portion 4 is raised from the side edge of the lower surface portion 2 on the shore side, and is installed so as to face the shore side. Further, the rear surface portion 4 is formed with an opening 4 a for ensuring the circulation of the wave guided into the wave-dissipating block 10. The rear surface portion 4 is formed lower than the front surface portion 3, and the difference in height causes the upper surface portion 1 to be inclined.
[0018]
The side surface portion 5 is formed so as to be continuous with each of the upper surface portion 1, the lower surface portion 2, the front surface portion 3, and the rear surface portion 4. An opening 5a for ensuring the flow of water is formed.
The leg portions 6 are formed at the four corners of the back surface of the lower surface portion 2, and prevent sediment accumulation inside the wave-dissipating block 10 and ensure the flow of water inside and outside the wave-dissipating block 10.
[0019]
As shown in FIG. 4, the convex portion 7 is formed at the lower end portion of the front surface portion 3, and is formed so as to protrude from the front surface portion 3 to the outside on the offshore side.
As shown in FIG. 5, the concave portion 8 is formed at the lower end portion of the rear surface portion 4, and utilizes a space surrounded by the lower end edge of the rear surface portion 4 and the leg portion 6 on the shore side. Moreover, the recessed part 8 is made into the shape corresponding to the convex part 7, ie, the shape in which the convex part 7 can be engage | inserted.
[0020]
Further, as shown in FIG. 1, when installing a plurality of wave-dissipating blocks 10 on a mound 20 constructed on the seabed, a wave-dissipating block 11 with a wall is used as the wave-dissipating block that is installed most offshore. .
The wall-mounted wave-dissipating block 11 is the same as the wave-dissipating block 10 except for the front-surface part 3, and only the front-surface part 3 will be described.
As shown in FIG. 3, the front surface portion 3 has an opening 3 a at the lower portion and a wall surface portion 3 b at the upper portion. By providing the wall surface portion 3b, wave breaking can be promoted. Further, by forming the opening 3a near the lower end without forming the entire surface of the front surface portion 3 as the wall surface portion 3b, it is possible to guide the waves into the wave-dissipating block 10, and the earth and sand inside the wave-dissipating block 11 Accumulation prevention and wave distribution in the wave-dissipating block 11 can be ensured.
[0021]
In order to construct the wave breaker 100 by installing a plurality of wave breaker blocks 10 in the sea, first, as shown in FIG. 1, crusher runs are spread on the bottom of the sea. Next, the crusher run is rubbed to construct the mound 20. Next, the wave-dissipating block 10 is installed on the mound 20 from the shore side. At this time, it installs so that the recessed part 8 of the wave-dissipating block 10 to install may be fitted on the already installed convex part 7 adjacent to the shore side. Here, a wave-dissipating block 11 with a wall is installed in the most offshore row. The wave-dissipating block 10 is also installed in a direction orthogonal to the wave traveling direction, that is, from the front side to the back side in FIG. After the installation of the wave-dissipating block 10 is completed, covering stones for preventing the scouring of the mound 20 and the displacement of the wave-dissipating block 10 are laid around and on the mound 20. By the above procedure, a plurality of wave-dissipating blocks 10 are continuously installed between the offshore side and the shore side, and the wave-dissipating bank 100 is constructed.
The wave-dissipating block 10 is installed near the shore on the mound 20. This is intended to reduce the wave energy with the mound 20 before the wave reaches the wave-dissipating block 10.
[0022]
Next, the operation of the wave breaking blocks 10 and 11 will be described.
When waves rush from offshore, first, wave energy is reduced by the mound 20. Then, a wave collides with the wall surface part 3b of the wave-dissipating block 11 with a wall, and a wave is broken. A part of the wave that has been broken travels over the front surface portion 3 of the wave-dissipating block 11 with a wall, and is guided into the wave-dissipating block 10 from the opening 3a of the wave-dissipating block 10 adjacent to the shore side. The wave that has entered the wave-dissipating block 10 loses most of the wave energy due to the disturbance in the vertical direction, and is extinguished. On the other hand, a part of the wave that has passed over the opening 3a is further guided from the opening 3a to the inside of the wave-dissipating block 10 adjacent to the bank by the wave-dissipating block 10. The wave energy is reduced as it travels to the wave-dissipating block 10 on the shore side, and is eventually extinguished.
[0023]
According to the wave-dissipating block 10 of the present embodiment, the wave that has passed over the upper end of the front surface portion 3 flows along the upper surface portion 1 and can change the direction of the water flow toward the shore. When the wave breaker 100 is constructed by the wave breaker block 10, the wave breaker 100 is smoothly guided to the inside of the wave breaker block 10 from the opening 3 a of the front surface part 3 of the wave breaker block 10 adjacent to the shore side. The wave guided to the inside of the wave-dissipating block 10 tends to flow out from the opening 4a of the rear surface portion 4, but is disturbed in the vertical direction due to the return wave returning from the shore toward the offshore and the presence of the inclined upper surface portion 1. And energy is greatly reduced.
[0024]
On the other hand, the energy of the wave guided from the opening 3a of the front surface portion 3 to the inside of the wave-dissipating block 10 is similarly reduced by the disturbance in the vertical direction. Therefore, since the wave rushed to the wave-dissipating block 10 is guided to the inside of the wave-dissipating block 10 regardless of whether or not it gets over the front surface portion 3, the wave energy can be greatly reduced by the disturbance in the vertical direction. . Further, the wave that has passed over the front surface portion 3 does not directly hit the upper surface portion 1, and it is not necessary to reinforce the structure of the wave-dissipating block 10 in order to withstand the impact.
[0025]
Further, the presence of the wall surface portion 3b of the front surface portion 3 widens the surface where the wave collides with the front surface portion 3, so that the wave energy can be greatly reduced. Here, for example, when the breakwater 100 is constructed, if the wavebreak block 10 having the wall surface portion 3 b is installed on the most offshore side, a large amount of wave energy can be reduced before the waves enter the breakwater 100. . Furthermore, since the wave period can be disturbed at the wall surface part 3b, even if long-period waves are pushed together, they are easily broken and the wave energy can be reliably reduced.
[0026]
Furthermore, when constructing the wave breaker 100, the convex part 7 of the wave breaker block 10 and the concave part 8 of the adjacent wave breaker block 10 can be fitted and connected. Therefore, the installation work of the wave-dissipating block 10 in water can be facilitated. In addition, when a vertically upward lifting pressure that causes the wave-dissipating block 10 to fall or shift acts on the wave-dissipating block 10, the coastal structure in which the wave-dissipating block 10 adjacent to the offshore side acts as a lifting force by its weight. Therefore, the stability of the wave-dissipating block 10 can be improved.
[0027]
Moreover, since the rising amount of the water level on the shore side becomes small by being wave-dissipated by the wave-dissipating block 10, the flow returning from the shore side to the off-shore side is small, and the erosion of the mound 20 can be prevented.
[0028]
The present invention is not limited to the embodiment described above. For example, the wave-dissipating block does not have to be a hexahedron, and may be an octahedron, a decahedron, or the like. Moreover, the upper surface part may be formed in the curved surface. Furthermore, the number of wave-dissipating blocks installed is arbitrary and can be changed according to the ocean wave conditions. In addition, each component can be changed in design without departing from the gist of the invention.
[0029]
【The invention's effect】
According to invention of Claim 1, the energy of a water flow can be reduced significantly. Moreover, it is not necessary to strengthen the structure of the wave-dissipating block.
[0030]
According to invention of Claim 2, reduction of the energy of a water flow can be promoted. Furthermore, even if long-period waves are pushed together, the wave energy can be reliably reduced.
[0031]
According to invention of Claim 3, the installation operation | work in water can be made easy. Moreover, the stability of the coastal structure can be improved.
[Brief description of the drawings]
FIG. 1 is a side sectional view for explaining a breakwater in an embodiment of the present invention.
FIG. 2 is a diagram for explaining a wave-dissipating block in the embodiment.
FIG. 3 is a diagram for explaining a wave-dissipating block with a wall in the embodiment.
FIG. 4 is a perspective view for explaining a convex portion in the embodiment.
FIG. 5 is a perspective view for explaining a recess in the embodiment.
FIG. 6 is a perspective view for explaining a wave-dissipating block in the prior art.
FIG. 7 is a side sectional view for explaining a breakwater using a breakwater block in the prior art.
FIG. 8 is a side sectional view for explaining a breakwater using a breakwater block in the prior art.
[Explanation of symbols]
1 Top surface (ceiling)
2 Lower surface (bottom)
3 Front (first wall)
3a Opening 3b Wall surface 4 Rear surface (second wall)
4a Opening 7 Convex 8 Concave 10 Wave-dissipating block (shore structure)
11 Wave-dissipating block (coast structure)

Claims (3)

A power source comprising a bottom portion that is a bottom, a first wall portion and a second wall portion that are continuous with the bottom portion and that are parallel to each other and have openings, and a ceiling portion that is continuous with the first wall portion and the second wall portion. A wave breaker in which a plurality of wave blocks are continuously installed in the sea with the first wall portion offshore and the second wall portion facing the shore,
Forming the ceiling portion on an inclined surface having a high first wall portion side and a low second wall portion side;
Forming the opening of the first wall part so that at least a part thereof is higher than the ceiling part at the upper end of the second wall part;
A wave breaker, wherein the wave breaker block is installed such that the first wall portion is substantially perpendicular to the water surface.   The wall surface portion above the opening portion of the first wall portion in the wave-dissipating block installed on the most offshore side is formed wider than the wall surface portion above the opening portion in other wave-dissipating blocks. The described breakwater. A plurality of legs spaced apart from each other are provided at the lower end of the second wall,
3. The eraser according to claim 1, wherein a convex portion that can be fitted into a space surrounded by the lower end edge of the second wall portion and the leg portion is provided at the lower end edge of the first wall portion. Wave dyke.

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